We present the geologic history of the High Rock caldera complex (HRCC; Nevada, USA), a major mid-Miocene silicic center associated with flood basalt volcanism. Based on 70 40Ar/39Ar ages and new 1:24,000- and 1:100,000-scale geologic mapping, we document that between ca. 16.5 and 15.5 Ma a minimum of ∼700 km3 of rhyolitic magma erupted from the HRCC, covering an area of ∼8300 km2 in northwestern Nevada and southern Oregon (USA). The volcanism immediately followed eruption of the Steens flood basalt in the region, and was contemporaneous with eruption of compositionally similar rhyolites from the McDermitt volcanic field (MVF) to the east. The HRCC and MVF together mark the starting point for the eastward-younging trend of voluminous rhyolitic calderas of the Snake River Plain–Yellowstone trend.
The HRCC comprises 4 major calderas, 24–40 km in diameter, that young from north-northeast to south-southwest: the Virgin Valley caldera formed on eruption of the 16.38 Ma high-silica alkali rhyolite Idaho Canyon Tuff; the overlapping Badger Mountain caldera collapsed due to eruption of the 16.34 Ma crystal-rich, low-silica rhyolite Summit Lake Tuff; eruption of the moderately peralkaline high-silica alkali rhyolite Soldier Meadow Tuff at 16 Ma resulted in formation of the Hanging Rock caldera; and the Cottonwood Creek caldera formed on eruption of the newly recognized, 15.70 Ma tuff of Yellow Rock Canyon, which is zoned from high-silica alkali rhyolite to trachyte. The four calderas contain caldera fill deposits, including pumice and ash falls, lahars, phreatomagmatic deposits, and well-bedded lacustrine deposits, which preserve diverse mid-Miocene fossil fauna and flora. Au and U mineralization developed along ring fractures of the Virgin Valley and Cottonwood Creek calderas. After silicic volcanism largely ceased, trachyte, trachyandesite, and alkalic basaltic lavas erupted through the caldera lakes.
Intense silicic volcanism at the HRCC during the interval 16.4–15.5 Ma overlapped the eruption of the Steens and Columbia River Basalts, strongly suggesting a petrogenetic link. We propose that the HRCC and MVF caldera centers are localized where dikes of Steens flood basalt encountered transitional crust west of the craton with a composition and thickness that allowed significant partial melting, based on the O and Nd isotopic values of the rhyolites, which require involvement of crustal melts in their origin. Steens Basalt eruptions largely ceased in the area by the time the oldest caldera-forming ignimbrites erupted at both the HRCC and MVF, indicating that once large silicic magma bodies aggregated in the crust, they intercepted flood basalt dikes. We suggest that the roots of the HRCC and MVF are composed of large volumes of gabbroic intrusions and cumulates formed by fractional crystallization of HRCC magmas, which strengthened the middle crust beneath the calderas; major basin-bounding normal faults are diverted around them, but outflow ignimbrites are prominently offset by Basin and Range faults.
Continental flood basalt provinces represent extraordinary magmatic events during which 105–106 km3 of basaltic lava are erupted over timespans as short as 105–106 m.y. (e.g., Courtillot and Renne, 2003; Bryan and Ernst, 2008). It has been increasingly recognized that they are spatially and temporarily associated with significant volumes of rhyolite erupted as ignimbrites and lavas (e.g., Garland et al., 1995; Bryan et al., 2002, 2010; Courtillot and Renne, 2003; Gibson et al., 2006; Pankhurst et al., 2011; Coble and Mahood, 2012). The youngest and best-exposed continental flood basalt province on Earth is located in the northwestern United States (Fig. 1), represented by the Steens and Columbia River Basalts (e.g., Camp et al., 2013); consequently, it is the locale in which the relationship of flood basalt to rhyolite can be best studied. Although ∼98% of the volume of magma that erupted in Washington, Oregon, and Nevada from 16.9 to 15.0 Ma was mafic (Reidel et al., 2013), locally rhyolitic volcanism far exceeded the volume of basalt erupted (Rytuba and McKee, 1984; Cummings et al., 2000; Brueseke et al., 2007; Shervais and Hanan, 2008; Coble and Mahood, 2012). Here the footprint of flood basalt magmatism and its thermal effects on the continental crust can be determined, and the age, location, and volume of silicic magmatism relative to the more voluminous mafic eruptions can be used to differentiate between various models for the origin of flood basalt magmatism.
Detailed work on caldera-forming silicic magmatism contemporaneous with Steens and Columbia River Basalt volcanism has been published only for the McDermitt volcanic field (MVF) on the Oregon-Nevada border (Rytuba and McKee, 1984; Conrad, 1984). As a result, the McDermitt caldera has tended to be the mid-Miocene silicic center most discussed in petrogenetic models for the flood basalt province and the eastward-younging silicic volcanism of the Snake River Plain (e.g., Hooper et al., 2007; Leeman et al., 2008). In many published models, the initial impingement of a proposed Yellowstone mantle plume head on North American lithosphere is located on the Oregon-Nevada border near the McDermitt caldera (Fig. 1) (e.g., Parsons et al., 1994; Pierce et al., 2002; Hooper et al., 2007; Leeman et al., 2008). The McDermitt caldera is also commonly cited as the starting point for the time-transgressive trend of silicic calderas along the Snake River Plain (e.g., Christiansen and Yeats, 1992; Pierce and Morgan, 1992; Perkins and Nash, 2002; Christiansen et al., 2002; Brueseke et al., 2007; Shervais and Hanan, 2008), and a trend of smaller silicic centers that generally young to the northwest away from McDermitt in the High Lava Plains province in eastern Oregon (Jordan et al., 2004; Ford et al., 2013) (Fig. 1). However, numerous workers have suggested that mid-Miocene silicic volcanism is more widespread (e.g., Christiansen and Yeats, 1992; Pierce and Morgan, 1992; Brueseke and Hart, 2008; Shervais and Hanan, 2008; Coble and Mahood, 2012; Camp et al., 2013; Streck et al., 2015). A compilation by Coble and Mahood (2012) documented that a minimum of 3900 km3 of rhyolite dense rock equivalent (DRE) erupted over a wide region between 16.5 and 15.0 Ma, contemporaneous with the main phase of Steens and Columbia River Basalt activity, the bulk of it at three major caldera complexes (Fig. 1): the MVF (1665 km3), Lake Owyhee volcanic field (∼1115 km3), and High Rock caldera complex (HRCC) (∼700 km3).
This paper presents the results of our study of the HRCC, which was named by Ach and Swisher (1990) for a northeast-trending set of 4 calderas ∼70 km west-southwest of the McDermitt caldera (Fig. 2). It is part of an effort to genetically link the timing, volume, and distribution of rhyolitic volcanism to models for the origin of flood basalts. Given the prolonged aridity and minimal local extension since the mid-Miocene (Wolfe et al., 1997; Colgan et al., 2006; Mulch et al., 2008), the HRCC has undergone only minor erosion and minimal sedimentation, making it among the best-preserved examples of the original morphology of silicic volcanism related to flood basalt eruptions anywhere on Earth. These centers are also better exposed than the hotspot-related silicic centers in the Snake River Plain, most of which are largely buried by younger Snake River Plain basalts, or, as is the case for the younger than 2.2 Ma volcanism at Yellowstone, are heavily forested.
Ours is the first caldera complex–wide study of the HRCC; we delineate individual calderas, establish the stratigraphy of the major ignimbrites, and assign rhyolitic and trachytic lavas to caldera centers. Through regional- and 1:24,000-scale geologic mapping, geochemical correlation, and high-precision 40Ar/39Ar geochronology, we have developed a tightly constrained stratigraphy for a 1 m.y. interval in the mid-Miocene. By demonstrating the extraordinary rate of activity concentrated at ca. 16.4–15.5 Ma, and the overlap in age with the outpouring of Steens Basalt and earliest Columbia River Basalt and with similar silicic volcanism at the MVF, we provide a more accurate understanding of the silicic magmatism associated with flood basalt eruptions and the inception of the Snake River Plain–Yellowstone caldera trend.
In the we discuss in detail our field mapping, sample collection strategy, sample preparation methods, whole-rock major and trace element analyses, Nd and O isotopic analyses, and paleomagnetic work. We also summarize the analytical methods for 40Ar/39Ar geochronology, and discuss precision, accuracy, and geologic sources of inaccuracy in the ages.
We conducted new 1:100,000-scale mapping () of the area shown in Figures 3 and 4 between 2006 and 2012 in order to delineate calderas, correlate individual ignimbrites, and assign ignimbrites and lavas to specific calderas or centers. We also conducted 1:24,000-scale mapping of 4 contiguous quadrangles (Bear Buttes, Badger Mountain SE, Nut Mountain, and Massacre Creek) to investigate a complicated area of overlapping calderas (Figs. 3 and 4; ). All volume estimates (Table 1) are calculated from mapped extracaldera eruptive exposures (Fig. 5; see for isopach maps) and expressed as DRE. Intracaldera deposits are not exposed due to the lack of incision and large-magnitude normal faulting in the HRCC.
Stratigraphic Nomenclature for Eruptive Units
For the major ignimbrites we have used the formal and informal unit names of Noble et al. (1970), except where our new mapping requires they be revised. We draw upon unit names for lavas from Greene (1984) and Korringa (1973), modifying the place names as necessary to be more representative. See for a comparison of the nomenclature used by previous workers with our revised and standardized unit names.
The convention we have followed in forming abbreviations for rhyolitic units on maps, figures, tables, and in the text is as follows: all have the prefix M for Miocene or P for Paleogene, followed by an i for an ignimbrite that is considered a single eruptive unit, t for a tuffaceous unit that represents more than a geologic instant in time because it consists of some combination of multiple ignimbrites, fall and surge deposits, reworked pumice deposits, and minor lavas, or an l for a lava unit, which generally consists of multiple flows that are chemically related and of similar age. These are followed by a one- or two-letter abbreviation for the unit name or location (e.g., sl for Summit Lake Tuff, Misl). In addition, mid-Miocene postcaldera mafic lavas and trachytic intermediate lavas are indicated by Mm and Mt, respectively.
Silicic Rock Classification
The total alkalies versus silica (TAS) classification diagram of LeBas et al. (1986) is of limited utility for rocks with >63 wt% SiO2 because many different rocks are subsumed under the rhyolite field. We have informally modified the traditional TAS diagram to add fields to provide for greater specificity in naming silicic rocks at the HRCC (Fig. 6). Our modification was prepared by comparing the names applied previously and the compositions of felsic rocks worldwide using the EarthChem Portal (http://www.earthchem.org/portal; accessed August 2013). It explicitly captures the fact that total alkalies generally begin to decline at silica contents >∼74 wt% SiO2 due to the large proportion of alkali feldspar in the fractionating assemblage in a rhyolitic magma approaching minimum-melt composition.
We obtained 70 new 40Ar/39Ar ages for rhyolitic lavas and ignimbrites and intermediate and mafic lavas associated with the HRCC employing a Nu-Instruments Noblesse noble gas mass spectrometer at Stanford University (Stanford, California) in multicollector mode using methods described in Coble et al. (2011). Single sanidine grains or individual groundmass fragments were fused using a 10W CO2 laser. No step-heating analyses were performed. Analyses were conducted during consecutive analytical sessions under the same instrument conditions; the circumstances in which the 40Ar/39Ar method has the greatest precision in distinguishing between the ages of units.
Total-fusion sanidine and groundmass ages are reported as weighted means and 2σ standard errors. Inverse-isochron ages are the calculated York fit intercept and 2σ error (York, 1968). Reported 2σ standard errors for total-fusion model ages are multiplied by the square root of the mean square of weighted deviates (MSWD) when the latter exceeded the range expected for a homogeneous population based upon Monte Carlo simulations (Mahon, 1996). All reported ages are calculated relative to a model age of 28.02 Ma for Fish Canyon sanidine (Renne et al., 1998).
Our preferred ages for eruptive units are listed in Table 1. Representative results for single-grain analyses of alkali and feldspar are illustrated in Figure 7 and results for devitrified groundmass of rhyolite lava and microcrystalline groundmass of trachyte and basalt lavas are in Figure 8. (Full information for all the analyses is available in and a discussion of analytical methods in the Supplemental Text File.)
PREVIOUS STUDIES AT THE HRCC
Our work reconstructing the geologic history of the calderas and major eruptive units that constitute the HRCC builds on more than a century of geologic studies. These began with Merriam (1910), who identified mammalian fossils of mid-Miocene age within what are now known to be sediments deposited in caldera lake environments (Hilton et al., 2008; this study). Noble et al. (1970) were the first to assign names to ignimbrites in northwest Nevada, obtain K-Ar dates that established their mid-Miocene ages, and propose potential sources. Subsequent work by Noble and colleagues (e.g., Korringa, 1973; Park, 1983; Noble et al., 2009; Smith et al., 2010; Smith, 2011) elucidated the volcanology and petrology of the Soldier Meadow Tuff and tuff of Trough Mountain and their relationship to possible calderas. Geologic mapping by the U.S. Geological Survey that focused on assessing resources in lands set aside as the Sheldon National Wildlife Refuge and as potential wilderness areas (e.g., Greene, 1984; Greene and Plouff, 1981; Ach, 1988, Ach and Swisher, 1990; Ach et al., 1991) furthered the understanding of the stratigraphy and the location of calderas. In particular, Ach and Swisher (1990) were the first to recognize the presence of four major calderas. Investigations of mineralization at the Virgin Valley caldera (Castor and Henry, 2000; Rytuba et al., 2010) and Cottonwood Creek caldera (Harvey et al., 1986; Bussey, 1996) (Fig. 4) have shown a strong correlation between the location of postcaldera ring-fracture rhyolitic intrusions with mineralization by gold, silver, uranium, lithium, gallium, and mercury. For a more extensive discussion of how our study builds on previous work, see the Supplemental Text File.
Summary of Eruptive History of the HRCC
The results of our mapping, geochronology, geochemistry, and paleomagnetic measurements indicate that the HRCC consists of eruptive products associated with 4 calderas that erupted over a period of ∼1 m.y. starting ca. 16.6 Ma (Figs. 2 and 4). We summarize that history (Table 1; Fig. 5 [see for a printable version of interactive Fig. 5]) and discuss the detailed geology of individual units and calderas in the following sections. Unit abbreviations in parentheses are referenced on maps (Fig 4; Plates 1 and 2) and throughout the text. All volume estimates for ignimbrites (calculated as DRE) are for outflow sheets, as the lack of incision makes accurate estimates of intracaldera volumes impossible.
We have delineated four major calderas, which decrease in age from northeast to southwest (Figs. 2, 4, and 5). The oldest, the Virgin Valley caldera, formed at 16.38 Ma on eruption of the mineralogically and chemically zoned alkali rhyolite Idaho Canyon Tuff (Miic), which has a minimum calculated volume of 52 km3 (Table 1). Within only a few tens of thousands of years, eruption of the strongly porphyritic, low-silica rhyolite Summit Lake Tuff (Misl), dated as 16.34 Ma, caused collapse of the Badger Mountain caldera, which overlapped the southern margin of the Virgin Valley caldera. Approximately 100 k.y. after eruption of the Summit Lake Tuff, >55 km3 of crystal-poor alkali rhyolite Antelope lavas (Mla) and compositionally similar small-volume pyroclastic units referred to as the tuff of Big Mountain (Mtbm) vented along reactivated ring faults of the Virgin Valley caldera.
South of the Badger Mountain caldera, there are curvilinear faults and vent alignments for 16.3–16.2 Ma crystal-poor alkali rhyolite lavas. Adjacent to these are exposures of densely welded ignimbrites of similar compositions, the newly identified 16.27 Ma tuff of Coyote Spring (Mics) and the 16.25–16.15 Ma tuff of Trough Mountain (Mttm). We suggest that these ignimbrites erupted from areas now preserved as scallop-shaped collapse features that represented migration of the caldera focus southwestward. The tuffs of Coyote Spring and Trough Mountain now form high-standing massifs (Figs. 3 and 4) due to magmatic uplift that culminated in eruption of more strongly alkalic rhyolite lavas along the northern ring fracture of the next major caldera, the Hanging Rock caldera. It formed at 16 Ma as a result of eruption of an estimated volume of ∼65 km3 of strongly porphyritic, alkali rhyolite of the Soldier Meadow Tuff (Mism). It is the most peralkaline of the major ignimbrites erupted at the HRCC. Shortly following collapse of the Hanging Rock caldera, the Soldier Meadow alkali rhyolite lavas (Mlsm), which are petrographically and chemically similar to the Soldier Meadow Tuff, erupted within the caldera and along an arcuate, north-south–trending vent array sympathetic to the eastern caldera margin.
Beginning ca. 15.95 Ma, shortly following eruption of the Soldier Meadow Tuff, renewed magma influx focused beneath the Badger Mountain caldera resulted in uplift and eruption of three chemically distinct generations of alkali rhyolite lavas of Mahogany Mountain (Mlmm); these lavas erupted over a period of 0.4 m.y. (Fig. 5). Vents were focused along the inferred ring fracture for the buried southern margin of the Virgin Valley caldera and along northwest- and north-northeast–trending faults related to trapdoor uplift within the Badger Mountain caldera. Associated with these lavas are small-volume crystal-rich, alkali rhyolite ignimbrites and fall deposits, the tuffs of Alkali Flat and Badger Mountain (Mtab), which erupted between ca. 15.85 and 15.7 Ma, and mostly ponded within the Badger Mountain caldera.
Contemporaneous with renewed magmatism in the Badger Mountain caldera, aphyric and weakly porphyritic alkali rhyolite magmas were erupting at the youngest and southernmost major caldera in the HRCC, the Cottonwood Creek caldera (Fig. 5). We propose that it collapsed on eruption of the newly identified tuff of Yellow Rock Canyon (Miyc) at 15.70 Ma. The tuff of Yellow Rock Canyon is the most strongly zoned ignimbrite in the HRCC, ranging from crystal-poor, high-silica alkali rhyolite to trachyte with ∼10% phenocrysts. In contrast to other calderas at the HRCC, the volume of aphyric and crystal-poor precaldera and postcaldera ring-fracture alkali rhyolite lavas of Cottonwood Creek (Mlcc), ∼220 km3, greatly exceeds the estimated volume of the outflow ignimbrite, ∼50 km3, though the latter is a minimum estimate due to its poor preservation.
The youngest eruptions of alkali rhyolite lavas along the Cottonwood Creek caldera ring fracture occurred a few tens of thousands of years after caldera collapse, and ceased by ca. 15.6 Ma; the youngest of the uplift-related rhyolitic lavas in the Badger Mountain caldera are ca. 15.5 Ma. These eruptions marked the cessation of peralkaline rhyolitic volcanism in the HRCC, followed by eruption between ca. 15.5 and 14.2 Ma of alkalic mafic lavas inside the Cottonwood Creek and Badger Mountain calderas and trachytic intermediate lavas along the southern ring fracture of the Hanging Rock caldera. Also during this interval, chemically distinct, small-volume metaluminous rhyolite lavas erupted within the Hanging Rock and Virgin Valley calderas.
Erosion due to draining of three lakes that occupied the overlapping Hanging Rock and Badger Mountain calderas, the Cottonwood Creek caldera, and the Virgin Valley caldera removed most of the caldera fill deposits, and carved striking gorges through ring-fracture lavas at High Rock Canyon (of emigrant trails fame), Little High Rock Canyon, and Thousand Creek Gorge, respectively. In the northern part of the HRCC the mid-Miocene volcanic and sedimentary rocks are covered and preserved by mesas capped by nearly flat-lying late Miocene high-Al olivine tholeiite lavas.
GEOCHEMISTRY AND PETROGRAPHY
Silicic Lavas and Ignimbrites
Mineralogy of Silicic Units
The phenocryst contents and assemblages of the major silicic units are summarized in Table 2. The vast majority of the silicic rocks are moderately peralkaline alkali rhyolites (Fig. 6) characterized by a single feldspar, sodic sanidine, as a near-liquidus phase. Rhyolites with >5%–8% crystals also contain phenocrystic quartz, with the ratio of sanidine to quartz decreasing with increasing abundance of phenocrysts. Trachytes either lack quartz or have feldspar:quartz > 10. In the low-silica alkali rhyolite of the Summit Lake Tuff, the alkali feldspar phenocrysts are anorthoclase (Fig. 9), with small amounts of resorbed plagioclase visible in thin sections (Fig. 10). In many of the ignimbrites, alkali feldspar and quartz phenocrysts are transparent in nonwelded to partially welded exposures, but in densely welded and devitrified specimens the feldspars are adularescent blue and the quartz is gray, dark gray, to nearly black.
Mafic phenocryst phases are sparse and difficult to see in hand specimen in the silicic rocks, except in pumiceous specimens, and are commonly strongly altered in vapor phase or silicified rocks; thus, they are only rarely diagnostic for mapping purposes. In thin section (Fig. 10), the porphyritic rhyolitic samples contain some combination of sodic clinopyroxene, sodic amphibole, and/or opaque Fe-Ti oxides (typically oxidized and exsolved). Sodic clinopyroxene is aegirine augite in rhyolitic compositions and sodic augite in trachytic compositions, where it can occur with fayalitic olivine. The more evolved alkali rhyolites contain phenocrysts of Ca-Na amphibole (Fig. 9). Chevkinite is prominent in a few rhyolitic samples, and zircon is present in most units as inclusions within or surrounding Fe-Ti oxides or clinopyroxene. Biotite phenocrysts occur in small amounts in the low-silica alkali rhyolite of the Summit Lake Tuff, were reported in the Soldier Meadow Tuff by Korringa (1973), and are relatively abundant in the late-stage metaluminous rhyolite lavas.
The most common vapor-phase minerals are tridymite, alkali feldspar, and Na amphibole (Fig. 9). Vapor-phase tridymite can be distinguished from phenocrystic quartz by its purple color and/or bipyramidal form. Vapor-phase hematite and zircon have also been found.
Fine-grained sodic clinopyroxene in the groundmass of devitrified lavas and densely welded ignimbrites can make fresh surfaces have a greenish tinge. This is most prominent in the Mahogany Mountain lavas. Similarly, the presence of fine-grained Na amphibole (riebeckite) causes a bluish cast, most obvious in the moderately peralkaline Soldier Meadow Tuff. In contrast, most of the weathered surfaces of devitrified rhyolitic rocks are dark reddish-brown due to oxidation of the abundant iron that characterizes these peralkaline compositions.
Whole-Rock Compositions of Silicic Units
Rhyolitic rocks in the HRCC range from metaluminous to moderately peralkaline. None are as strongly peralkaline or as rich in iron as pantellerites (Table 3; ). The usual indicator of magma peralkalinity, the agpaitic index (mol [Na2O + K2O]/Al2O3), is not an accurate measure in most of the silicic rocks due to vapor-phase crystallization in ignimbrites and lavas, widespread weak silicification of ring-fracture lavas, and hydration of pumice lapilli. Instead, we estimate the peralkalinity based on the concentration of Zr, a high field strength element (HFSE) that is relatively resistant to the effects of hydration, weathering, and weak hydrothermal alteration. Zr behaves as an incompatible element because zircon is not abundant due to the large solubility of zircon in peralkaline melts (Watson and Harrison, 1983). We characterize as mildly peralkaline those rhyolites that have ∼240–500 ppm Zr, because fresh, unaltered samples with these values typically have agpaitic indices of 1.01–1.05. Those rhyolites with ∼500–1100 ppm Zr are moderately peralkaline, with agpaitic indices of 1.05–1.15.
The most abundant rocks in the HRCC are mildly to moderately peralkaline alkali rhyolite ignimbrites and lavas (Fig. 6), although both the youngest and oldest rhyolitic lavas are metaluminous. Late in the history of the complex, after nearly all the volume of rhyolitic magmas had been erupted, crystal-poor intermediate lavas ranging from trachyte to trachyandesite erupted in the Hanging Rock and Badger Mountain calderas.
Due to the fact that many of the rhyolitic magmas approach minimum-melt compositions in the Q-Ab-Or system, SiO2 is not a good measure of degree of magma differentiation. Incompatible trace elements (e.g., Zr, Rb, and Th) are a better measure. Declining TiO2 is a good proxy for degree of differentiation except in the most evolved silicic rocks, where the tiny proportion of mafic phenocrysts results in TiO2 being buffered at a near-constant value (Fig. 11A). FeO* has a variable behavior at the HRCC because the inverse covariation of fO2 and peralkalinity among suites results in it being incompatible, weakly compatible, or a strongly compatible element (Fig. 11A).
On a plot of Zr versus Rb (Figs. 11B and 12), two incompatible elements in these zircon-poor rocks, the HRCC ignimbrites form arrays with different slopes. Although some fraction of the dispersion along the arrays can be explained by crystal concentration in densely welded ignimbrites, the fact that different units have very different slopes on some bivariate plots (e.g., TiO2 versus FeO* or Ba versus Zr) (Figs. 11 and 12B) proves that most of the arrays are a result of compositional zoning in magma bodies prior to eruption. Although most of the HRCC ignimbrites display a range in trace element concentrations on bivariate plots, we have identified systematic variations in composition with stratigraphic height and sectoral emplacement for only two: (1) the Idaho Canyon Tuff is zoned from crystal-poor to crystal-rich high-silica rhyolite in the later erupted, stratigraphically higher part; and (2) the tuff of Yellow Rock Canyon is zoned from crystal-poor high-silica rhyolite to trachyte with 10% phenocrysts (Table 2; Figs. 6, 11, and 12).
The presence of compositional zoning that results in different slopes and offsets of elemental ratios on bivariate plots makes it possible to distinguish similar-looking ignimbrites and correlate far-flung exposures. These plots were also used to assign lavas to eruptive groups and to calderas. Bivariate plots using Zr, Rb, Th, Zn, Ba, FeO*, and TiO2 proved to be the most useful, with the caveats that anomalously high Rb values can occur in strongly hydrated pumice lapilli sampled from ignimbrites and fall deposits, and that the Ba analyses are neither accurate nor precise at concentrations below ∼50 ppm. In addition, we found that analyses of Ba, Th, Nb, Y, and the light rare earth elements (REE) are subject to nugget effects due to the high concentration of Ba in alkali feldspar and the other elements in accessory phases.
Mafic and Intermediate Lavas
Mafic and intermediate lavas are greatly subordinate in the HRCC. Pre-HRCC mafic lavas of known mid-Miocene age include the Steens Basalt in small volume on the east side of the complex and transitional olivine basalts and intermediate lavas and associated phreatomagmatic deposits on the northwest and southwest side. Postcaldera alkalic mafic and intermediate lavas erupted in the Cottonwood Creek, Hanging Rock, and Badger Mountain calderas for ∼1 m.y. following cessation of main-stage silicic volcanism. Much later, high-Al olivine tholeiite lavas that erupted from vents north of the HRCC flowed over parts of the Virgin Valley and Badger Mountain calderas.
On many published and unpublished maps, isolated exposures of mid-Miocene basaltic lavas in and around the HRCC have been mapped as the Steens Basalt. We adopted the suggestion of Camp et al. (2013) that the term Steens Basalt be restricted to lavas in physical continuity with the thick sections at Steens Mountain and in the Pueblo Mountains. In the area around the HRCC, most of the Steens Basalt lavas are phenocryst-poor, dense, microcrystalline rocks, which makes it easy to distinguish them from mid-Miocene olivine basalts that contain conspicuous olivine and plagioclase phenocrysts, and the younger 10–1 Ma high-Al olivine tholeiites, which are uniformly diktytaxitic and less weathered.
In Figures 6 and 13–15 we plot compositions of Steens Basalt lavas that are immediately adjacent to the HRCC as local Steens Basalt in order to distinguish them from the compositions of samples collected to the north and closer to the type section (e.g., Hart et al., 1989; Johnson et al., 1998; Camp et al., 2013). The Steens Basalt has been informally subdivided into two compositionally distinct members (Johnson et al., 1998; Camp et al., 2003, 2013): lower Steens lavas are olivine tholeiites, whereas upper Steens lavas are generally more evolved and more alkalic, including transitional basalts, alkali basalt, trachybasalt, and trachybasaltic andesite. The Steens Basalt lavas adjacent to the HRCC belong to the more alkalic upper member.
Precaldera Transitional Olivine Basalts and Intermediate Lavas
Silicic volcanic rocks of the HRCC overlie mafic and intermediate lavas widely at the edges of the complex, but only a few of these lavas have been dated precisely. The transitional olivine basalts adjacent to the HRCC that we interpret based on the available ages and on stratigraphic relationships to be mid-Miocene in age are easily distinguished chemically from Oligocene basalts and intermediate lavas, which have much higher ratios of large ion lithophile elements/HFSE. The known and presumed mid-Miocene lavas we have analyzed overlap the field of Steens Basalt on the TAS diagram (Fig. 6), but their concentrations of Zr and TiO2 (Figs. 13 and 14) are too low to be considered Steens Basalt.
Immediately Postcaldera Alkalic Mafic and Intermediate Lavas
Mafic lavas that erupted in the calderas between ca. 15.5 and 14.2 Ma, shortly following cessation of most of the silicic volcanism, are exclusively alkalic, ranging from alkali basalt to trachybasaltic andesite. Most are phenocryst poor (0%–8%) with an aphanitic or microcrystalline groundmass. Alkali basalts typically contain small (∼1 mm) olivine phenocrysts, whereas more evolved compositions have 1%–5% clinopyroxene and/or plagioclase phenocrysts with only trace olivine.
The mafic lavas overlap the range of the alkalic upper Steens Basalt on the TAS diagram (Fig. 6), but contain higher P2O5, Ba, and Sr and lower Zr and TiO2 and lower Zr/Ba than Steens Basalt (Fig. 14; Table 4). They have chemical similarities to a stack of somewhat older alkalic basalts that erupted 16.6–16.0 Ma in the Buffalo Hills and Smoke Creek region of northwestern Nevada, southwest of the HRCC, and to the small volumes of basalt in the northern Nevada rift (Camp et al., 2013) that erupted between 16.5 and 15.0 Ma (John et al., 2000).
Intermediate lavas, ranging in composition from trachyandesite to trachyte (Fig. 6), erupted along trapdoor uplift–related faults in the Badger Mountain caldera and in relatively large volumes from vents within and along the southern ring fracture of the Hanging Rock caldera (Fig. 4). The trachytic lavas are weakly porphyritic with 2%–8% total phenocrysts of feldspar, clinopyroxene, fayalitic olivine, and Fe-Ti oxides in variable proportions in an aphanitic or microcrystalline groundmass. Feldspar phenocrysts are typically resorbed, which along with the presence of quartz phenocrysts, suggests that there was magma mixing involving entrainment of rhyolitic magma. Despite being crystal poor, all four of the intermediate rocks we analyzed for REEs (MC248, MC300, MC321, and MC390 in Table 4) have pronounced positive Eu anomalies (Fig. 14), suggesting that their current phenocryst-poor state and exceedingly fine grained groundmass comes from a preeruptive heating by hotter magma that caused cumulate feldspars to be resorbed. That these lavas represent mobilization of feldspar-rich cumulates is supported by their extremely high concentrations of Ba, to nearly 10,000 ppm (Table 4).
Late Miocene to Quaternary High-Al Olivine Tholeiite Lavas
Thin, flat-lying lavas of olivine basalt form mesas in the northern part of the HRCC, and postdate all the mid-Miocene volcanism (shown in Figs. 3 and 4 as part of NQm: undifferentiated Neogene–Quaternary deposits). Chemically, they are similar to other lavas in the region that have been termed high-alumina olivine tholeiite (HAOT of Hart et al., 1984) or low-K olivine tholeiite (e.g., Carmichael et al., 2006) (Table 4; Fig. 14). The high-alumina olivine tholeiites contain a distinctive diktytaxitic groundmass texture in which angular vesicles occur between groundmass grains of olivine, augite, plagioclase, and minor oxides. Phenocryst content varies between flows, but most contain very small (<0.5 mm) subhedral to anhedral olivine (1%–8% vol%) and plagioclase (0–4 vol%).
LANDSCAPE PRIOR TO DEVELOPMENT OF THE HRCC
Based on the distribution of Miocene ignimbrites and lavas, the landscape prior to eruptions at the HRCC does not appear to have been one of great relief. The current generation of Basin and Range faulting and tilting that created the steep eastern scarp of the Pueblo Mountains and the elevation of the Pine Forest Range postdates volcanism at the MVF and HRCC, based on exposures of Steens Basalt and ignimbrites from the MVF in the tilted section on the west sides of these ranges (Figs. 3 and 4). Our mapping and geochronology suggest that HRCC lavas and ignimbrites and the immediately preceding Steens Basalt erupted onto a hilly topography developed on Paleogene volcanic rocks, and that Paleogene volcanic edifices influenced the distribution pattern of the mid-Miocene ignimbrites (Figs. 3 and 4).
The oldest Cenozoic rocks in the region surrounding the HRCC are Eocene to Oligocene volcanic and volcaniclastic units. West of the HRCC, the Warner Mountains and Hays Canyon Range (Fig. 2) contain andesite and basaltic lavas with subduction-related chemical affinities, along with thick sections of volcaniclastic sediments and lahars, indicative of an ancestral Cascades arc setting (Duffield and McKee, 1986; Carmichael et al., 2006; Colgan et al., 2011; Egger and Miller, 2011). Paleogene volcanic rocks are present immediately south of the complex (Fig. 3), where they are extensively exposed in the Calico Mountains (Bonham and Papke, 1969; this study). To the east in the Pine Forest Range, they consist of rhyolitic ignimbrites, subordinate silicic lavas, and rare basalt and basaltic andesite lava flows (Noble et al., 1970; Colgan et al., 2006; Lerch et al., 2008). Most are calc-alkaline to alkali-calcic in composition, characterized by the presence of plagioclase and biotite phenocrysts in felsic rocks. There are, however, mildly peralkaline Oligocene rhyolites similar in composition to the rhyolites of the HRCC: the Ashdown Tuff and tuff of Alder Creek (Colgan et al., 2006; Lerch et al., 2008).
On the east side of the HRCC, mid-Miocene ignimbrites appear to have been influenced by a north-northeast–trending basin in what is now the area of Bog Hot Valley, Craine Creek Valley, and the northern Black Rock Desert (Fig. 3). We interpret the thick section of Idaho Canyon Tuff in the northern Black Rock Range and the tuff of Trough Mountain to have ponded in this north-northeast–trending paleobasin, which also seems to have controlled the distribution of the Summit Lake Tuff and Soldier Meadow Tuff (Fig. 4). We interpret the sediments in this north-northeast–trending basin, now largely removed by erosion, to have formed the eastern topographic wall for the Virgin Valley caldera. The presence of an active alluvial channel in the mid-Miocene west of what is now the southern Pueblo Mountains and northern Pine Forest Range may account for the relative lack of exposures of the caldera-forming unit, the Idaho Canyon Tuff , northeast of the caldera (Fig. 4).
Preexisting topography, albeit of low relief, also influenced the distribution of the Oregon Canyon Tuff and other ignimbrites from the MVF. They overtopped a low divide between what is now the southern Pueblo Mountains and the northern Pine Forest Range, but most of the volume of these units was confined to the east (Figs. 3 and 4).
Although the presence of a north-northeast–trending paleobasin and the partial confinement of MVF outflow ignimbrites are consistent with post-Oligocene, pre–16.5 Ma normal faulting, the magnitude of such faulting must have been small. Early Miocene sediments preserved beneath high-alumina olivine tholeiite lavas at Oregon End Table and Big Springs Table and on both sides of Craine Creek Valley (Fig. 4) consist of silt- to pebble-sized clasts, indicating that the relief was not great enough to generate coarse debris. Most of the identifiable clasts are silicic volcaniclastic rocks derived from mid-Miocene and Paleogene volcanic rocks. Modern Craine Creek Valley, in contrast, contains coarser deposits of sand- to cobble-sized clasts that include granitic and metamorphic rocks in addition to volcaniclastic debris, presumably due to the relief produced by late Miocene to Holocene uplift of the Pine Forest and Black Rock Ranges that exposed the basement. This faulting may have reactivated pre–16.5 Ma faults, particularly in the Black Rock Range.
GEOLOGIC HISTORY OF THE HRCC
Overall, there is a paucity of precaldera volcanism at the HRCC. This statement has to be qualified by the fact that there may be precaldera volcanism covered on the north and west by late Miocene high-Al olivine tholeiite lavas and obscured in the interior of the complex by successive caldera collapse.
The nearest exposures of known Steens Basalt are east of the HRCC in the southern Pueblo Mountains (Hart et al., 1989) and the northern Pine Forest Range (Colgan et al., 2010). There are undated lavas mapped as Steens Basalt that underlie outflow ignimbrites further south in the Pine Forest Range, Idaho Canyon, and in the northern Black Rock Range (Figs. 3 and 4), but this correlation has been confirmed chemically only on the east side of Craine Creek Valley and in Idaho Canyon (Figs. 3 and 4), where both have chemical similarities to upper Steens Basalt (Figs. 13–15).
The section of Steens Basalt lavas thins abruptly south of the Oregon-Nevada border (Lerch et al., 2008) from nearly 1 km in the northern Pueblo Mountains (Hart et al., 1989) to ∼550 m in the northern Pine Forest Range (Colgan et al., 2010). In a fault scarp on the east side of Idaho Canyon (Figs. 3, 4, and 16), ∼80 m of Steens Basalt is present; the base is unexposed. In the northern Black Rock Range, the Steens Basalt is ∼150 m thick. South of ∼41.55°N (Figs. 2 and 3), however, the Steens Basalt is, to our knowledge, absent, and outflow ignimbrites from the HRCC and MFV directly overlie Paleogene sedimentary and volcanic rocks (Lerch et al., 2008; this study) in the Black Rock Range and Calico Mountains (Fig. 3).
Mid-Miocene Mafic and Intermediate Lavas
Mafic and intermediate lavas that are not petrographically Steens Basalt directly underlie HRCC rhyolitic lavas near Massacre Creek, Wall Canyon Reservoir, and Nellie Spring Mountain, and are found beneath outflow ignimbrites in the Calico Mountains (Figs. 3 and 4). Based on the available chemistry and their petrography and geologic occurrence, we believe that all of these lavas except those near Wall Canyon Reservoir are Paleogene, although this remains to be proved. We obtained a 40Ar/39Ar age of 16.55 ± 0.56 Ma from a transitional olivine basalt lava near Wall Canyon Reservoir (AT6 in Table 4; Fig. 4). It underlies lavas from the Cottonwood Creek caldera, which our dating indicates erupted between 15.9 and 15.6 Ma. See the Supplemental Text File for new 40Ar39Ar ages and a discussion of other precaldera mafic and intermediate units in Nellie Spring Mountain and at Massacre Rim.
Hawks Valley—Lone Mountain volcanic center 16.5–16.3 Ma. There is significant silicic activity of mid-Miocene age 10 km north of Virgin Valley caldera at the Hawks Valley–Lone Mountain center (Figs. 3 and 4), for which Wypych et al. (2011) reported 40Ar/39Ar plateau ages for trachydacitic and rhyolitic lavas that range from 16.51 ± 0.25 to 16.33 ± 0.17 Ma. It remains to be demonstrated through further mapping and more precise geochronology whether this center contains a caldera and how it relates to the HRCC. We include it within precaldera volcanism because distal outflow of the first major ignimbrite from the HRCC, the 16.38 Ma Idaho Canyon Tuff, banks in against silicic lavas at the Hawks Mountain massif (Fig. 3). This age relationship is consistent with the southward younging of the initiation of activity within the HRCC.
Rhyolite lavas of Nut Mountain (Mlnm) 16.6 Ma. The oldest rhyolitic unit in the HRCC proper is the rhyolite lavas of Nut Mountain (Mlnm), which emanated from a large cumulodome centered at Nut Mountain (Figs. 3 and 4). The lavas are aphyric and typically finely devitrified and strongly flow foliated. Obsidian nodules to 25 cm in diameter are ubiquitous in talus at the base of outcrops or as subcrop, and the dark gray, opaque, and slightly resinous luster of the obsidian is unique at the HRCC. Mlnm are metaluminous high-silica rhyolite in composition, setting them apart from the alkali rhyolites that dominate the main stage of silicic volcanism at the HRCC. As such, they contain the lowest measured concentrations of HFSE elements and have relatively elevated Ba and Sr (Table 3).
A sample of aphyric devitrified lava (MC341) from Nut Mountain yielded an inverse isochron age of 16.59 ± 0.15 Ma. Nut Mountain is one of the few units in the HRCC that has a normal paleomagnetic polarity (Fig. 17). This age is consistent with Nut Mountain lavas having erupted during the C5Cr chron. The 25 × 15 km positive aeromagnetic anomaly centered on Nut Mountain (Fig. 18) suggests that Nut Mountain lavas extend west beneath younger eruptive units to cover an area at least twice that of the current 7-km-diameter exposure.
Idaho Canyon Tuff (Miic) 16.38 Ma
The first major ignimbrite known to erupt from the HRCC is the Idaho Canyon Tuff, which resulted in collapse of the Virgin Valley caldera. It was named formally by Noble et al. (1970) for exposures in Idaho Canyon (Figs. 3, 4, and 16). The ignimbrite is typically strongly welded and devitrified, with distinctive well-developed postdepositional revesiculation cavities 5–30 cm in diameter (Fig. 19). Lithics are rare, but are most abundant near Virgin Valley, where they are mostly devitrified rhyolite or mafic lava fragments <2 cm in size.
The Idaho Canyon Tuff is zoned from crystal-poor (∼4–8 vol%) high-silica alkali rhyolite (Miica) to slightly more mafic, crystal-rich (∼15–20 vol%), high-silica alkali rhyolite (Miicb) (Figs. 11 and 12; Table 2). The zoning is best displayed at the mouth of Idaho Canyon (Figs. 16 and 19), where the strongly welded ignimbrite overlies crystal-poor Steens Basalt and ∼25 m of pyroclastic deposits. Approximately 125 m of crystal-poor, purplish-gray Miica grades sharply at the top of the section into an ∼11-m-thick section of crystal-rich, dark gray to dark brown Miicb. Lithics are more abundant (5%–8%) and slightly larger (1–5 cm) in Miicb. Both Miica and Miicb span a range of compositions (Fig. 12) and phenocryst abundance, but the obvious quartz and small feldspars of Miica contrast with the larger and more abundant feldspar and the general absence of quartz characteristic of the slightly less evolved Miicb.
The most extensive exposure of the ignimbrite, northwest of Virgin Valley (Figs. 3–5) consists entirely of Miica, where fresh surfaces are tan to pinkish-gray, and the densely welded and revesiculated portions weather to a deep reddish-brown. Exposures in Catnip Creek indicate that the outflow sheet is at least 80–100 m thick near the Virgin Valley caldera, where it consists of a single cooling unit with a characteristic tripartite massive-revesiculated-massive section (Fig. 19). To the north, several welding reversals become apparent, and where it laps against rhyolitic lavas of the Hawks Valley–Lone Mountain center, the ignimbrite is ∼10 m thick. Miicb is best exposed in the scarp that extends from Idaho Canyon to south of McGee Mountain and in the northwesternmost Black Rock Range in the headwaters of Craine Creek, where it is densely welded. Thin, partially welded deposits occur locally in the westernmost Pine Forest Range.
We obtained 40Ar/39Ar ages on sanidine of 16.39 ± 0.02 Ma (MC273) and 16.37 ± 0.02 Ma (MC502) for densely welded samples of outflow Miica collected at Idaho Canyon and near Sage Hen Hills ∼12 km northwest of the Virgin Valley caldera, respectively, and 16.37 ± 0.02 Ma (MC274) on Miicb collected stratigraphically above Miica at Idaho Canyon (Table 1). All 3 ages agree within 2σ error with the 40Ar/39Ar age of 16.40 ± 0.04 Ma reported by Castor and Henry (2000) for strongly welded Idaho Canyon Tuff exposed at the base of McGee Mountain (H95–74 in Fig. 4). We recollected the densely welded, crystal-rich exposure at their H95–74 locality (MC500), and, on analysis, found it to have the low Rb, Zr, Th, and Nb, and high Ti and Ba concentrations characteristic of Miicb (Figs. 11 and 12).
See the Supplemental Text File for a discussion of how we have distinguished Idaho Canyon Tuff Miica from the slightly older Oregon Canyon Tuff sourced from the MVF (Rytuba and McKee, 1984), and Miicb from the similar looking, but slightly younger Summit Lake Tuff.
Summit Lake Tuff (Misl) 16.34 Ma
The Summit Lake Tuff (Misl) is a strongly porphyritic (25–32 vol%) low-silica alkali rhyolite ignimbrite, the eruption of which resulted in collapse of the proposed Badger Mountain caldera. The ignimbrite was described and named formally by Noble et al. (1970) for exposures near Summit Lake. Although exposures are generally thin (5–25 m), the Summit Lake Tuff has the largest areal distribution of the mid-Miocene ignimbrites in the HRCC (Fig. 5), and has an estimated volume of 31 km3. It typically forms dark gray or dark brown rounded ledges of a single densely welded cooling unit (Fig. 20) with well-developed eutaxitic texture. Postwelding revesiculation cavities and lithophysae are common, and can be tens of centimeters in diameter. Lithic fragments typically make up 3%–5% of the rock, and are predominantly basaltic lava, with subordinate devitrified rhyolite and obsidian nodules. Talus and modern soils derived from the Summit Lake Tuff are distinctively crystal rich. The abundance of anorthoclase crystals, paucity of quartz (those present are xenocrystic), and dark color distinguish the Summit Lake Tuff from other HRCC ignimbrites.
We obtained a 40Ar/39Ar age of 16.34 ± 0.02 Ma on anorthoclase from the Summit Lake Tuff (MC85, Fig. 7) collected from near the type locality north of the Summit Lake Reservation (Figs. 3 and 4). We also obtained ages on 2 additional densely welded localities: 16.35 ± 0.02 Ma (MC611) from south of the summit of Nut Mountain, and 16.29 ± 0.03 Ma (MC263) from south of High Rock Lake. A sample of pumice lapilli from vapor-phase–altered, nonwelded ignimbrite 5 km east of MC263 yielded an age of 16.31 ± 0.03 Ma (MC365).
Our preferred age of 16.34 Ma for the caldera-forming Summit Lake Tuff is based on the age for MC85, which was coirradiated and analyzed as an internal standard with all other eruptive units analyzed in this study. This age is stratigraphically consistent with the field observations that the Summit Lake Tuff directly overlies the 16.6 Ma lavas from Nut Mountain and the 16.38 Ma Idaho Canyon Tuff (Figs. 4 and 21). It is indistinguishable from the age of 16.33 ± 0.03 Ma (H06–18) reported in Smith (2011) for a sample collected north of Summit Lake and analyzed at the New Mexico Geochronology Research Laboratory.
See the Supplemental Text File for a discussion of an ignimbrite with anomalously old ages tentatively mapped as Summit Lake Tuff in Massacre Creek and near Massacre Rim, and its possible correlation with the tuff of Big Basin of Swisher (1992).
Alkali Rhyolite Lavas of Catnip Mountain (Mlcm) 16.3 Ma
Catnip Mountain is a large composite lava dome consisting of aphyric, moderately peralkaline, high-silica alkali rhyolite lavas (Figs. 4 and 5). Greene (1984) informally named the lavas the Catnip rhyolite, and included within it the weakly porphyritic lava of Echo Canyon that we have assigned to the Hell Creek lavas. Devitrified exposures exhibit very strong millimeter- to centimeter-scale chaotic flow foliation. Poorly developed pressure ridges make it difficult to determine vent locations for individual flows. Black nodules of nonhydrated obsidian are locally abundant as a lag on surfaces. The obsidian is transparent on thin edges, whereas obsidian from the older Nut Mountain lavas is opaque.
We obtained an inverse isochron age of 16.31 ± 0.13 Ma from aphyric, devitrified, alkali rhyolite lava (MC504) sampled west of Catnip Mountain (Table 1; Fig. 8). Given the relatively large uncertainty on the age for the devitrified matrix of this aphyric lava, we cannot resolve it from the ages of the Idaho Canyon Tuff and Summit Lake Tuff or from the ages for the Hell Creek lavas (discussed in the following sections). We map the alkali rhyolite lavas of Catnip Mountain separately from aphyric Hell Creek lavas of similar age because the Catnip Mountain lavas are chemically distinct, with higher Zr/Rb ratios (Fig. 5). We interpret exposures along Nevada State Route 140 to indicate that Catnip Mountain lavas overlie the Idaho Canyon Tuff. The age relation relative to the Summit Lake Tuff is unknown because the two units are not exposed nearby. See the Supplemental Text File for a discussion of additional 40Ar/39Ar ages, unit correlations, and chemistry.
Alkali Rhyolite Lavas of Hell Creek (Mlhc) 16.3–16.2 Ma
Aphyric and weakly porphyritic high-silica alkali rhyolite lavas that erupted in the western part of the Virgin Valley caldera and along the southern ring fracture and west of the Badger Mountain caldera (Figs. 4, 5, and 21) are newly recognized and informally named the alkali rhyolite lavas of Hell Creek (Mlhc). The total eruptive volume of these lavas is ∼12 km3. We obtained sanidine ages of 16.31 ± 0.03 Ma (MC430) and 16.29 ± 0.02 Ma (MC244, Fig. 7) for lavas at Hanging Rock Canyon and Echo Canyon, respectively. We also analyzed sanidine separated from a strongly porphyritic magmatic enclave slightly more mafic than its aphyric host near Hell Creek and obtained an age of 16.22 ± 0.02 Ma (MC433). We interpret the range of ages to reflect eruptions of chemically similar lavas over ∼30–100 k.y. See the Supplemental Text File for a description of the distribution and field attributes of Mlhc lavas.
Tuff of Big Mountain (Mtbm) and Alkali Rhyolite Antelope Lavas (Mla) 16.3–16.1 Ma
Closely following and in part contemporaneous with eruption of the Catnip and Hell Creek lavas, less peralkaline lavas vented within the Virgin Valley caldera in association with eruptions of small ignimbrites, falls, and surges (Fig. 5). The weakly peralkaline, moderately porphyritic (8–10 vol%) alkali rhyolite lavas, which we have informally named the alkali rhyolite Antelope lavas, are interpreted as ring-fracture lavas (Castor and Henry, 2000), based on the arcuate pattern of vent locations partially encircling Virgin Valley (Fig. 4). Lava flows at lower elevations were covered by and interfingered with caldera lake sediments, resulting in highly silicified outcrops that weather rust-red or bright red. Antelope lavas exposed near the tops of McGee Mountain and Big Mountain have an appearance more typical of lavas in the HRCC. A large dike exposed in the east-facing fault scarp on the northeast side of Big Mountain (rhyolite dike, Tcrd, of Greene, 1984) has more phenocrysts than the typical Antelope lavas (∼15% versus 5%–10%) and is fresher; we interpret it as a feeder for the youngest lava capping Big Mountain.
Intercalated with the Antelope lavas are small ignimbrites, fall and surge deposits, and minor reworked volcaniclastic sedimentary intervals that make up the tuff of Big Mountain (Greene, 1984; Castor and Henry, 2000; this study). This unit name was originally applied by Noble et al. (1970) to the most conspicuous eruptive unit in the tuff, a crystal-poor (2–5 vol%) ignimbrite with a small areal extent near Big Mountain (Figs. 3, 4, 16, and 22). The ignimbrite is mostly nonwelded, with white pumice lapilli 3–15 cm in diameter, forming rounded light pink or light gray hoodoos and talus slopes; however, the upper 4–20 m is weakly to moderately welded, vapor-phase altered, salmon-colored on weathered surfaces, and incipiently columnar jointed (Fig. 22). It is relatively lithic rich (7%–12%), containing clasts to 6 cm in diameter of mafic lava, devitrified rhyolitic lava, and crystal-rich, densely welded ignimbrite, which are locally concentrated in layers.
We obtained an age of 16.25 ± 0.03 Ma (MC413) for a sample of alkali rhyolite Antelope lavas located low on the southeast side of McGee Mountain, which overlaps the 40Ar/39Ar age of 16.27 ± 0.04 Ma reported by Castor and Henry (2000) for a lava low on the northwest side. Castor and Henry (2000) reported a 40Ar/39Ar age of 16.20 ± 0.04 Ma for an Antelope lava high on McGee Mountain, and a similar age of 16.23 ± 0.03 Ma for ignimbrite below it. We obtained an age of 16.13 ± 0.03 Ma (MC326) for sanidine extracted from pumice lapilli in the main ignimbrite south of Big Mountain, which we interpret as the age of emplacement of the Antelope lava making up Big Mountain.
The compositions of Antelope lavas and pumice from the tuff of Big Mountain are similar regardless of age (Fig. 8), which suggests that the tuff of Big Mountain is composed of relatively small volume ignimbrites, falls, and surge deposits that erupted in association with emplacement of the Antelope lavas along the ring fracture of the Virgin Valley caldera over an extended period of time, perhaps 100 k.y.
The tuff of Big Mountain is ∼150 m thick in the cliff west of Idaho Canyon, but it is absent immediately east of Idaho Canyon and south of Rock Spring Table, suggesting that it is preserved only where it is overlain by Antelope lavas. We interpret the tuff of Big Mountain as representing subaerial and minor littoral deposits at the margin of the caldera lake filling the Virgin Valley caldera; fine-grained, diatomaceous, ashy sediments indicative of a deep caldera lake environment accumulated in the depocenter in Virgin Creek (Fig. 3).
Our work suggests there are tuffs in the caldera fill section that are both older and younger than the Antelope lavas, and that the caldera fill records input from sedimentary and volcanic sources from the time of caldera collapse on eruption of the Idaho Canyon Tuff at 16.38 Ma until the end of most rhyolitic volcanism at 15.5 Ma. See the Supplemental Text File for further information on these tuffaceous deposits and the ages of units within them.
Tuff of Coyote Spring (Mics) 16.27 Ma
More or less simultaneously with ring-fracture eruption of the weakly peralkaline alkali rhyolite Antelope lavas and associated tuff of Big Mountain, more strongly peralkaline rhyolite lavas erupted along and near the southeastern ring fracture of the Badger Mountain caldera in a swath immediately north and northeast of the site of the future Hanging Rock caldera. Two ignimbrites that are similar in age and only slightly different in composition, the tuff of Coyote Spring and the tuff of Trough Mountain, also erupted in this area and may be related to scallop-shaped collapse features preserved between the older Badger Mountain caldera and the younger Hanging Rock caldera.
The tuff of Coyote Spring is a newly identified ignimbrite that is well exposed west of Wall Canyon and around Nut Mountain (Figs. 4, 5, and 21). The crystal-poor (5–9 vol%) ignimbrite is typically moderately to densely welded and devitrified, with a well-developed flattening foliation that causes exposures to weather into flaggy slabs. Outcrops are typically tan to gray, but can be light brown where intensely welded or silicified. Postdepositional revesiculation cavities 5–15 cm in diameter are common in more strongly welded sections. We estimate the exposed volume to be ∼5 km3 based on its restricted distribution and relatively thin exposures (∼10–25 m); however, given the dense welding, we suspect that the volume is much greater and that it is buried beneath younger ignimbrites, lavas, and caldera fill to the south and east.
We obtained ages of 16.27 ± 0.04 Ma and 16.27 ± 0.02 Ma for aliquots of sodic sanidine from a densely welded exposure west of Nut Mountain (MC302). This age is consistent with the tuff overlying the 16.6 Ma lavas of Nut Mountain and the 16.29 ± 0.02 Ma Hell Creek lava at Hanging Rock Canyon.
Tuff of Trough Mountain (Mttm) 16.25–16.15 Ma
The tuff of Trough Mountain (Mttm) was named informally by Noble et al. (1970) for the thick section exposed at Trough Mountain (Figs. 3 and 4). Although the bulk of the exposure is lithic-poor, crystal-poor (<6 vol%), densely welded, devitrified alkali rhyolite ignimbrite, the tuff of Trough Mountain is a composite unit consisting of multiple cooling units of nonwelded to densely welded ignimbrite and intercalated welded fall deposits and lavas intruded by petrographically similar north-south–trending rhyolite dikes that are presumably feeders for the upper part of the tuff (Korringa, 1973; this study). The unit has a restricted areal distribution centered on Trough Mountain, where it exceeds 325 m in thickness, and thins rapidly to <50 m within 10 km in all directions (Korringa, 1973). The presence of variably welded fall deposits containing lithic fragments as large as 60 cm in diameter (Korringa, 1973) requires a nearby vent to produce welding in peralkaline fall deposits (Mahood, 1984) and to account for large ballistic lithic blocks. In Slumgullian Creek, densely welded Mttm ignimbrite is overlain by 30 m of chemically similar coarse fall deposit, indicating that the vents are nearby and that the great thickness of Mttm at Trough Mountain is not a result of a far-traveled ignimbrite ponding in a basin. The poorly sorted fall deposits are characterized by white or tan pumice lapilli and by distinctive thick, dark green bubble-wall glass shards as large as 6 mm in diameter that are lacking in other HRCC deposits.
We attribute the restricted areal extent of the tuff of Trough Mountain and its rapid thinning away from Trough Mountain to the densely welded component of the ignimbrite having filled a depression, perhaps a caldera fragment or possibly a paleobasin that also controlled the distribution of the Summit Lake Tuff and the Soldier Meadow Tuff (Fig. 4). Partially welded distal deposits presumably were removed by erosion where they were not protected by younger capping units.
Consistent with the observation that the tuff of Trough Mountain consists of the products of more than one eruption, we have obtained 2 resolvably different ages on the unit: an age of 16.25 ± 0.03 Ma (MC212) from sodic sanidine extracted from a densely welded exposure ∼5 km north of Trough Mountain proper near the base of the section, and 16.15 ± 0.02 Ma (MC124) from a moderately welded exposure southeast of Summit Lake. All samples of the tuff of Trough Mountain define a trend on bivariate trace element plots (Figs. 11 and 12), suggesting that all the units included in the tuff were related to eruptions from a single magma reservoir over a period of ∼100 k.y. Samples of the tuff of Trough Mountain and Hell Creek lavas span a range of compositions with Rb/Zr ratios higher than those for the tuff of Coyote Spring and associated pre–Hanging Rock caldera lavas. They plot on a trend that is similar to the zoning in the Idaho Canyon Tuff (Figs. 5, 11, and 12), suggesting that they have affinities with a magma body related more closely to the Virgin Valley caldera than to the developing magma body beneath the Hanging Rock caldera.
See the Supplemental Text File for a discussion of distinguishing the petrographically similar tuff of Trough Mountain and tuff of Coyote Spring in the field.
Pre–Hanging Rock Caldera Alkali Rhyolite Lavas (Mlns, Mlmc, Mlwh) 16.2–16.1 Ma
We have mapped and chemically correlated three groups of crystal-poor alkali rhyolite lavas that occur south and southeast of the Badger Mountain caldera. New 40Ar/39Ar ages indicate that these lavas vented between 16.2 and 16.1 Ma, and several were truncated on collapse of the Hanging Rock caldera at 16.0 Ma (Figs. 4 and 5). These lavas include the 16.21 Ma low-silica alkali rhyolite lavas of Nellie Spring Mountain (Mlns), which are distinctive due to the presence of large sanidine (to 6 mm) and chevkinite (50–200 μm) and their lower silica content than most HRCC rhyolites, the 16.2 Ma aphyric alkali rhyolite lavas of Massacre Creek (Mlmc), and 16.1 Ma phenocryst-poor alkali rhyolite lavas of Wild Horse Pasture (Mlwh) (Table 1). See the Supplemental Text File for unit descriptions, a discussion of their 40Ar/39Ar ages, and how they are distinguished.
The lavas of Nellie Spring Mountain have compositions that plot between the Summit Lake Tuff and the tuff of Coyote Springs on bivariate plots, which, in turn, is very similar to the least-evolved composition erupted in the younger Soldier Meadow Tuff (e.g., Fig. 5). The Massacre Creek lavas and Wild Horse Pasture lavas have compositions similar to the tuff of Coyote Springs. We therefore interpret the pre–Hanging Rock caldera alkali rhyolite lavas and the tuff of Coyote Springs as erupting from a developing magma chamber that ultimately gave rise to the more voluminous Soldier Meadow Tuff and collapse of the Hanging Rock caldera.
Soldier Meadow Tuff (Mism) 16 Ma
The Soldier Meadow Tuff was named by Noble et al. (1970) and described by Korringa (1973) based on strongly welded exposures in the hills near Soldier Meadow (Figs. 3 and 4). It is distinctive in that it is phenocryst rich (40–50 vol%). It is typically strongly welded, with subequal amounts of adularescent sanidine and dark smoky-gray quartz phenocrysts. Extensive vapor-phase crystallization of sodic amphibole along flow foliations imparts a light bluish-green color to the rock. Incipiently welded ignimbrite is tan, light gray, or pale green on fresh surfaces, and typically contains >75% pumice lapilli and <5% lithic fragments composed of mafic lava. East of Soldier Meadow, nonwelded deposits grade upward over a distance of 1–2 m into strongly welded ignimbrite. At least 7 welding reversals can be identified in an ∼200 m fault-bound exposure of strongly welded Soldier Meadow Tuff north of Fly Canyon. These features are consistent with the relatively low viscosities of peralkaline magmas, which lead to abrupt variations in welding intensity as a function of accumulation rate (Mahood, 1984). In strongly welded outcrops, pyroclastic textures can be completely obscured by intense welding, devitrification, and vapor-phase crystallization; thicker deposits exhibit prominent columnar jointing and, more rarely, rheomorphism (Korringa, 1973). We estimate the volume of the Soldier Meadow Tuff to be ∼65 km3, including inferred deposits buried beneath the younger Cottonwood Creek caldera, based on large lithics within the tuff of Yellow Rock Canyon (described in the following sections).
We obtained ages of 16.00 ± 0.02 Ma (MC121) and 16.01 ± 0.02 Ma (MC369) for samples of Soldier Meadow Tuff from strongly welded exposures south of Mud Meadow Reservoir and southwest of High Rock Lake, respectively. The average radiogenic yield (%40Ar*) for both samples is >97%, resulting in caluclated ages that are very precise (Fig. 7). Our ages overlap at the 2σ level the range of less precise ages for Soldier Meadow Tuff reported by Smith (2011). An age of 16 Ma for the Soldier Meadow Tuff is consistent with the observations that the tuff overlies the 16.34 Ma Summit Lake Tuff and the 16.25–16.15 Ma tuff of Trough Mountain south and southeast of the Hanging Rock caldera, and is, in turn, overlain by a petrologically similar 15.91 Ma Soldier Meadow lava north of Soldier Meadow and by the 15.70 Ma tuff of Yellow Rock Canyon in Little High Rock Canyon and north of Fly Canyon.
We attribute formation of the Hanging Rock caldera to eruption of the Soldier Meadow Tuff at 16 Ma. This age is consistent with 16.20 Ma Massacre Creek lavas and a 16.29 Ma Hell Creek lava at Hanging Rock Canyon being cut by the northern topographic wall of the caldera. We interpret a lava for which Smith (2011) reported an age of 15.93 ± 0.07 Ma to have erupted on the caldera floor and to have banked against the Hanging Rock caldera topographic wall north of Grassy Rock Canyon (Figs. 4 and 5).
Alkali Rhyolite Soldier Meadow Lavas (Mlsm) 16.0–15.9 Ma
Noble et al. (1970) and Korringa (1973) noted the petrographic similarity between the Soldier Meadow Tuff and phenocryst-rich (∼40 vol%) lavas that erupted from a linear vent array north of Soldier Meadow (Figs. 3 and 4), and proposed that the lavas marked the vent for the Soldier Meadow Tuff. Although we believe that the distribution and welding relations of the Soldier Meadow Tuff are more consistent with it having vented from the southeastern segment of the ring fracture of the Hanging Rock caldera (Figs. 4 and 5), the close relationship between the ignimbrite and the lavas is supported by our 40Ar/39Ar age of 15.91 ± 0.02 Ma (MC315) for a lava sample from the linear vent array near Warm Spring Canyon, and 15.98 ± 0.02 Ma (MC213) for a chemically and petrographically similar lava dome northwest of Trough Mountain. Two additional lavas that erupted on the floor of the Hanging Rock caldera (Fig. 4) are included in this unit due to their chemical and petrographic similarity (Fig. 7) to the lavas erupted along the linear vent array. Smith (2011) reported a 40Ar/39Ar age of 15.93 ± 07 Ma for one of these lavas near Grassy Rock. We obtained an age of 16.14 ± 0.02 Ma (MC376) on a glassy, crystal-rich lava just north of Yellow Rock Canyon, and attribute its anomalous older age to inherited 40Ar, most likely because the lava erupted into a caldera lake and was quenched quickly. We interpret the ages of the Soldier Meadow lavas and their chemical and petrographic similarity to the Soldier Meadow Tuff (Fig. 9) to indicate that magma erupted as the lavas represented the further evolution of magma not tapped during eruption of the Soldier Meadow Tuff.
The Soldier Meadow lavas have well-developed meter-scale flow laminae, and contain sparse dark colored magmatic enclaves. Fresh devitrified surfaces are coarsely recrystallized and light gray, pale green, or light blue. Darker shades of blue and green characterize specimens from where the lavas were silicified as a result of erupting into a caldera lake. The lavas weather dark tan, brick red, or brown, except locally where they remain vitric due to having erupted into water.
Uplift and Renewed Magmatism in the Badger Mountain Caldera
Simultaneously with eruption of Soldier Meadow lavas, magmatism was occurring across the HRCC in two areas: to the southwest at what was to become the youngest caldera at Cottonwood Creek (described in the following sections), and to the northeast with renewed activity in the Badger Mountain caldera (Fig. 5). Intrusion of magma beneath the Badger Mountain caldera resulted in uplift and venting of alkali rhyolite lavas of Mahogany Mountain and the associated tuff of Alkali Flat and Badger Mountain (Fig. 4) along linear trapdoor faults and the reactivated southern ring fracture of the Virgin Valley caldera.
Tuff of Alkali Flat and Badger Mountain (Mtab) 15.8–15.7 Ma
Park (1983) suggested that nonwelded and partially welded ignimbrite exposed north of Trough Mountain and surrounding Badger Mountain (Figs. 3 and 4), previously identified by Noble et al. (1970) and Korringa (1973) as Soldier Meadow Tuff, consists of two petrographically similar but younger ignimbrites, based on evidence from paleomagnetic measurements and phenocryst proportions. Park (1983) named these units the tuff of Alkali Flat (normal paleomagnetic direction) and tuff of Badger Mountain (reversed). Although we mapped (scale 1:24,000) from Alkali Flat to Massacre Creek (Plate 2), we were not able to distinguish Park’s (1983) tuff of Alkali Flat and tuff of Badger Mountain in the field. Therefore, we mapped exposures of nonwelded to partially welded ignimbrite and related fall deposits as a single unit, Mtab, for the tuff of Alkali Flat and Badger Mountain. We have, however, confirmed Park’s (1983) paleomagnetic results (Fig. 17; ) and his suggestion that these are younger ignimbrite deposits. We obtained three ages for samples of the tuff, all of which are analytically well resolved from the 16.00 ± 0.02 Ma age of the Soldier Meadow Tuff: 15.80 ± 0.03 Ma (MC217) on ignimbrite near Alkali Flat, and 15.71 ± 0.02 Ma (MC314) and 15.84 ± 0.02 Ma (MC429B) from exposures south of Badger Mountain (Fig. 4).
Exposures of the tuff of Alkali Flat and Badger Mountain are largely confined within the Badger Mountain caldera (Figs. 4, 5, and 22), although thin deposits are exposed north and east of Nut Mountain and north of Trough Mountain. The thickest exposure (>100 m) is located 4 km northeast of Alkali Flat, where it has been preserved by the overlying high-Al olivine tholeiite lava flow of Rock Springs Table (Figs. 3 and 4). Ignimbrite components of the tuff of Alkali Flat and Badger Mountain are typically nonwelded or incipiently welded, vapor-phase altered, light bluish gray, tan, or pink on fresh surfaces, and weather reddish-orange or brown. Nonwelded outcrops gradually grade into incipiently welded or partially welded ignimbrite where the deposits are thickest around the Mahogany Mountain lavas. Vapor-phase alteration is more common in exposures >25 m thick, where it produces a pervasive salmon color, causes pumice lapilli to weather in negative relief forming cavities 3–10 cm in diameter, and results in prominent columnar jointing. The tuff is usually strongly porphyritic (40 vol%), and is broadly similar to the petrography of the crystal-rich Mahogany Mountain lavas.
Our field observations of several flow units and welding reversals, along with the new 40Ar/39Ar ages (Table 1), indicate that a number of small-volume pyroclastic flows and falls totaling ∼20 km3 erupted over a period of ∼100 k.y. between ca. 15.8 and 15.7 Ma in association with eruption of chemically and petrographically similar alkali rhyolite lavas of Mahogany Mountain surrounding Rodero Flat and Badger Flat (Figs. 3 and 4).
Alkali Rhyolite Lavas of Mahogany Mountain (Mlmm) 15.9–15.5 Ma
Named the rhyolite of Badger Mountain by Greene (1984), we have renamed the large number of lavas erupted within the Badger Mountain caldera the alkali rhyolite lavas of Mahogany Mountain (Mlmm) to avoid confusion with the Badger Mountain caldera, and because the lava that caps the southwest side of Badger Mountain is atypical in being very crystal poor, whereas the rest of the lavas are moderately to strongly porphyritic.
The Mahogany Mountain lavas erupted between 15.9 and 15.5 Ma along the reactivated southern ring-fracture zone of the Virgin Valley caldera and along northwest- and north-northeast–trending faults associated with intrusion of magma and trapdoor uplift within Badger Mountain caldera (Figs. 5 and 21). Most of the Mahogany Mountain lavas are crystal rich (Table 2) with subequal amounts of adularescent-blue sanidine and smoky quartz, but they span a wide range of phenocryst contents (2–55 vol%), with no clear correlation with age (Table 1; Supplemental Table 2). Most of the lavas are alkali rhyolites, but their trace element compositions show systematic variations with time (Fig. 5), becoming less alkalic in the younger lavas, some of which contain abundant dark colored magmatic enclaves, which can be locally abundant near vents.
We grouped Mahogany Mountain lavas as a single unit on our maps (Fig. 4; Plate 1), but distinguish three eruptive phases based on 40Ar/39Ar ages, stratigraphic relations, and trace element compositions (Table 3; Fig. 5; Supplemental Table 2). Mlmm-1 lavas have the highest Zr/Rb (2.9–3.0), and are stratigraphically the oldest. Mlmm-2 lavas have slightly lower Zr/Rb (2.0–2.5; Fig. 5). Mlmm-3 lavas are the youngest and least peralkaline, having lower Zr/Rb (1.0–1.4). See the Supplemental Text File for a discussion of 40Ar/39Ar ages for the three phases of Mahogany Mountain lavas.
Consistent with the range in 40Ar/39Ar ages for the Mahogany Mountain lavas (Table 1), the lavas both overlie and are onlapped by the crystal-rich tuff of Alkali Flat and Badger Mountain (Figs. 4 and 22). The tuffs are most similar in age and composition to Mlmm-2 (Fig. 17), so we infer that they were small-volume pyroclastic units associated with emplacement of these lavas. Eruption of the youngest crystal-poor lavas at Badger Mountain (Mlmm-3) was associated with a small-volume, nonwelded, phenocryst-poor, light pink ignimbrite that is exposed within Rodero Flat and along County Road 8A west of Badger Mountain.
Tuff of Yellow Rock Canyon and Alkali Rhyolite Lavas of Cottonwood Creek
Contemporaneously with the renewal of eruptions within Badger Mountain caldera, aerially extensive aphyric and weakly porphyritic alkali rhyolite lavas began erupting ca. 15.9 Ma at what was to become the youngest and southernmost major caldera in the HRCC, the Cottonwood Creek caldera (Fig. 5). We propose that it collapsed at 15.70 Ma on eruption of the newly recognized tuff of Yellow Rock Canyon.
Tuff of Yellow Rock Canyon (Miyc) 15.70 Ma
Most of the known exposures of the tuff of Yellow Rock Canyon occur north and northeast of the Cottonwood Creek caldera, where it flowed into the topographic depression of the Hanging Rock caldera (Figs. 20, 23, and 24) and was preserved by younger trachyte lavas that flowed over it (Fig. 4). The southern margin of the Cottonwood Creek caldera is composed of a large massif of phenocryst-poor precaldera lavas centered at Fox Mountain (Fig. 3), which may have prevented the tuff of Yellow Rock Canyon from being emplaced southward. The mapped extent of the ignimbrite is relatively limited, which we attribute to the poor preservation potential of the partially welded ignimbrite. The best outcrops of the tuff of Yellow Rock Canyon are in the footwalls of normal faults and in canyons incised through trachytic lavas that preserve the nonwelded deposits below. The most complete section is in High Rock Canyon (Figs. 3, 4, and 23), where ∼80 m of ignimbrite is exposed below trachytic lavas. We estimate the total volume of ignimbrite to be ∼50 km3 (DRE).
The tuff of Yellow Rock Canyon is compositionally and mineralogically zoned from a base characterized by light tan pumice lapilli of crystal-poor (2%–5%) alkali rhyolite to an upper flow unit that contains gray-blue trachytic pumice lapilli with ∼10 vol% phenocrysts. The upper trachyte-bearing flow unit is present only in thicker sections northeast of the Cottonwood Creek caldera. Exposures of nonwelded ignimbrite are 5–50 m thick and form white or light gray rounded mounds or hoodoos (Fig. 23). Nonwelded ignimbrite contains 30–60 vol% pumice lapilli, ranging in size from 5 to 30 cm, set in an ashy matrix. The degree of vapor-phase alteration, the size of pumice lapilli and lithics, and lithic abundance increase upward within the alkali rhyolite part of the ignimbrite. At the tops of thicker sections, 4–18 m of moderately welded ignimbrite can be present (Fig. 23). Basal exposures exhibit a 1–5-m-thick section of fall deposits and a minor surge deposit 3–5 cm thick.
The tuff of Yellow Rock Canyon contains silicified lithic fragments of Soldier Meadow Tuff that are typically <20 cm in diameter and locally concentrated in layers (Smith, 2011), but are as large as 1.5 m in diameter near Yellow Rock Canyon. We suggest that the pyroclastic flows entrained this coarse debris in canyons cut in Hanging Rock Canyon caldera fill. The upper trachytic part of the unit contains lithic fragments of crystal-poor rhyolitic and mafic lavas that are generally smaller (<20 cm) than lithics in the lower nonwelded parts (Fig. 23).
Previously, workers (Ach et al., 1991; Bussey, 1996; Smith, 2011) included the tuff of Yellow Rock Canyon exposed northwest of Fly Canyon (Figs. 3 and 4) with undifferentiated sedimentary deposits or bedded pyroclastic deposits. They may not have identified the unit as an ignimbrite due to its yellowish-orange alteration color and stratified character resulting from interaction with water on flowing into the caldera lake near what is now the eponymous Yellow Rock Canyon (Fig. 24).
We obtained an age of 15.69 ± 0.01 Ma from sanidine from a fall deposit at the base of the ignimbrite (MC256, Fig. 7B), 15.71 ± 0.03 Ma on sanidine from rhyolitic lapilli within the ignimbrite (MC428) north of the caldera, and 15.81 ± 0.03 Ma on trachytic lapilli (MC364, Fig. 7D) in the ignimbrite north of High Rock Lake. Our preferred age for the tuff of Yellow Rock Canyon is 15.70 Ma, based on these ages and the ages obtained on what we interpret to be precaldera and postcaldera lavas (described in the following sections). The two ages from the lower rhyolitic parts of the ignimbrite agree within 2σ uncertainties. We attribute the older age and more scattered results (cf. Figs. 7D, 7B) of the trachytic MC364 to extraneous radiogenic 40Ar from incompletely degassed alkali feldspar. The anomalously old age for the trachytic part of the tuff is inconsistent with the stratigraphic relation that the tuff banks against an alkali lava of Cottonwood Creek with an age of 15.75 ± 0.02 Ma (Plate 1; MC254 in Table 1). In addition, there is no conspicuous eruptive break in sections of the tuff zoned from alkali rhyolite to trachyte. We therefore favor the interpretation that the tuff of Yellow Rock Canyon represents a single eruptive event, rather than a series of eruptions that took place over ∼100 k.y., as we do for the tuff of Trough Mountain and for the tuff of Alkali Flat and Badger Mountain.
Alkali Rhyolite Lavas of Cottonwood Creek (Mlcc) 15.9–15.6 Ma
Based on the patterns of pressure ridges in what he interpreted as rheomorphic ignimbrites, Bussey (1996) mapped a circular pattern of vents ∼20 km in diameter surrounding Cottonwood Creek. We interpret these as vents for aerially extensive alkali rhyolite lavas that erupted along ring fractures associated with the Cottonwood Creek caldera.
Lavas we have mapped as precaldera and postcaldera Cottonwood Creek lavas are megascopically similar in the field, being aphyric or weakly porphyritic (∼5 vol%). They are similar in composition to the rhyolitic portion of the tuff of Yellow Rock Canyon (Table 3; Fig. 5). We report 40Ar/39Ar ages in the range 15.9–15.6 Ma for five lavas and a nonwelded ignimbrite associated with lava dome emplacement (Table 1; Supplemental Table 2). The new 40Ar/39Ar results are consistent with precaldera lavas beginning to erupt ca. 15.9 Ma, the tuff of Yellow Rock Canyon erupting at 15.70 Ma, with postcaldera ring-fracture volcanism ceasing shortly afterward, perhaps within a few tens of thousands of years (Fig. 7).
The 40Ar/39Ar ages and mapped relations lead us to estimate that the total volume of precaldera Cottonwood Creek lavas, ∼135 km3, exceeds the volume of postcaldera lavas, ∼85 km3, and that, in contrast to the other calderas at the HRCC, the lavas greatly exceed the extracaldera volume of the caldera-forming tuff of Yellow Rock Canyon. Eruptions centered on the Cottonwood Creek caldera (Miyc and Mlcc) and contemporaneous magmatism within Badger Mountain caldera (Mlmm and Mtab) represent the highest overall volumetric eruptive rates in the HRCC (∼2000–4000 km3/m.y.; Fig. 25B). See the Supplemental Text File for a further discussion of 40Ar/39Ar ages and field attributes of the lavas.
Metaluminous Rhyolitic Lavas that Postdate Peralkaline Rhyolitic Volcanism
In the Virgin Valley and Badger Mountain calderas, small volumes of metaluminous rhyolite erupted through the caldera fill several hundred thousand years after alkali rhyolite volcanism ceased in that particular area. These lavas are chemically distinct from most of the HRCC rhyolites in being metaluminous, with much higher concentrations of Ca, Ba, and Sr. Compositionally they are more similar to the earliest rhyolitic lavas in the HRCC, those at Nut Mountain (Fig. 5).
A group of five 100–300-m-diameter trachyrhyolite lava domes forming an east-northeast–trending chain intruded caldera lake sediments on the east side of the Virgin Valley caldera 4 km west of McGee Mountain (Fig. 4). A sixth dome occurs south of the chain forming a cryptodomes, the jagged top of which is barely exposed amid enveloping sediments. Emplacement of all the domes was associated with phreatomagmatic explosions that are recorded in adjacent caldera fill as a series of surge and fall deposits. These rhyolite lavas of Rock Springs Canyon (Mlrs) have well-defined topographic forms, and are relatively fresh with well-preserved mafic phenocrysts set in a hydrated glassy matrix, in contrast to nearby strongly silicified, ring-fracture–related Antelope lavas. They contain ∼12 vol% phenocrysts that reflect their metaluminous character: prominent biotite along with sanidine, amphibole, Fe-Ti oxides, and minor resorbed plagioclase and pyroxene. This chain of domes was mapped as rhyolite vitrophyre by Greene (1984) and Castor and Henry (2000), who reported a 40Ar/39Ar plateau age of 15.85 ± 0.11 Ma for one of the domes. This makes these lavas the youngest eruptive units in the Virgin Valley caldera, at least 250 k.y. younger than the ring-fracture Antelope lavas given the 2σ uncertainties on the ages.
Based on stratigraphy and 40Ar/39Ar dating, the youngest silicic lavas to erupt in the HRCC are the rhyolite lavas of Wall Canyon (Mlwc), which erupted through caldera fill at the intersection of caldera collapse- and uplift-related faults in the western part of Badger Mountain caldera (Figs. 4 and 21). These high-silica rhyolite lavas with <2 vol% alkali feldspar and trace quartz phenocrysts are commonly vesicular. We obtained an age of 14.68 ± 0.29 Ma (MC330) from devitrified whole-rock lava sampled from the largest outcrop, a dome that caps a thick section of caldera fill in Wall Canyon.
Postcaldera Alkalic Mafic and Intermediate Lavas (Mm and Mt) 15.5–14.2 Ma
Cessation of alkali rhyolite volcanism was followed by eruption of alkalic mafic and intermediate lavas (Fig. 26). In the Badger Mountain caldera, lavas ranging in composition from alkali basalt to trachyte erupted along preexisting faults associated with trapdoor uplift. Basaltic trachyandesite through trachyte lavas erupted in the Hanging Rock caldera, largely from vents along the southern ring-fracture zone, forming flows that protected underlying caldera fill from erosion. At the Cottonwood Creek caldera, alkali basalt erupted through the middle of the caldera lake. In all three calderas, venting through wet caldera lake sediments (Fig. 24) caused explosions that produced subaerial tuff rings and phreatomagmatic deposits of scoria and pumice that can be as much as 20 m thick beneath and adjacent to lava flows (mapped separately as Mp in Plate 2).
Postcaldera mafic lava flows are typically 3–6 m thick. Fresh surfaces are typically black, microcrystalline, and slightly vesicular with sparse (0–8 vol%) small phenocrysts of plagioclase, clinopyroxene, ± olivine. Flows weather dark reddish-brown or dark gray in color. Associated phreatomagmatic deposits typically weather yellowish-brown.
Individual trachyandesite to trachyte lava flows are typically 3–10 m thick. Fresh surfaces are typically aphanitic and black in color, giving them the appearance of basalt, despite their intermediate composition. Because the lavas are iron rich, they weather orange-brown. A thin brecciated basal zone is typical, which grades into a more massive, columnar jointed or platy zone, with a vesicular or rubbly top. Where flows are not massive, small rounded outcrops weather into thin, platy slabs typical of intermediate composition lavas. These lavas were mapped as andesite and dacite flows (Tad) by Ach (1988) and Ach et al. (1991) or basaltic andesite to dacite by Smith (2011).
Relatively precise ages can be determined for the postcaldera mafic and intermediate lavas because, with one exception, all the samples analyzed have relatively high K2O contents (1.9–4.0 wt%), so the radiogenic yields for laser fusion analyses of individual microcrystalline groundmass fragments were relatively high (53–78 average % 40Ar*, Fig. 8). These new ages show that all postcaldera alkalic basaltic to trachyte lavas identified in the HRCC are younger than ca. 15.5 Ma, and are among the youngest eruptive units.
At the Badger Mountain caldera we obtained an age of 15.55 ± 0.06 Ma (MC89, Fig. 8A) on a basalt west of Fish Creek Mountain, 15.08 ± 0.05 Ma (MC506) on a basaltic trachyandesite north of Badger Mountain, and 14.84 ± 0.03 Ma (MC237) on a trachybasalt southeast of Badger Mountain. Within the Hanging Rock caldera, we obtained ages of 14.5 ± 0.8 Ma (MC390) on a basaltic trachyandesite west of Soldier Meadow and 14.45 ± 0.07 Ma (MC249, Fig. 8D) from a trachyte lava flow overlying caldera lake sediments. The alkali basalt that erupted through the Cottonwood Creek caldera has the youngest age, 14.21 ± 0.04 Ma (MC266). Based on these ages, in any particular area within the HRCC, eruptions of mafic to intermediate lavas occurred at least 150 k.y. after the youngest alkali rhyolite volcanism, and marked the end of large-volume rhyolitic magmatism.
Late Miocene to Quaternary Basalts (NQm) 10–0.5 Ma
After an interval of nearly 5 m.y. without volcanic activity, eruptions of high-Al olivine tholeiitic basalt (HAOT) as thin (<10 m), dark colored, dikytaxitic, lava flows formed extensive, nearly flat-lying tables in the northern part of the HRCC (included within map unit Neogene to Quaternary undifferentiated volcanics, NQm in Figs. 3 and 4). These resistant lavas forming Rock Spring Table, Gooch Table, Big Spring Table, and Massacre Rim (Fig. 3) have preserved underlying caldera fill of the Virgin Valley and Badger Mountain calderas as well as older basinal sediments north of Nevada State Route 140 and at Massacre Rim.
We have found no evidence for vents for the HAOT flows within the calderas; these fluid lavas appear to have vented from low shield volcanoes north and northwest of the HRCC. Flows armoring tilted landslide blocks of caldera fill within the Virgin Valley caldera can give the superficial appearance of fin-like dikes, but on close inspection prove to be lavas, based on the presence of vesicle cylinders and the absence of horizontal columnar joints that would characterize dikes. The HAOT flows do not have associated phreatomagmatic deposits, pillowed bases, or peperite facies, suggesting that sizable bodies of water were no longer present in the HRCC during late Miocene time when they erupted.
We obtained 40Ar/39Ar ages of 10.1 ± 1.2 Ma (MC381) and 7.5 ± 0.9 Ma (MC358) for flat-lying HAOT flows of Rock Springs Table and Gooch Table. Farther west, 2 different flows at Massacre Rim yielded ages of 4.4 ± 0.7 Ma (AT13) and 4.7 ± 0.8 Ma (AT26) (Fig. 4). Carmichael et al. (2006) reported ages of 8–3 Ma for HAOT lavas in the Hays Canyon and Warner Ranges, west of the HRCC (Fig. 2). North of the HRCC, the HAOT flows are Pleistocene in age. The mesa referred to as the Oregon End Table (Fig. 3) is capped by a ca. 2 Ma HAOT (Legge, 1988), and the sinuous ∼20-km-long ridge ending at Railroad Point (Fig. 3) is inverted topography where a ca. 1 Ma HAOT lava flow (McKee and Marvin, 1974) filled a paleochannel cut in basinal sediments that have since been eroded away. HAOT lavas in Hawks Valley are younger than 1 Ma (Wypych et al., 2011).
CALDERAS OF THE HRCC
One of the main focuses of this study has been delineating calderas and identifying the sources for ignimbrites based on mapping, geochronology, and chemical correlation of ignimbrites and lavas. Where possible we distinguish between the topographic walls of calderas and the structural margins defined by ring-fracture volcanism (Figs. 4 and 21). In the HRCC, where the relief was low and the caldera walls commonly consist of strong, thick, silicic lavas, the topographic rim and the structural margin may nearly coincide.
Caldera Fill Deposits
An important criterion for delineating the boundaries of calderas is the distribution of caldera fill deposits. We mapped caldera fill to include lacustrine sediments, alluvial deposits, and primary volcanic deposits formed in a range of depositional environments: caldera lakes that range from deep and persistent to ephemeral, shallow bodies of water, littoral zones and minor streams, and dominantly subaerial settings in which alluvium, lahars, primary pyroclastic deposits, and talus debris on caldera topographic walls and around lavas (e.g., Smith, 1991) are deposited and interfinger with littoral lacustrine sediments.
The hallmark sedimentary deposits of a rhyolitic caldera environment are white, laminated, diatomaceous, ashy sediments and light colored, stratified, tuffaceous siltstones characteristic of quiescent lacustrine conditions (e.g., Smith and Bailey, 1968; Mahood, 1980; Smith, 1991) (Mcf in Plate 2; Fig. 24A). Petrified logs and wood chips are a characteristic feature of these deposits, their abundance suggesting that wood fragments from trees felled and shattered by volcanic activity may have been incorporated in ashy sediments that promoted replacement of organic debris with silica or opal (Hilton et al., 2008). In the Virgin Valley caldera, fine-grained ashy horizons are the host for specimen-quality opal (e.g., Zielinski, 1982) that replaces branches of wood, conifer cones, and other organic debris. A pyroclastic flow near the head of Little High Rock Canyon in the Cottonwood Creek caldera, associated with emplacement of one of the postcaldera Cottonwood Creek lavas, contains petrified logs nearly a meter in diameter that have been toppled and oriented horizontally by the pyroclastic flow.
We emphasize that the term caldera fill is not synonymous with caldera lake sediments. A large part of the caldera fill in HRCC calderas consists of subaerial deposits. Phreatomagmatic eruptions were triggered by the intrusion of both silicic and mafic magmas, resulting in the construction of subaerial tuff rings. The emplacement of lava domes was accompanied by eruption of small ignimbrite and surge deposits, the construction of ramparts of vitric lithic debris, and the entrainment of unconsolidated lake sediments by autobrecciated lava. Three of the caldera lakes appear to have drained catastrophically, rapidly downcutting dramatic gorges through lavas making up the topographic walls of the calderas. The calderas remained depocenters of sediments in more restricted bodies of water, however, and continued to accumulate pyroclastic debris.
Rhyolitic pumiceous deposits make up a significant fraction of the caldera fill at the HRCC, enough to be differentiated as a separate unit (Mcfp) in Plate 2. These consist of multiple horizons (∼10–50 cm thick) of well-stratified, centimeter-scale, normally graded beds that are variably reworked, with rounded pumice lapilli and subrounded lithics in an ashy matrix. The pumice-rich horizons are various shades of gray on fresh and weathered surfaces (gray layers in Fig 24A). They are typically located adjacent to postcaldera rhyolite lava flows and domes, and become finer grained upsequence and toward the interiors of the caldera lakes. They are interpreted as the products of subaerial and littoral reworking of pumice and ash fall and surge deposits associated with emplacement of silicic lavas into the caldera lakes. In the Virgin Valley caldera, these tuffaceous and pumice lapilli–rich sediments interfinger with Antelope lavas that erupted along ring fractures and with finer grained ashy sediments deposited in the interior of the Virgin Valley caldera that include distal ash fall deposits from other mid-Miocene centers (Perkins and Nash, 2002).
Where postcaldera trachytic and mafic lavas intruded caldera fill, dark gray, brown, or light yellow-brown phreatomagmatic deposits (Mp in Plate 2; Fig. 24B) up to 20 m thick consist of well-stratified, normally graded beds, which locally display meter-scale, low-angle, surge cross-bedding. They contain dark brown to black, scoriaceous lapilli and blocks 1–30 cm in diameter. Accretionary lapilli are common, typically concentrated within beds 3–10 cm thick. Locally the phreatomagmatic deposits grade into peperites or hyaloclastites, and at their distal edges they are interbedded with typical fine-grained, light colored caldera lake sediments.
At the HRCC, caldera fill is best exposed in the Virgin Valley (to ∼450 m thick) and Hanging Rock calderas because the deposits have been preserved beneath younger lava flows, and incised by creeks (Fig. 24). Caldera fill is not well exposed in the Cottonwood Creek caldera due to low relief, and because most of it has been eroded away. Most caldera fill exposures in the Badger Mountain caldera consist of pumiceous sediments that incorporated debris from primary and reworked subaerial pyroclastic deposits formed in association with emplacement of the 15.9–15.5 Ma Mahogany Mountain lavas. Fine-grained sediments are found only locally.
Virgin Valley Caldera
The Virgin Valley caldera is the oldest and northernmost caldera in the chain of southwest-younging HRCC calderas (Figs. 2, 3, and 5) and is the source of the 16.38 Ma Idaho Canyon Tuff. The caldera is easily recognized by the distribution of fine-grained caldera lake sediments partially encircled by vents for postcaldera ring-fracture alkali rhyolite Antelope lavas surrounding Virgin Creek (Fig. 4).
Castor and Henry (2000) outlined the Virgin Valley caldera as a 22-km-diameter circular caldera. Based on our new mapping, 40Ar/39Ar geochronology, and chemical data for lavas and ignimbrites, we suggest that the caldera is somewhat larger, 34 × 24 km, with the eastern part of the caldera centered on Virgin Creek having collapsed more than the northwestern part. There is an abrupt break in the intracaldera topography ∼6 km east of the western caldera rim, approximately where Castor and Henry (2000) drew the western margin of the caldera. Caldera fill west of this break in slope (i.e., north of Gooch Table and in western Hell Creek; Figs. 3 and 4) has a high proportion of reworked volcaniclastic sediments and subaerial pyroclastic deposits, consistent with small, shallow, and short-lived bodies of water. East of this break in slope, deposits are fine-grained, laminated, ashy, and diatomaceous, and thereby indicative of a persistent, quiescent lacustrine environment. These fully lacustrine deposits are centered at Virgin Creek (Figs. 3 and 4), where the thickest sequence of exposed caldera fill deposits (∼450 m) defines the zone of greatest caldera collapse.
The distribution of welding facies and the two chemically and petrographically defined subunits of the Idaho Canyon Tuff , Niica and Niicb, along with variations in thickness (see Supplemental Fig. 2) can be used to elucidate the nature of collapse of the Virgin Valley caldera. The most chemically evolved and crystal-poor samples of the ignimbrite have been found northwest of the caldera, and the bulk of the volume of more-evolved Miica Idaho Canyon Tuff was emplaced north and northwest of the caldera. In contrast, the less-evolved Miicb is exposed only in the fault scarp on the east side of the complex and locally as outflow southeast of caldera (Fig. 16). We interpret that to mean that initial venting of the ignimbrite and caldera collapse occurred in the northwest, and that subsequent greater subsidence was associated with eruption of more mafic magma sourced deeper in the chamber venting from the southeast quadrant of the ring fracture. It is possible there was a small amount of additional collapse that occurred in the eastern part of the caldera as a result of the later eruption of the pyroclastic deposits making up the tuff of Big Mountain. See the Supplemental Text File for further discussion of this point.
The northeastern quadrant of the structural margin of the Virgin Valley caldera is well defined by the pattern of vents for the Antelope lavas, which erupted ∼100–200 k.y. after caldera collapse. We speculatively locate the northwest quadrant of the structural margin along a major fault-controlled canyon through the vent area for the 16.31 ± 0.03 Ma Hell Creek lava in Echo Canyon (Fig. 4). We interpret the zones of pervasive hydrothermal alteration, silicification, and mineralization of the crystal-poor lavas in Hell Creek and all exposures of Antelope lavas as evidence for the location of buried caldera ring fractures.
The southern to southwestern margin of the caldera is obscured by the overlapping collapse of the younger Badger Mountain caldera and by products of younger volcanism. We believe that the structural margin is marked by the arcuate arrangement of vents for the Mahogany Mountain lavas. Although the Mahogany Mountain lavas erupted much later during a 15.9–15.5 Ma renewal of activity in the younger Badger Mountain caldera, we interpret the associated uplift as reactivating the southern ring fracture of the Virgin Valley caldera, leading to reversal of motion on the fault, and venting of alkali rhyolite magma as lava domes and flows along it (Figs. 4 and 21). We consider the chemical trends shown by the three groups of Mahogany Mountain lavas as supportive of this conclusion, as over time the lavas become chemically more like the Antelope lavas to the north (Fig. 5), suggesting shared magma sources and/or reservoirs.
The topographic margin of the Virgin Valley caldera is constrained by outcrops of caldera fill and the distribution of outflow Idaho Canyon Tuff exposed outside the caldera walls to the northwest and southeast. The northern topographic margin of the Virgin Valley caldera is partially covered by younger HAOT lavas of the Big Springs Table, but its position is apparent from the truncation of what we interpret to be Paleogene lavas at Big Springs Butte and by the outcrop pattern and pressure ridges of Antelope lavas east of Big Spring Reservoir along Nevada State Route 140 (Figs. 3 and 4). The topographic margin confines the westward extent of Antelope lavas and caldera fill south of Big Springs Reservoir, whereas basinal sediments are exposed just outboard of the caldera topographic margin. A thin veneer of moderately welded Idaho Canyon Tuff laps the sediments and an undated aphyric rhyolite lava we infer to be Paleogene near Big Springs Butte just outboard of what we interpret as the caldera margin. The outflow ignimbrite thickens abruptly to >80 m (base unexposed) and is densely welded throughout exposures in Catnip Creek and around the Sage Hen Hills (Figs. 3 and 4), where it apparently filled a broad paleovalley. At its northernmost extent, northwest of Hawks Mountain (Fig. 3), the Idaho Canyon Tuff thins, the intensity of welding decreases such that several welding reversals are apparent, and a nonwelded base is exposed locally. In addition to using welding relationships in the Idaho Canyon Tuff to locate the northwest quadrant of the topographic wall, we interpret a break in slope along the eastern side of the Catnip Mountain dome as marking where postcaldera Catnip Mountain lavas flowed over the caldera rim.
The outcrop pattern of postcaldera Antelope lavas defines the northeastern and eastern sectors of the topographic margin of the Virgin Valley caldera. On the north and east side of McGee Mountain and east side of Big Mountain, these lavas and the associated tuff of Big Mountain appear to have banked in against a caldera topographic wall that no longer exists, as they form a striking 300–500-m-high arcuate wall above the modern Bog Hot and Craine Creek Valleys (Figs. 3 and 4). We interpret this as a reversal of topography resulting from banking against a caldera topographic wall that was composed of weakly consolidated basinal sediments that have since been largely eroded away. Erosion along with what we interpret to be the reactivation of caldera collapse–related structures by northeast- and northwest-trending Basin and Range faulting has resulted in the continuation of this feature in a large, arcuate scarp south of McGee Mountain (Figs. 3 and 4).
We interpret the Idaho Canyon Tuff exposed south and southeast of the Virgin Valley caldera as outflow ignimbrite that flowed down a precursor basin to the modern Craine Creek Valley (Figs. 3 and 4). The absence of the Idaho Canyon Tuff northeast of the caldera is puzzling, particularly in light of the fact that a tilted section on the east side of the southern Pueblo Mountains contains the Oregon Canyon Tuff, the Trout Creek tuff, and the Long Ridge tuff, all from the MVF, that bracket the appropriate age interval (Coble and Mahood, 2012; Benson and Mahood, 2015). It may be that the presence of an active drainage east of the caldera prevented the preservation of the ignimbrite there, as well as its deposition on the west side of the southern Pueblo Mountains and northern Pine Forest Range. Farther south, thin deposits of Miicb are exposed in the westernmost Pine Forest Range, and thicken to the south toward the headwaters of Craine Creek (Figs. 3 and 4), suggesting that any drainage that prevented the spread of the Idaho Canyon Tuff must have been farther east, perhaps controlled by what are now prominent faults in the Pine Forest Range (Fig. 4).
Badger Mountain Caldera
We identify the newly defined Badger Mountain caldera as the source of the 16.34 Ma Summit Lake Tuff. It is the least confidently delineated of the calderas in the HRCC because it partly overlaps the older Virgin Valley caldera to the northwest, and is truncated by the younger Hanging Rock caldera and what we identify as scallop-shaped collapse features to the southwest. In addition, it was the site of uplift and renewed volcanism from ca. 15.9 to 15.5 Ma (Figs. 4, 5, and 21). Due to these complexities, it is difficult to distinguish between the topographic and structural margins of the caldera; instead we discuss the evidence used to delineate an outline of the caldera that we refer to more generically as the caldera margin. We believe it more closely approximates the topographic margin, and given that the topographic rim retreats outward due to landslides and erosion, the original caldera was likely smaller than shown in Figures 2–4.
The southeast and southwest margins of the 40 × 30 km Badger Mountain caldera are delimited by locations of outflow Summit Lake Tuff (Fig. 4). Additional evidence used to place the southern and southeastern margin of the Badger Mountain caldera is the distribution of the younger tuff of Alkali Flat and Badger Mountain that we suggest was largely confined within the caldera (Fig. 4).
We interpret the prominent arcuate break in topography along the south side of Catnip Mountain as a result of truncation on collapse of the Badger Mountain caldera, although the two ages for Catnip Mountain lavas (Table 1) are insufficiently precise to determine whether the Catnip Mountain edifice predates or postdates eruption of the Summit Lake Tuff. The arcuate break continues to the west in more subdued topography that is buried by young high-Al olivine tholeiite lavas (Fig. 4). This break in slope also marks the northern limit of caldera fill. We have placed the caldera margin near two exposures of Catnip Mountain lavas located south of Alkali Flat and west of Trough Mountain. We have drawn this southern margin of the Badger Mountain caldera in such a way that inferred vents for the 16.1 Ma Wild Horse Pasture lavas, which also have chemical affinities with the Summit Lake Tuff (Fig. 5), could be postcaldera ring-fracture lavas of the Badger Mountain caldera.
The Badger Mountain caldera is reflected in regional gravity and magnetic maps (Fig. 18) by prominent negative anomalies. We have extrapolated the caldera margin in areas where stratigraphic evidence is not available by honoring the shapes of the geophysical anomalies, in particular the steep gradients in the magnetic map at the west margin of the caldera.
Post–Badger Mountain Caldera and Pre–Hanging Rock Caldera Volcanism
The eruption of two large ignimbrites on collapse of the Virgin Valley caldera and the overlapping Badger Mountain caldera within a relatively short time (<80 k.y., based on 2σ uncertainties of ages on the caldera-forming ignimbrites) means that eruptions following collapse of the younger Badger Mountain caldera reflect the rejuvenation of both magmatic systems. Because the two systems are slightly different chemically, we can utilize bivariate chemical plots (Figs. 5 and 12) to assign lavas and ignimbrites erupted in the interval between the eruption of the Summit Lake Tuff at 16.34 Ma and the Soldier Meadow Tuff and collapse of the Hanging Rock caldera at 16 Ma to one of two trends. A lower Rb/Zr trend associated with the Summit Lake Tuff consists of the 16.27 Ma tuff of Coyote Spring, which occurs west of the Badger Mountain caldera, the 16.2 Ma Nellie Springs Mountain lavas and Massacre Creek lavas west of what was to become the Hanging Rock caldera, the 16.1 Ma Wild Horse Pasture lavas near the southeastern ring fracture of the Badger Mountain caldera, and the caldera-forming 16 Ma Soldier Meadow Tuff. A higher Rb/Zr trend defined by the Idaho Canyon Tuff is shared by the 16.3–16.2 Ma Hell Creek lavas, and by the 16.25–16.15 Ma tuff of Trough Mountain, which vented south of the Badger Mountain caldera. At least locally these slightly different alkali rhyolite types commingled, as evidenced by a phenocryst-rich magmatic enclave in an aphyric high-Rb/Zr Hell Creek lava in Hell Creek that yielded an age of 16.2 Ma and a chemical composition similar to low-Rb/Zr Nellie Springs Mountain lavas (MC433 in Fig. 5), providing strong evidence that the higher and lower Rb/Zr magma types coexisted at 16.2 Ma.
More or less contemporaneous with eruption of both these magma types, rhyolitic magmas distinctly less alkalic (Fig. 5) were erupting as the Antelope lavas and the tuff of Big Mountain along the ring-fracture zone of the Virgin Valley caldera (Fig. 4); these eruptions were the last peralkaline rhyolitic eruptions in this northern part of the caldera. We interpret the high Rb/Zr ratios and the more metaluminous character of these magmas (Mla and Mtbm in Fig. 5) as reflecting the types of magmas formed in the waning stages of the caldera systems because they are compositionally similar to the last peralkaline lavas to erupt in the Badger Mountain caldera (Mlmm-3 in Fig. 5).
Possible Collapse Associated with Eruption of Tuffs of Coyote Spring and Trough Mountain
During the same interval that the Antelope lavas and tuff of Big Mountain were erupting in Virgin Valley, pre–Hanging Rock caldera eruptions were occurring south and west of the Badger Mountain caldera. We suggest that the topographically low area between the Badger Mountain and Hanging Rock calderas, from Wall Canyon (Fig. 21) to the west side of Trough Mountain, is an expression of collapse along structures synthetic to the older Badger Mountain and future Hanging Rock ring-fracture faults. Bounding this low area are two massifs, Nut Mountain and Trough Mountain, which contain spatially restricted exposures of the 16.27 Ma tuff of Coyote Springs and 16.25–16.15 Ma tuff of Trough Mountain, respectively. We interpret these ignimbrites as being associated with two poorly defined scallop-shaped collapse features west and southeast, respectively, of the Badger Mountain caldera, which were truncated on the southwest by the Hanging Rock caldera collapse at 16.0 Ma. The tuff of Trough Mountain is along the high Rb/Zr Idaho Canyon Tuff trend, and the tuff of Coyote Spring is along the low Rb/Zr Summit Lake Tuff trend (Fig. 5). Given the overlap in the ages of the tuffs, it seems possible that these magmas existed as laterally distinct bodies in the same magma chamber or as adjacent magma bodies.
The complicated fault zone that is well exposed on the west side of Wall Canyon (Plate 2) could have formed on collapse associated with eruption of the tuff of Coyote Springs. Blocks of silicified Nut Mountain lava, Summit Lake Tuff, and tuff of Coyote Spring occur as fault slivers within this zone (Fig. 21), indicating that the fault zone postdates collapse of the Badger Mountain caldera.
Based on our mapping and field observations, the distribution of the units, and the descriptions of Korringa (1973), we suggest that the ignimbrite component of the tuff of Trough Mountain vented from a northern portion of the lineament along which Soldier Meadows lavas later erupted. Collapse along this feature may have enlarged the Badger Mountain caldera to the south, accounting for the topographic low and gravity low anomaly in the area between the Badger Mountain and Hanging Rock calderas (Fig. 18). We have interpreted the topographic margin of the collapse feature we relate to the tuff of Trough Mountain as having controlled the eastern extent of caldera fill and phreatomagmatic deposits (Mp) related to the younger Hanging Rock caldera.
Hanging Rock Caldera
We delineate the ∼17-km-diameter Hanging Rock caldera by the distribution of ashy lake sediments inside the caldera and of outflow Soldier Meadow Tuff east and southeast of the caldera, and by the truncation of precaldera lavas and the position of vents for postcaldera lavas. We identify the Soldier Meadow Tuff as the caldera-forming unit based on its stratigraphic position above the tuff of Trough Mountain, which is cut by the caldera margin, and below the tuff of Yellow Rock Canyon, which flowed into the Hanging Rock caldera. In addition, the 16 Ma age of the Soldier Meadow Tuff is consistent with it being the caldera-forming unit, based on the fact that 16.2 Ma Massacre Creek lavas, similar in composition to the most-evolved Soldier Meadow Tuff, are truncated by collapse. Postcaldera lavas erupted within the caldera are petrographically and chemically similar to the Soldier Meadow Tuff, and have ages that are statistically indistinguishable.
We have not applied the name High Rock caldera used informally by Noble et al. (2009) and Smith (2011) to avoid confusion with our use, following that of Ach and Swisher (1990), of the place name for the regional-scale HRCC. In addition, Smith (2011) suggested that the 16.34 Ma Summit Lake Tuff erupted from the High Rock caldera or a location near it (cf. Noble et al., 1970). Our new mapping and geochronology demonstrate that the 16.2 Ma Massacre Creek lavas overlie the Summit Lake Tuff and are truncated by the northern margin of the caldera, requiring that at least this quadrant of the caldera is younger than 16.2 Ma and cannot be related to collapse on eruption of the Summit Lake Tuff.
The northwestern margin of the Hanging Rock caldera is well exposed because it has not been the site of subsequent eruptions. Both the topographic wall and structural margin here occupy a broad zone of normal faulting expressed in a series of arcuate structural benches along which precaldera lavas are step faulted down into the caldera (Figs. 3 and 4). South of Nut Mountain, northeast-trending parallel benches are continuous in the topography for more than 20 km (Fig. 21) and are prominent on aerial imagery. At their northern ends, these structures intersect and curve into north-northwest–oriented features that are parallel to the margin of the Badger Mountain caldera (Fig. 4; detailed quadrangle mapping in Plate 2). These fault-controlled benches wrap continuously around the Hanging Rock and Badger Mountain calderas, suggesting that some of the deformation is due to regional-scale downsagging toward the calderas that occurred on a longer time frame than individual collapse events.
Given the broad zone of deformation, it is somewhat arbitrary to assign the location of the structural margin; logically, the entire slope could be considered the topographic wall. We placed the northwest topographic wall at the break in slope, inboard of which precaldera lavas form striking cliffs, including at Hanging Rock Canyon. The western sector of the topographic margin is well marked by the truncation of an Oligocene dacite lava dome and the arcuate edge of a postcaldera Soldier Meadow lava that banks against it near Grassy Rock (Figs. 3 and 4). The western and southwestern sectors of the topographic wall are largely obscured by younger lavas derived from the Cottonwood Creek caldera, but we placed the topographic wall outboard of caldera fill and along breaks in slope in Cottonwood Creek lavas where we infer they cascaded over the caldera wall. The southern caldera wall is located based on the thickest accumulations of postcaldera trachyte lavas, which we interpret as erupting along the southern ring fracture to form low shields that ponded against the caldera wall, with a smaller number of flows spilling over the southern margin where they overlie outflow Soldier Meadow Tuff and the younger tuff of Yellow Rock Canyon. We place the southeastern and eastern topographic margin of the Hanging Rock caldera west (inboard) of exposures of Soldier Meadow Tuff and tuff of Trough Mountain (Fig. 4).
The northeastern and northern sectors of the topographic margin of the caldera are poorly defined because the margin overlaps the older Badger Mountain caldera and is buried by the younger tuff of Alkali Flat and Badger Mountain and caldera fill (Fig. 4). We believe that the topographic wall in this area was already low due to the cumulative effects of collapse of the Badger Mountain caldera and postulated scallop-shaped collapse associated with eruption of the tuff of Coyote Spring and the tuff of Trough Mountain. We envision that shortly following collapse of the Hanging Rock caldera there would have been a near-continuous lake basin that encompassed the Hanging Rock, Badger Mountain, and Virgin Valley calderas.
We infer that the structural margin of the Hanging Rock caldera is only slightly inboard of the topographic wall in the northwest sector of the caldera, mostly buried by caldera fill at the base of the resistant cliffs of precaldera rhyolitic lavas. In the western sector we locate the ring-fracture zone to pass through the locations of the vents for postcaldera Soldier Meadow and Cottonwood Creek lavas (Fig. 4). We locate the southern structural margin at the location of feeder dikes and the summits of low shields that were the sources for postcaldera trachytic lavas. The eastern and northern sectors of the structural margin are difficult to define. There are several rhyolitic lava flows in the age range of 16.0–15.7 Ma that could mark eruptions along ring fractures, but we think it is likely that due to overlap in this region of collapse structures of Summit Lake, Coyote Spring, Trough Mountain, and Soldier Meadow tuff ages, the cauldron block is sufficiently disrupted by faults that it is unlikely that lavas would mark a single ring fracture analogous to that in the Virgin Valley caldera.
Based on the outflow distribution of the Soldier Meadow Tuff and the thickness of caldera fill, the floor of the Hanging Rock caldera subsided more on the south than on the north. The section of caldera fill is thin on the north, and the caldera floor is exposed near the mouth of Hanging Rock Canyon, where Nut Mountain lavas occur on both sides of the structural margin of the caldera. The thickness of sediment increases southward, and the thickest accumulation of the younger tuff of Yellow Rock Canyon ponded in the southern half of the caldera. Given that most of the Soldier Meadow Tuff is exposed southeast of the Hanging Rock caldera, it is possible that most of the ignimbrite vented from ring fractures along the southern margin, which resulted in greater collapse there.
Postcaldera Soldier Meadow Lavas and Uplift and Renewed Volcanism in the Badger Mountain Caldera
Shortly after collapse of the Hanging Rock caldera, lavas chemically and petrographically similar to the Soldier Meadow Tuff erupted in the western side of the caldera into a caldera lake, and erupted east of the caldera along a north-south chain of vents located north of Soldier Meadow (red dotted line in Fig. 4). The 40Ar/39Ar ages of the Soldier Meadow lavas and the petrographically similar Soldier Meadow Tuff overlap at 2σ uncertainty (Table 1), suggesting that no more than ∼50 k.y. passed between eruption of the tuff and the postcaldera lavas. We interpret this short time span and the similar but more evolved compositions of the Soldier Meadow lavas (Fig. 5; Table 3) as indicating that the magma erupted as lavas represented either residual melts not tapped during the ignimbrite eruption or the further evolution following caldera collapse of magma remaining in the chamber.
Emplacement of Soldier Meadow lavas on the floor of the Hanging Rock caldera was not associated with significant uplift, as the lavas have patterns of pressure ridges indicating that they erupted onto a relatively flat surface and extensive glassy carapaces characteristic of erupting into a caldera lake. We interpret the vent array of Korringa (1973) east of the caldera as having formed when magma was intruded along faults that formed concentric to Hanging Rock caldera collapse or to collapse associated with eruption of the tuff of Trough Mountain.
The northernmost of the Soldier Meadow lavas along the vent array erupted within the poorly defined southern boundary of the Badger Mountain caldera, representing a rapid propagation of magmatism to the north. Intrusion of magma renewed volcanism in the caldera, and created a fault-bound trapdoor-style uplift ∼18 × 12 km centered on Rodero Flat (Figs. 3 and 4). In Hell Creek, three northwest-trending benches are interpreted to represent a broad zone of faulting on the north side of the trapdoor uplift (Fig. 21), which reactivated the southwestern structural margin of the Virgin Valley caldera (Fig. 4). The alkali rhyolite lavas of Mahogany Mountain that erupted within the Badger Mountain caldera between 15.9 and 15.5 Ma, contemporaneous with and immediately following the Soldier Meadow lavas, vented along the northwest- and north-northeast–trending trapdoor faults and along the reactivated ring fracture of the Virgin Valley caldera (Fig. 4). The vents for the largest flows are located where trapdoor uplift was greatest, forming a linear north-northeast–trending chain of lava centers near Alkali Peak and Mahogany Mountain. In contrast, the hingeline for trapdoor uplift, located along County Road 8A, is characterized by a paucity of rhyolitic vents (Figs. 3 and 4).
Small-volume ignimbrites and pumice falls related to emplacement of these lava domes and flows were erupted at 15.8–15.7 Ma forming the crystal-rich alkali rhyolite tuff of Alkali Flat and Badger Mountain. Welding horizons in the ignimbrites now dip as much as 8° quaquaversally from Rodero Flat, indicating that a significant fraction of the magmatically driven uplift postdated these eruptions.
After peralkaline rhyolitic volcanism ceased, lavas of basalt, trachybasalt, and basaltic trachyandesite erupted along the trapdoor faults and hingeline between ca. 15.5 and 14.2 Ma. Phreatomagmatic deposits (Mp) associated with eruption of these mafic lavas into a caldera lake are exposed along County Road 8A (Fig. 4).
Cottonwood Creek Caldera
Postcaldera rhyolitic volcanism was short lived at the Hanging Rock caldera; activity rapidly migrated to the north to Badger Mountain caldera, and simultaneously occurred to the southwest at the Cottonwood Creek caldera, the youngest caldera in the HRCC. Ach and Swisher (1990) postulated the presence of a caldera in this area, and Bussey (1996) recognized a volcanic center in his study of the geology of the Hog Ranch gold mine, but no caldera-forming unit was identified in these previous studies. We suggest that eruption of the newly recognized 15.70 Ma tuff of Yellow Rock Canyon led to collapse of the 24 × 28 km Cottonwood Creek caldera (Figs. 3 and 4).
The Cottonwood Creek caldera is defined principally by the arcuate arrays of vents for precaldera and postcaldera phenocryst-poor and aphyric alkali rhyolite lavas of Cottonwood Creek that are inferred to have erupted along caldera ring faults (Fig. 4; Plate 1). Within the annular distribution of ring-fracture lavas is a low-relief basin containing poorly exposed caldera fill deposits that include fine-grained caldera lake sediments, small-scale pyroclastic deposits, and sediments representing reworking of volcanic debris. Near the center of the caldera lake these sediments were intruded by alkali olivine basalt, which gave rise to phreatomagmatic deposits and thin lava flows. The age of 14.21 ± 0.04 Ma (MC266) obtained from one of these flows is a maximum age for the cessation of caldera fill sedimentation.
There is also a pattern of arcuate normal faults within the alkali rhyolite lavas of Cottonwood Creek that are concentric around the caldera fill and athwart the younger northwest trends of Basin and Range faults (e.g., the topographic break north of Fox Mountain; Figs. 2–4). We interpret these arcuate faults as offsetting precaldera lavas in a manner sympathetic to the ring faults. In many places these faults are marked by the vents for postcaldera lavas.
Low sulfidation epithermal gold deposits are interpreted to be located within postcaldera ring-fracture lavas at the Hog Ranch Mine (Bussey, 1996) (Figs. 3 and 4). Economically significant mineral deposits have also been identified at other mid-Miocene calderas in northwest Nevada (Rytuba and Glanzman, 1979; Bussey 1996; Castor and Henry, 2000; Rytuba et al., 2003), presumably because silicic magma chambers fuel shallow meteoric water–dominated hydrothermal systems concentrated along ring-fracture zones (Rytuba, 1994; Bussey, 1996; Saunders et al., 2008; this study).
The magnitude of collapse at the Cottonwood Creek caldera appears to be small relative to the other calderas at the HRCC. In all but the eastern sector of the caldera, Cottonwood Creek lavas that we interpret as precaldera are exposed within the caldera and are lapped by only a thin section of caldera fill, indicating that the top of the cauldron block was not entirely covered by intracaldera ignimbrite and subsided only hundreds of meters. The amount of caldera collapse is greatest in the northeastern quadrant of the Cottonwood Creek caldera, which coincides with inferred vent locations for the tuff of Yellow Rock Canyon.
Most of the known exposures of the tuff of Yellow Rock Canyon are north of the caldera, where the ignimbrite flowed into the topographic depression of the Hanging Rock caldera. Small exposures of ignimbrite located north of Hog Ranch Mine and south of Hart Mountain that are preserved beneath postcaldera Cottonwood Creek lavas are interpreted as being between the structural margin and the topographic wall of the caldera (Fig. 4).
Redefinition of the Beginning of the Snake River Plain–Yellowstone Trend
Many researchers attribute eruption of mid-Miocene flood basalts to mantle melting caused by upwelling of a mantle plume head beneath the base of the North American lithosphere ca. 17 Ma, and the northeast-younging silicic centers of the Snake River Plain–Yellowstone trend to subsequent passage of the North American plate over a stationary plume tail (e.g., Pierce and Morgan, 1992; Nash et al., 2006; Hooper et al., 2007; Shervais and Hanan, 2008). The beginning of the Snake River Plain–Yellowstone trend has been depicted frequently in the literature as beginning at the McDermitt caldera in northern Oregon, with the implication that this was also the location of the initial impingement of the plume head on North American lithosphere.
Numerous studies, however, have suggested that mid-Miocene silicic volcanism is widespread (e.g., Pierce and Morgan, 1992; Brueseke and Hart, 2008; Shervais and Hanan, 2008; Castor and Henry, 2000; Cummings et al., 2000; John et al., 2000; Camp et al., 2013; Streck et al., 2015). Nash and Perkins (2012) concluded that there was widespread, abundant silicic volcanism between 16 and 15 Ma in southeastern Oregon and northern Nevada, based on the abundance and distribution of ash fall tuffs of this age in sedimentary basins. Independently, we reached a similar conclusion based on a compilation of the existing evidence for the locations of calderas and lava fields of this age (Coble and Mahood, 2012). In addition, we suggested that the plume head was focused beneath Steens Mountain, and that broadly distributed silicic volcanism at the HRCC, MVF, Lake Owyhee volcanic field, and numerous smaller, lava-dominated centers (see other 16.6–15.0 Ma centers in Fig. 1), and the eruption of voluminous flood basalts of the Columbia River Basalt Group were associated with spreading of a plume head.
These regional studies combined with our work delineating the HRCC, which is the source of ignimbrites similar in age (ca. 16.5–15.7 Ma), volume, and composition to ignimbrites erupted from the MVF, require a modification of the common depiction of the McDermitt caldera sensu stricto as the inception point of the Snake River Plain–Yellowstone trend. We suggest that the HRCC and MVF together with the nearby, smaller lava-dominated Hawks Valley–Lone Mountain, and Santa Rosa–Calico volcanic centers (Fig. 1) should be taken as the origin of the trend. In this model, the transition to the more focused Snake River Plain–Yellowstone track coincided with the passage ca. 15.2 Ma (Nash et al., 2006) of the edge of the North American craton over the mantle thermal anomaly interpreted as a plume tail. This transition was also accompanied by a change from the peralkaline compositions among the rhyolites that erupted at in the Nevada-Oregon-Idaho border region to the metaluminous compositions of the Snake River Plain and at Yellowstone (Nash et al., 2006). The large volumes of the younger rhyolites, despite being associated with lesser volumes of basalt associated with a plume tail, as well as their metaluminous composition, can be explained by the thicker and more felsic composition of the crust east of the craton boundary.
HRCC as an Analog for the Geometry of Calderas Buried Beneath the Snake River Plain
The well-preserved and well-exposed calderas of the HRCC may provide a template for thinking about the nature of the sources of voluminous ignimbrites buried beneath younger basaltic lavas of the Snake River Plain. Based on map patterns for calderas in the HRCC and Yellowstone calderas (Christiansen, 2001), we suggest that the representation of broad eruptive centers postulated beneath basalts and sediments along the Snake River Plain (Fig. 1; Bonnichsen, 1982) should not be taken to represent individual calderas. To do so would greatly exaggerate their sizes and eruptive volumes. Branney et al. (2008) also made this argument based on a similar inference from the geometry of the Yellowstone calderas and the distributions of Pliocene ignimbrites erupted from centers buried beneath the Snake River Plain basalts. The pattern of physical and temporal overlap of calderas at Yellowstone and the HRCC suggests that at each buried Snake River Plain center there would be a clustering of calderas, with nesting of smaller calderas and overlap of larger ones, and there would not be a continuous trail of calderas that young unidirectionally toward the northeast. This clustering may reflect a feedback mechanism in which a locally greater flux of basaltic dikes initiates local crustal melting, which causes stagnation of basaltic dikes, and in turn leads to even more partial melting and hybridization (e.g., Hildreth, 1981; Annen and Sparks, 2002; de Silva and Gregg, 2014). Mechanical focusing of rising dikes by a silicic magma chamber in the middle or upper crust (Karlstrom et al., 2009) could lead to clustering of clustering of calderas. This process may account for the appearance of discrete centers with 1–2 m.y. lifespans along the Snake River Plain–Yellowstone trend (Fig. 1).
Relationship Between Mid-Miocene Basalts and Silicic Volcanism
Contemporaneity of Eruption of Columbia River Basalt Group and Rhyolite Volcanism
Mid-Miocene eruption of more than 210,000 km3 of magma as flood basalts of the Columbia River Basalt Group covered much of the area that is now Oregon, Washington, western Idaho, and northern Nevada (Fig. 1) (Reidel et al., 2013). The main phase of flood lavas erupted between 16.9 and 15.0 Ma, accounting for ∼97% of the volume of the Columbia River Basalt Group based on the volume estimates of Barry et al. (2013). In Coble and Mahood (2012) we highlighted that widespread and voluminous silicic volcanism was contemporaneous with eruption of this main phase of the Steens and Columbia River flood basalt lavas. Between 16.6 and 15.0 Ma, a minimum of 3900 km3 of silicic magma erupted across a wide area (Figs. 1 and 2), most of it from 3 main caldera complexes located along a north-northeast–trending band in northwest Nevada and southeast Oregon: the MVF, HRCC, and Lake Owyhee volcanic field (Fig. 1; Rytuba and McKee, 1984; Cummings et al., 2000; Coble and Mahood, 2012). In addition to the three main caldera complexes, there are several lava fields where caldera-forming volcanism appears to be subordinate or lacking, including the Santa Rosa–Calico volcanic field (Brueseke et al., 2007), Hawks Valley–Lone Mountain region (Wypych et al., 2011), and the particularly voluminous Jarbidge Rhyolite (Coats, 1964; Brueseke et al., 2014) (Fig. 1), as well as volumetrically less significant silicic lava domes and flows dispersed throughout eastern Oregon, western Idaho, and northern Nevada with ages between 16.6 and 15.0 Ma (yellow and orange dots in Fig. 1).
The earliest mid-Miocene rhyolitic eruptions overlap the 16.9–16.4 Ma age of the earliest flood basalts, the Steens Basalt (Barry et al., 2013,Camp et al., 2013; cf. Baksi, 2013) (Fig. 26). The beginning of caldera-forming silicic volcanism at the HRCC and MVF at 16.4 and 16.5 Ma, respectively, coincided with a decline in Steens Basalt eruptions ca. 16.6 Ma (Fig. 26) and a shift of the locus of mafic volcanism northward from Steens Mountain to the Chief Joseph and Monument dike swarms that gave rise to Columbia River Basalt lavas between 16.7 and 15.0 Ma (e.g., Camp et al., 2003; Barry et al., 2010, 2013; Reidel et al., 2013). The northward shift of mafic volcanism was accompanied by initiation of more northern major silicic volcanism in the Lake Owyhee volcanic field (Rytuba and Vander Muelen, 1991; Rytuba, 1994; Cummings et al., 2000). A major rhyolitic ignimbrite that is interbedded within a section of Columbia River Basalt, the Dinner Creek Tuff (Rytuba and Vander Muelen, 1991; Streck et al., 2015), erupted from the northern part of the field at 16.0 ± 0.1 Ma (Nash and Perkins, 2012). The Mascall tuff, a younger widespread ash fall tuff (Nash and Perkins, 2012) that yielded a 40Ar/39Ar age of ca. 15.9 Ma at the type locality near Picture Gorge, Oregon (Swisher, 1992), is from a nearby source (Streck et al., 2015). At the southern end of the Lake Owyhee volcanic field, the weakly peralkaline, high-silica alkali rhyolite Leslie Gulch tuff erupted at 15.8 Ma, forming an ∼20 × 25 km caldera (Benson et al., 2013) (Fig. 1).
Role of Columbia River Basalt Group Flood Basalts in the Petrogenesis of Alkali Rhyolites at the HRCC
The location of the three major caldera complexes (i.e., the MVF, HRCC, and Lake Owyhee volcanic field) at the periphery of the most intense flood basalt volcanism along a north-northeast–trending band that closely coincides with location of the 87Sr/86Sri = 0.704 isopleth for basement granitoids (Fig. 1), suggests that although a large basaltic flux through the crust favors the formation of silicic magmas (e.g., Annen and Sparks, 2002; Hughes and Mahood, 2011; de Silva and Gregg, 2014), it is a necessary but not sufficient condition. The composition and thickness of the crust are the main factors controlling where large volumes of silicic magma are produced in association with flood basalts (Coble and Mahood, 2012). The 0.704 isopleth is interpreted as the western margin of transitional crust, i.e., accreted mafic terrains thrust over a craton edge attenuated by rifting and overlain by miogeoclinal sediments. It appears that all 3 caldera fields were formed on transitional crust as they all erupted rhyolites with εNd values of ∼–0.5 to +6.7 (Table 5; Tegtmeyer and Farmer, 1990; Nash et al., 2006; Coble, 2012).
We interpret the δ18O and Nd isotopic compositions of the HRCC rhyolites (Table 5) as requiring that they contain partial melts of this transitional continental crust and/or Mesozoic granitoids that formed within it. The analyzed samples of HRCC rhyolite yielded δ18O values for quartz phenocrysts in the narrow range +7.3 to +8.4‰, with the exception of the most peralkaline ignimbrite, the Soldier Meadow Tuff, which has a slightly lower value of +6.7‰ (Table 5). These data require the involvement of partial melts of crust because values >6‰ cannot be attained by fractional crystallization of mantle-derived basalt. In addition, the εNd values of the 6 analyzed rhyolites at the HRCC, –0.5 to +3.7, range to values lower than those reported for the Steens Basalt (Carlson and Hart, 1987; Wolff et al., 2008), stratigraphically the most logical parental magma and the only mid-Miocene basaltic unit voluminous enough to give rise by fractionation-assimilation processes to the large amount of mid-Miocene rhyolite erupted at the HRCC. However, given the εNd values, the origin of the HRCC rhyolites cannot have involved large amounts of felsic Paleozoic or older metamorphic or granitic basement rock.
We suggest that intrusion of the Steens Basalt provided the thermal energy to promote crustal anatexis and sustain the silicic magma chambers at the HRCC for ∼1 m.y. (Figs. 26 and 27), and given the similarities in eruptive volumes and compositions of coeval magmatism at the MVF, it is likely that the same processes operated at both caldera complexes. Modeling of isotopic compositions at both centers (Starkel, 2014; Mallis, 2014) demonstrates that fractionation of the upper Steens Basalt must have been accompanied by assimilation of transitional crust, probably in the form of Mesozoic granitoids, to produce trachytes, but little or no involvement of crust is required in fractionating trachytes to form alkali rhyolites. Similar conclusions were reached in Novak and Mahood (1986) for the mid-Miocene Kane Springs Wash caldera in southern Nevada, and by Brueseke and Hart (2009) with regard to intermediate-composition lavas at the mid-Miocene Santa Rosa–Calico volcanic field in northern Nevada.
We suggest that voluminous mid-Miocene silicic volcanism is located where a large flux of basalt coincided with relatively fertile crustal lithologies (see also Camp et al., 2013; Streck et al., 2015). Although the greatest volume of basalt erupted at Steens Mountain, where ∼950 m of lavas created a broad shield, the intrusion of flood basalt caused significant partial melting of the crust only where dikes intruded the more fertile transitional crust at the western edge of the North American craton (i.e., between the 87Sr/86Sri = 0.704 and 0.706 isopleths). Voluminous, coeval, silicic magma chambers formed at a distance of ∼75–200 km from Steens Mountain. Existing mapping indicates that there are fewer mid-Miocene calderas associated with the Columbia River Basalt than with the Steens Basalt, despite the greater volume of the former. We think that this is the case because, along most of their length, the Chief Joseph and Monument dike swarms that fed Columbia River Basalt lavas strike north or north-northwest into an area west of the 0.704 isopleth, traversing mafic accreted terrains rather than transitional crust (e.g., Camp, 1995; Camp et al., 2003, 2013). Similarly, although the greatest flux of Steens Basalt occurred at Steens Mountain, as indicated by the thickest accumulation of basaltic lavas and the highest density of mafic dikes, the silicic centers did not occur there. Instead, the voluminous rhyolitic centers of the HRCC and MVF occur where Steens Basalt intruded transitional crust.
Moreover, we suggest that where mafic intrusion rates are as high as those documented for flood basalt provinces and the crust is not fertile, sizable bodies of silicic magma do not accumulate in the upper crust to form calderas. For example, near intense zones of diking at Steens Mountain that produced extraordinarily high eruption rates of 0.3–0.6 km3/yr (Jarboe et al., 2010; Barry et al., 2013), the small amounts of silicic melts produced from partially melting mafic crust may have been insufficient to coalesce into separate magma bodies and were incorporated into the basaltic magmas instead. Partial melting of the crust in the absence of accumulation of silicic magma bodies of significant size may explain at least part of the difference in composition between the lower and upper Steens Basalt (e.g., Hart et al., 1989; Johnson et al., 1998; Camp et al., 2003, 2013). The more evolved and alkalic character of the upper Steens may reflect the temporal evolution of the thermal state of the middle and upper crust, with the upper Steens compositions reflecting significant contamination by crust (e.g., Hart et al., 1989; Wolff et al., 2008; Ramos et al., 2013), whether by direct incorporation of crustal partial melts or by cannibalization of hybridized gabbroic bodies by subsequent intrusions.
Dikes and shallow sills within the section of Steens Basalt in the Pueblo Mountains (Hart et al., 1989) and the Pine Forest Range (Colgan et al., 2010) are proof that basalt was being injected into the crust near the HRCC and Hawks Valley–Lone Mountain center, and that the flood basalt in these sections does not simply consist of far-traveled lava flows that erupted from the focus at Steens Mountain farther north. We suggest that the abrupt southward thinning of the flood basalt section across what is now the Oregon-Nevada border, from nearly 1 km in the northern Pueblo Mountains to its near-absence south of 41.55°N, is due to a feedback mechanism, wherein once a critical mass of silicic magma is generated in the crust by advection of heat by basaltic intrusions, eruptions of flood basalt largely cease in that area as subsequent intrusions of basaltic magma are intercepted by a low-density silicic melt zone (e.g., Annen and Sparks, 2002; de Silva and Gregg, 2014). While flood basalt eruptions continue elsewhere (Figs. 26 and 28), the stagnation of rising basaltic intrusions thermally sustains the silicic magma chambers and contributes to their growth (Fig. 27).
A consequence of this model is that one would not expect to see the causative Steens Basalt erupting at the surface above the locus of partial melting; there is a near absence of basaltic eruptions for ∼1 m.y. in the HRCC. We have analyzed two alkali basalts from localities within the HRCC proper that have chemical similarities to upper Steens Basalt (MC342 and MC434 in Figs. 4, 6, 13–15). MC342 has an εNd value of +4 (Table 5), within the range for the Steens Basalt (Wolff et al., 2008). Both are strongly porphyritic, with plagioclase phenocrysts exceeding olivine. MC342 is a small outcrop near the ring fault of the Hanging Rock caldera. Although the field relations are not entirely clear due to extensive faulting along the caldera margin, the lava appears to overlie the 16.34 Ma Summit Lake Tuff and underlie 16.3 Ma Hell Creek lavas, an age consistent with it being upper Steens Basalt. MC434 is from a phreatomagmatic deposit within the caldera fill sequence at the overlap of the Badger Mountain and Hanging Rock calderas. Its stratigraphic position suggests an age between ca. 16.0 and 15.5 Ma, which would make it younger than nearly all dated examples of Steens Basalt lavas (Fig. 26).
An important observation concerning mafic volcanism at the HRCC is that we have found almost no stratigraphic or geochronologic evidence for eruption of basaltic magmas during the interval silicic volcanism was active within the HRCC. The possible exceptions are the aforementioned small volumes of Steens composition basalt that erupted along the intersections of the ring-fracture zones of the Badger Mountain and Hanging Rock calderas. The fact that almost no basalt erupted for ∼1 m.y. along the entire 110 km length of the HRCC suggests that there was a continuous zone of partial melting and/or silicic magma bodies that largely prevented penetration of basalt into the upper crust (Fig. 27).
A large flux of flood basalt into the roots of the HRCC magma chambers would allow eruption of large volumes of crystal-poor rhyolite. We observe that crystal-poor rhyolites (<15 vol% phenocrysts) erupted throughout most of the history of the HRCC but appear to be lacking for the interval 16.1–15.9 Ma (Fig. 25B). This is also an interval of much lower than average volumetric eruptive rate (Fig. 25A). We speculate that this interval may represent a relative lull in the flux of Steens Basalt beneath the HRCC, which allowed magma within the Hanging Rock caldera magma chamber to differentiate to the highly evolved yet phenocryst-rich compositions found in the Soldier Meadow Tuff and Soldier Meadow lavas, and allowed magma beneath Badger Mountain caldera to crystallize to a high degree. At 15.9 Ma, rhyolitic eruptions began at the site of the southernmost caldera, Cottonwood Creek, and, simultaneously, eruptive activity renewed within Badger Mountain caldera. This suggests that intrusion of Steens basalt dikes beneath the HRCC reached their southernmost extent at this time, initiating activity in the south with crystal-poor alkali rhyolites, while, beneath the older Badger Mountain caldera, mobilizing crystal mushes to erupt as the Mahogany Mountain lavas (to 55% phenocrysts) (Table 2; Fig. 25B).
The compositions of alkali rhyolite lavas of Mahogany Mountain lavas became less alkalic over the ∼0.5 m.y. they erupted. Mlmm-1 lavas are similar to the Soldier Meadow Tuff (Fig. 5), suggesting some physical continuity between magma beneath the Hanging Rock caldera and the magma that initiated uplift and renewed activity in the Badger Mountain caldera. Mlmm-3 lavas are the least peralkaline, and overlap the compositional range of the tuff of Big Mountain and Antelope lavas (Fig. 5), which erupted along the Virgin Valley caldera ring fracture ∼600 k.y. earlier, suggesting that this may represent a baseline composition to which HRCC magmas return after highly fractionated magmas are removed by eruption, similar to other large silicic magma systems (e.g., Smith, 1979; Hildreth et al., 1991).
Based on our new 40Ar/39Ar ages, it appears that the volumetric eruptive rate of alkali rhyolites at the HRCC declined precipitously by ca. 15.6 Ma (Fig. 25A). Given that magma chambers associated with peralkaline rhyolites are neither deep nor large (Mahood, 1984), they would cool quickly in the absence of continued heat inputs from below. Therefore, we postulate that flood basalt dikes ceased propagating beneath the HRCC at about that time.
Interaction of Postcaldera Alkali Basalt and Intermediate Lavas with the HRCC Silicic Magma Reservoir
After peralkaline volcanism ceased at the HRCC, mafic to intermediate lavas (Mm, Mt) erupted (Fig. 26) from vents within HRCC calderas along buried ring-fracture zones and trapdoor-uplift faults in all but the Virgin Valley caldera (Fig. 4). In each case these lavas erupted ∼400 k.y. after the youngest peralkaline rhyolite in that particular caldera. We interpret this as representing the time required for the underlying silicic magma bodies to cool and crystallize to a rigid crystal mush, allowing brittle fracture and intrusion of younger mafic dikes.
Feldspar-rich cumulate mush beneath the HRCC must have been partially rejuvenated and remelted during intrusion of postcaldera mafic magma, as some of the nearly aphyric 15.4–14.5 Ma trachytic lavas erupted in the Hanging Rock caldera have positive Eu anomalies (Fig. 15) and Ba concentrations exceeding 9600 ppm (Table 4), suggesting a contribution from an anorthoclase-rich cumulate. However, we have not found evidence of basalts making it to the surface in the Hanging Rock caldera.
We link the small-volume, metaluminous lavas that postdate all the peralkaline volcanism to the postcaldera alkalic basalts and intermediate lavas. Stratigraphically, the rhyolite lavas of Wall Canyon (Mlwc) and Rock Springs Canyon (Mlrs) overlap in age with immediately postcaldera alkalic mafic and intermediate lavas. They are small in volume and erupted at the intersection of structural features that were also utilized by the postcaldera mafic and intermediate lavas. Rhyolite lavas of Wall Canyon contain abundant dark colored, trachytic(?) magmatic enclaves near vents. These observations, along with their metaluminous compositions, lead us to suggest that they represent local melting of hot wall rocks by intrusion of small volumes of postcaldera mafic magmas, rather than significant renewal of an underlying silicic magma reservoir; they are only indirectly related petrogenetically to the large volume of peralkaline rhyolites that dominated most of the eruptive history of the HRCC.
We suggest that the metaluminous rhyolite lavas that characterize the earliest (Mlnm) and latest stages (Mlwc and Mlrs) of silicic volcanism at the HRCC may represent small-scale partial melting involving a greater proportion of crust during the waxing and waning stages, respectively, of basaltic magmatism. During the waxing stages, this low-melting-temperature component was transitional crust. During the waning stages of silicic volcanism, the crust was extensively transformed by the preceding HRCC magmatism (Fig. 27), and the most easily melted material would be heated wall rocks around former HRCC magma reservoirs and alkali granites or syenitic cumulates that remain within them.
Comparison of Eruptive Rates at the HRCC with Large Silicic Provinces Globally
The intensity of the silicic volcanism contemporaneous with flood basalt magmatism can be demonstrated for the HRCC due to the level of mapping and the number of new ages determined in this study. Four calderas 24–40 km in diameter formed in a span of only ∼0.7 m.y. During the interval 16.6–15.5 Ma, an estimated minimum volume of 700 km3 (DRE) of rhyolitic magma erupted at the HRCC, which accounts for nearly 20% of the total volume of silicic magma erupted regionally between 16.5 and 15.0 Ma. Estimated volumetric eruptive rates average ∼700 km3/m.y., but rates were as low as ∼200 km3/m.y. prior to eruption of the most peralkaline of the units, the Soldier Meadow Tuff, and, shortly thereafter, briefly as high as 2000–4000 km3/m.y. during eruption of lavas associated with uplift and renewed volcanism in the Badger Mountain caldera (Fig. 25). During the interval of lowest eruptive rates, there was time for differentiation in the subjacent magma reservoirs to produce the most evolved alkali rhyolites erupted in HRCC history. When eruptive rates were highest, evolved magmas were tapped out, resulting in a progressive decline in the peralkalinity of Mahogany Mountain lavas with time.
Our estimates of volumes and eruptive rates are minimum values. They are based on a conservative reconstruction of the distribution of extracaldera ignimbrite (Fig. 5; see Supplemental Fig. 2 for isopach maps), which could be underestimated by as much as 25% because the bases of measured sections are rarely exposed. More significantly, unexposed intracaldera ignimbrite may equal or exceed the volume of outflow sheets. Adopting a conservative estimate of 1:1 for the ratio of extracaldera to intracaldera ignimbrite would make the total eruptive volume at the HRCC ∼1400 km3. We note that the resulting volumetric eruptive rates using these larger estimates are still only ∼1% of those for the Columbia River Basalt Group flood lavas.
The eruptive volumes for the HRCC and MVF (assuming extracaldera:intracaldera = 1:1), the oldest caldera complexes along the Snake River Plain–Yellowstone trend, are less than half those of the younger Bruneau-Jarbidge and Yellowstone Plateau complexes, and the volcanism lasted about half as long (Fig. 28). This is the case despite the spatial and temporal association of the HRCC and MVF with the voluminous flux of Steens and Columbia River flood basalts, whereas the younger complexes are interpreted as being related to the smaller volumes of mantle melt associated with the Yellowstone plume tail. This highlights the importance of the nature of the crust in controlling the volume of silicic magma produced. The caldera complexes along the Snake River Plain–Yellowstone are east of the Sri = 0.706 isopleth, and formed in thicker, more fertile cratonic crust, which promotes growth and storage of larger, longer lived silicic magma reservoirs than those in mafic crust (e.g., Hildreth, 1981; Annen et al., 2006; White et al., 2006; Hughes and Mahood, 2011; Lipman and Bachmann, 2015).
In aggregate, the pulse of silicic magmatism between ca. 16.7 and 15.0 Ma contemporaneous with Steens Basalt and Columbia River Basalt has a total volume and duration similar to other silicic provinces coeval with flood basalt eruptions globally (Fig. 28). Although the number of published studies with volume estimates and accurate geochronology is limited (e.g., Garland et al., 1995; Ukstins Peate et al., 2005; Pankhurst et al., 2011), the available data for the Steens, Columbia River, Deccan Traps, Karoo, Yemen-Ethiopia, and Paraná-Etendeka flood basalt provinces indicate that they have volumetric eruptive rates of silicic magmas between ∼2500 and 12,000 km3/m.y. (Fig. 28; see for data shown in this figure).
The relatively short pulse of moderate-volume silicic magmatism from 16.7 to 15.0 Ma in northern Nevada, southern Oregon, and western Idaho associated with the Steens and Columbia River flood basalts is in contrast to the regional magmatic events during the Eocene to Oligocene ignimbrite flare-ups in the Great Basin and Rocky Mountains (e.g., Best and Christiansen, 1991; Christiansen and McCurry, 2008) that culminated in the some of the largest supereruptions on Earth (Bryan et al., 2010; Best et al., 2013; Henry and John, 2013; Lipman and Bachmann, 2015). Globally, the total volumes of silicic magma erupted in ignimbrite flare-up provinces is 2–10 times greater than the volumes erupted in flood basalt provinces (Fig. 28). These enormous volumes are not, however, a result of more intense silicic volcanism. Most ignimbrite flare-up provinces have volumetric eruptive rates smaller than flood basalt provinces, ∼1000–2000 km3/m.y., and only the Sierra Madre Occidental (Bryan and Ferrari, 2013; McDowell and McIntosh, 2012) and Chon Aike (Pankhurst et al., 1998, 2000) flare-up provinces have rates that equal the upper end of those calculated for the flood basalt provinces, 12,000 km3/m.y. Ignimbrite flare-up provinces have huge volumes because eruptions continue for 10–20 m.y., ∼10 times longer than silicic volcanism associated with flood basalts (Fig. 28). We suggest that these contrasts in total volume and duration are due primarily to the different time scales over which heat is advected into the crust by mantle melts in these two types of provinces, and secondarily to the nature of the crust in which they occur.
In continental flood basalt provinces, >100,000 km3 of basaltic magma (Bryan and Ernst, 2008) erupts over a period of 1–2 m.y., with most of the volume being supplied over intervals as short as hundreds of thousands of years (e.g., Courtillot and Fluteau, 2014). This huge throughput is consistent with the model that the basalts are produced rapidly by decompression partial melting of a mantle plume head upwelling beneath the base of the lithosphere (e.g., Campbell and Griffiths, 1990; Anders and Sleep, 1992; Pierce and Morgan, 1992; Pierce et al., 2002; Hooper et al., 2007). Once the plume head has undergone shallow melting, the basaltic flux would drastically decrease to produce the small-degree partial melts that might be induced in the subcontinental mantle lithosphere or the asthenosphere by conductive heating by the plume (e.g., at the HRCC, the chemically distinct, relatively small volume, postcaldera alkali basalts and similar basalts erupted in the Smoke Creek Mountains and Northern Nevada Rift; Fig. 13).
In comparison to this short-lived event, the prolonged duration of volcanism in ignimbrite flare-ups (Fig. 28), which can wax and wane through time (Salisbury et al., 2011; McDowell and McIntosh, 2012), suggests a geodynamic process that causes much longer term production of mantle melting. Ignimbrite flare-up provinces typically occur or are interpreted to have formed in subduction settings behind the volcanic front, in some cases in crust overthickened by a previous flat-slab subduction event (e.g., Best et al., 2009; Lipman and Bachmann, 2015). They are thought to be associated with backarc extension, rollback of a subducting slab, delamination of the base of overthickened lithosphere (Kay et al., 1994; Dufek and Bergantz, 2005; de Silva et al., 2006; Farmer at al., 2008), or, in the particular case of the Eocene to Oligocene of western North America, the falling away of the Farallon slab, which brought hot mantle into contact with subcontinental lithosphere previously hydrated by subduction processes (e.g., Best and Christiansen, 1991; Humphreys, 1995, 2009; Henry and John, 2013). All of these processes involve the upward flow of depleted, upper mantle asthenosphere to shallower depths in compensation, which would undergo decompression melting and also heat the overlying mantle lithosphere (e.g., Farmer et al., 2008). We speculate that although mantle melting may not be as productive as when undepleted plume-related mantle undergoes partial melting, the magmatism in this tectonic setting is sustained over a longer period of time.
The differences in composition and phenocryst mineralogy of the rhyolites erupted in ignimbrite flare-ups and in flood basalt–related provinces indicate a contrast in the type and proportion of crustal melts involved in their genesis. Silicic magmas in ignimbrite flare-ups tend to be cooler, richer in water, and more oxidized than those in flood basalt provinces, and peralkaline rhyolites are lacking (Christiansen and McCurry, 2008). This is consistent with the observation that ignimbrite flare-up provinces occur where the continental crust is relatively thick and fertile. Although basalts are greatly subordinate to intermediate and silicic rocks at the surface in ignimbrite flare-up provinces, the huge volumes of rhyolite produced that contain significant proportions of mantle-derived material (e.g., ∼50% for the southern Rocky Mountain and Mogollon-Datil volcanic fields; Farmer et al., 2008; ∼30% for Altiplano-Puna; de Silva et al., 2006) require a sizable supply of basalt into the lower and middle crust that drives crustal anatexis (de Silva and Gregg, 2014). A sustained basaltic flux into thick, fertile crust creates the conditions for development of a large zone of partial melting in the crust, and the assembly and thermal maintenance of large, long-lived silicic magma chambers (e.g., Annen et al., 2006; Bachmann et al., 2005; Lipman, 2007; de Silva and Gregg, 2014).
Expression of Mid-Miocene Caldera Magmatism in Modern Basin and Range Topography
The modern topography in northwestern Nevada and southern Oregon is largely the result of post-HRCC Basin and Range extension concentrated along large-magnitude, north-northeast–trending, range-bounding normal faults (Colgan et al., 2006; Colgan and Henry, 2009). The HRCC is on the eastern edge of the Modoc Plateau, which has undergone less extension than the rest of northwest Nevada (5%–10% versus 15%–25% since the mid-Miocene; Wells and Heller, 1988; Colgan et al., 2006). Even so, the calderas of the HRCC are remarkably little affected by Basin and Range faulting. The largest faults within the complex are all associated with caldera collapse, and many of the smaller faults are associated with magmatic uplift or with regional postcollapse downsagging around the calderas (Figs. 2–4). Normal faults with the regional north-northwest to north-northeast extension-related trends have maximum offsets of a few tens of meters within the calderas, whereas immediately east of the calderas in the Black Rock Range outflow ignimbrites are offset hundreds of meters along regional normal faults, and farther north in the southern Pueblo Mountains and northern Pine Forest Range, the section of Steens Basalt and overlying outflow ignimbrites from the MVF are tilted westward as much as 45° (Burnam, 1970; Colgan et al., 2010).
The same pattern can be seen at the MVF, where large-offset normal faults (shown with thick black lines in Fig. 2) do not offset the McDermitt or Whitehorse calderas, but sections consisting of stacked outflow ignimbrites are faulted and tilted. We interpret the fault along the west side of the Montana Mountains to have reactivated a McDermitt caldera ring-fracture zone, just as the normal fault on the east side of McGee Mountain at the HRCC reactivated the Virgin Valley caldera ring fracture (Figs. 3 and 4).
Based on apatite fission-track data from the Pine Forest Range, it was suggested (Colgan et al., 2006) that in northwestern Nevada the onset of significant extension occurred at 12–7 Ma. This age range coincides with the onset of eruption of HAOT lavas across southern Oregon, northern Nevada, and northeastern California (Hart et al., 1984; Hart, 1985; Carlson and Hart, 1987; Bailey and Conrey, 1992; Jordan et al., 2004; Carmichael et al., 2006; this study), suggesting that a post–16 Ma episode of extension allowed these partial melts of depleted, asthenospheric, upper mantle (Hart et al., 1984) to erupt at the surface. HAOT lavas are present only in the northern part of the HRCC, where they are 10–8 Ma, and the thin (<10 m) flows form prominent mesas or tables that are flat-lying or tilted <5°. In contrast, 8–3 Ma HAOT lavas west of the HRCC are cut by prominent normal faults and are tilted as much as 15° in the Hays Canyon Range (Carmichael et al., 2006) and at Massacre Rim (Trugman, 2011). Moreover, we have not identified vents for HAOT flows within the HRCC; the lavas in the northern half of the complex flowed south from vents north and northwest of the complex (e.g., Bitner Butte in Fig. 3), suggesting that the complex was not affected by the minor extension that allowed eruption of HAOT lavas.
Additional evidence that the HRCC complex has not undergone significant extension since its formation is that we have not identified basinal sediments between the HAOT lavas and underlying caldera fill (cf. Greene, 1984; Castor and Henry, 2000). The Rock Spring Table HAOT flow directly overlies the tuff of Big Mountain and fine-grained lacustrine sediments in the Virgin Valley caldera, and, where it flowed into the Badger Mountain caldera, it directly overlies the tuff of Alkali Flat and Badger Mountain east of Alkali Flat (Figs. 3 and 4). These observations are consistent with the results of Nash and Perkins (2012) that show, through chemical correlation of ashes in the Virgin Valley caldera with regionally extensive units, that the upper part of the caldera fill is ca. 14.3 Ma. The absence of late Miocene sediment is evidence that the HRCC remained an elevated plateau, and was not significantly affected by the regional extensional event that began ca. 16 Ma (Colgan and Henry, 2009), or by local extension that began ca. 12 Ma (Colgan et al., 2006). As a result of the only minor offset on extension-related faults (as opposed to caldera collapse– or trapdoor uplift–related faults), the HRCC today is a volcanic plateau that is physiographically similar to conditions in the mid-Miocene (Merriam, 1910; Mulch et al., 2008; Hilton et al., 2008).
Role of Mid-Miocene Magmatism in Strengthening the Crust
We interpret the observation that major Basin and Range normal faults do not transect the High Rock and McDermitt caldera complexes, and that major range-bounding faults appear to be deflected around them, as evidence that mid-Miocene magmatism at the HRCC and MVF transformed the lithosphere beneath the caldera complexes to make it stronger than surrounding areas. We suggest that intense, focused rhyolitic and basaltic magmatism locally modified the entire crustal column and created strong localized structural blocks that have not been cut by Basin and Range normal faults. As a result, the caldera complexes remain as elevated plateaus, and the structural and topographic margins of the calderas are unusually well preserved.
Low seismic velocities in the middle to upper crust beneath the HRCC have been interpreted as reflecting the presence of Jurassic and Cretaceous granitic rocks (Lerch et al., 2007; Van Buer et al., 2009). Although this is possible, we note that the nearest granitic rocks are exposed well east of the HRCC in the Pine Forest Range and Pueblo Mountains. Granitic lithics are absent in the many ignimbrites erupted from the HRCC, indicating that granitic rocks (and, for that matter, other basement lithologies) are absent from the upper crust beneath the calderas. We think it is equally or more plausible to interpret the low seismic velocities in the middle to upper crust beneath the HRCC (Lerch et al., 2007) as silicic to intermediate plutons associated with mid-Miocene silicic volcanism.
However, we do not believe that the crustal blocks beneath the HRCC and MVF are strong solely because they have been stitched together by overlapping upper crustal plutons into small batholiths the sizes of the caldera complexes. Quartz-rich rocks are not strong at mid-crustal depths, especially under conditions of high heat flow characteristic of the Basin and Range Province (Kusznir and Park, 1987; Bürgmann and Dresen, 2008). Rather, we believe that the strength of these blocks is due mostly to the presence of a significant volume of dry gabbros in the middle crust, largely the crystallized remains of flood basalt magmas that were intercepted by bodies of low-density silicic melt and the cumulates that resulted from their fractionation and the extraction of trachytic and rhyolitic melts (Fig. 27). We suggest that the resulting network of mafic sills and dikes in the middle crust began to cool ca. 15.6 Ma, at the end of peralkaline volcanism at the HRCC, which we interpret as the time when the focus of intrusion of flood basalt magmas shifted northward and the flux of Steens Basalt declined (Fig. 26). Final cooling of mid-crustal gabbroic bodies would have occurred at the cessation of postcaldera mafic and trachytic magmatism in the HRCC by ca. 14 Ma. These solidified gabbroic bodies locally strengthened the crust beneath the HRCC and MVF. Later, when major regional normal faulting began ca. 12–7 Ma as a result of the northward progression of the Basin and Range extension into the HRCC area (Colgan et al., 2004, 2006), large-magnitude, north-northeast–trending normal faults were concentrated along the Santa Rosa, Pine Forest, Black Rock, and Warner Ranges, and avoided the HRCC and MVF (Fig. 2).
The Pueblo Mountains and Steens Mountain expose thick sections of Steens flood basalt lavas along major range-bounding normal faults, indicating that the crust beneath these areas was not as strong as at the HRCC and MVF. In our model, despite the intense intrusion of mafic magma at Steens Mountain, only minor volumes of silicic partial melts were formed there due to the less fertile nature of the crust (i.e., west of the 0.704 Sri isopleth). We suggest that in the absence of significant bodies of silicic magma in the middle and upper crust, basaltic dikes were not impeded in their rise through the crust, and large mid-crustal gabbroic bodies did not form. Therefore, despite the large volume of basalt erupted at Steens Mountain, the middle crust beneath Steens Mountain was not rendered as strong as at the HRCC or at MVF, where upper crustal silicic bodies caused large volumes of mafic magma to pond and hybridize in mid-crustal reservoirs (Fig. 27).
Additional evidence for the importance of mid-crustal gabbroic bodies for strengthening the crust is the observation that Paleogene calderas of the ignimbrite flare-up in the central Great Basin have been strongly extended and tilted such that cross sections of the calderas and the underlying plutonic underpinnings are exposed (e.g., Caetano caldera, Colgan et al., 2008; Stillwater caldera complex, John, 1995). These calderas differ from the mid-Miocene plume-related rhyolites in that they formed in fertile, cratonic crust that was close to its solidus due to thermal relaxation following a Laramide shortening event and exposure to strong thermal gradients due to delamination of the lower crust and/or the falling away of a shallowly dipping slab (e.g., Humphreys, 1995; Christiansen and McCurry, 2008; Best et al., 2009). As a result, a smaller flux of basalt was required to melt the crust, and there was extensive hybridization between basalts and crustal melts (e.g., the isotopic data for the Mogollon Datil and San Juan Mountains fields requiring that the rhyolites consist of a 50:50 mixture of crust and mantle-derived basalt; Farmer et al., 2008). Because of the extensive crustal anatexis and hybridization of the basalts, large volumes of mid-crustal gabbroic bodies did not form and the crust was not significantly strengthened beneath Paleogene caldera complexes. We argue that the crust beneath the HRCC and MVF has been uniquely modified by voluminous and intense intrusion of flood basalt magmas that fueled moderate amounts of melting of transitional continental crust, enough to cause ponding of basalt in the middle crust, but not enough for extensive hybridization between basalt and crustal melts. We suggest that, as a result, mid-crustal mafic intrusions are below a seismically imaged low-density HRCC granitoid in the upper crust (Fig. 27).
The volcanic and volcaniclastic rocks of the HRCC represent one of the best-preserved and best-exposed examples of the original geometry and geomorphology of silicic volcanism related to flood basalt eruptions anywhere on Earth. The HRCC consists of overlapping mid-Miocene rhyolitic calderas and their products that cover an area of ∼8300 km2 in northwestern Nevada and southern Oregon near the southern extent of the Steens Basalt flood lavas (Figs. 1, 4, and 5). A minimum estimated volume of ∼700 km3 of peralkaline rhyolitic magma (DRE), ∼60% of the total as lavas, erupted during an ∼1 m.y. interval between 16.4 and 15.5 Ma. Four major calderas 24–40 km in diameter formed at 16.38, 16.34, 16, and 15.70 Ma on eruption of moderate-sized ignimbrites that ranged in composition from high-silica alkali rhyolite to trachyte (Figs. 5 and 6).
Thick sequences of caldera fill accumulated in caldera lakes, including fine-grained, diatomaceous, ashy sediments that contain abundant petrified wood and opal. Ring-fracture lavas that erupted into the caldera lakes at the Virgin Valley and Cottonwood Creek calderas were strongly altered and host minor Au and U mineralization. In contrast, volcanism associated with uplift and late-stage renewal of magmatism in the Badger Mountain caldera is associated with little alteration, only fault-localized silicification.
After peralkaline rhyolitic volcanism ceased, trachyte to trachyandesite lavas erupted along the ring fracture of the Hanging Rock caldera. The positive Eu anomalies and high Ba concentrations in these phenocryst-poor lavas suggest that they represent melting of feldspar-rich cumulate material formed earlier in the history of the HRCC. Alkali basalts through trachytes erupted at the Badger Mountain caldera, and alkali basalt erupted at the Cottonwood Creek caldera. Eruption of these mafic to intermediate lavas between 15.5 and 14.2 Ma indicates that the underlying silicic magma reservoirs had cooled to the point that they could sustain brittle fracture and diking.
Voluminous mid-Miocene silicic magmatism at the HRCC, MVF, and Lake Owyhee volcanic field is located where flood basalt dikes encountered fertile crustal lithologies at the western margin of the North American craton. Beginning ca. 16.9 Ma, flood basalt magma focused at Steens Mountain began to intrude southward as dikes along zones of preexisting crustal weakness, causing significant partial melting of the crust where dikes intruded transitional crust at the craton margin (i.e., between the 87Sr/86Sri = 0.704 and 0.706 isopleths). The stagnation of these basaltic dikes within zones of partial melting in the crust and beneath low-density upper crustal magma chambers provided heat that sustained voluminous rhyolitic magmatism at both the HRCC and MVF for ∼1 m.y. Upon cooling, hybridized gabbroic equivalents of intruded Steens Basalt locally strengthened the crust beneath calderas at the MVF and HRCC, so they are little affected by normal faulting compared to surrounding areas of the Basin and Range Province and remain elevated plateaus.
The eruptive products of the HRCC and MVF are among the >3900 km3 of rhyolite that erupted across a large area in the Nevada-Oregon-Idaho border region between 16.6 and 15.0 Ma. This widespread occurrence over a short period of time that followed initiation of Steens Basalt volcanism by ∼0.2 m.y. and coincided with main stage Steens and Columbia River flood basalt volcanism (Fig. 26) is consistent with the rhyolitic centers of the Nevada-Oregon-Idaho border region marking the spread of a mantle plume head at the base of the North American lithosphere beginning ca. 17 Ma. The overall volumetric eruptive rates of widespread mid-Miocene silicic volcanism associated with Steens Basalt and Columbia River Basalt are in the range of other flood basalt–related silicic provinces globally, 2500–12,000 km3/m.y. These rates exceed those at most ignimbrite flare-up provinces, which attain their large volumes by having durations an order of magnitude longer than the short lived but more intense volcanism that is interpreted as being related to arrival of a mantle plume beneath continental lithosphere.
We suggest that the initiation point of the focused trend of eastward-younging silicic calderas along the Snake River Plain encompasses the caldera complexes of the HRCC and MVF along with nearby lava-dominated centers at Hawks Valley–Lone Mountain and Santa Rosa–Calico volcanic centers. The smaller volume and presence of peralkaline compositions among the rhyolites that erupted at 16.6–15.0 Ma in the Nevada-Oregon-Idaho border region compared to the younger, metaluminous, and voluminous rhyolitic eruptions in the Snake River Plain and at Yellowstone can be explained by the thinner and more mafic composition of the crust west of the craton boundary.
This paper is based on Coble’s Ph.D. thesis. Coble thanks Joseph Colgan, Derek Lerch, and Chris Henry for discussing their work in the area at the initiation of this project, Jim Rytuba for his continued support and guidance, and Jonathan Glen for instructing him on collecting paleomagnetic data. This project would not have been possible without the work of Marty Grove to revitalize the argon geochronology laboratory at Stanford, and the help of Andy Calvert in calibrating the Nu instrument. We thank Tom Benson for performing additional X-ray fluorescence analyses that allowed further correlation of ignimbrites, and Jonathan Glen for providing the regional aeromagnetic and gravity maps. We appreciate the efforts of Benson, A. Strickland, H. Mix, S. Pitter, E. Pope, V. Mitchell, K. Maier, G. Hughes, and A. Trugman as field assistants. Discussions with Benson, Grove, and Elizabeth Miller were helpful in writing early drafts of the manuscript. We appreciate the efforts of reviewers Matt Brueseke and Martin Streck, and editors Ben Ellis and Shan de Silva. Financial support was provided by the U.S. Geological Survey, National Cooperative Geologic Mapping Program, under Award No. 185 08HQAG0037 awarded to Mahood, and a Stanford–U.S. Geological Survey Fellowship and a Stanford School of Earth Sciences McGee Fund grant to Coble.