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Journal Article

River-evolution and tectonic implications of a major Pliocene aggradation on the lower Colorado River: The Bullhead Alluvium Open Access

Keith A. Howard, P. Kyle House, Rebecca J. Dorsey, Phillip A. Pearthree
Journal: Geosphere
Published: 01 February 2015
Geosphere (2015) 11 (1): 1–30.
DOI: https://doi.org/10.1130/GES01059.1
...Keith A. Howard; P. Kyle House; Rebecca J. Dorsey; Phillip A. Pearthree Abstract The ∼200-m-thick riverlaid Bullhead Alluvium along the lower Colorado River downstream of Grand Canyon records massive early Pliocene sediment aggradation following the integration of the upper and lower Colorado River...
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View PDF for article title, River-evolution and tectonic implications of a major Pliocene aggradation on the lower Colorado River: The <span class="search-highlight">Bullhead</span> <span class="search-highlight">Alluvium</span>
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Longitudinal profile of elevations of exposed Pliocene Bullhead Alluvium (dots) and tentatively identified exposed and subsurface Bullhead Alluvium (squares) projected to the historic Colorado River (red curve from La Rue, 1925). Bedrock canyons are shown in gray. Pre-Bullhead Bouse Formation lakes are from Spencer et al. (2013). Dated pre-Bullhead units (Table 1) restrict the Bullhead strata to be younger than 6.0 Ma Hualapai Limestone in Temple Basin, younger than 5.6 Ma Lost Cabin beds that underlie Bouse Formation in Cottonwood Valley, and younger than 4.8 Ma Bouse Formation in Blythe Basin. (A) Bullhead profile II is the estimated top of the Bullhead Alluvium. Bullhead profile I at the base of the aggradation sequence is bracketed between the lowest exposures (typically near modern river level) and uncertainly correlated subsurface occurrences (see Table A1). Pre-Bullhead Bouse Formation, Miocene rocks, or basement below undated Colorado River deposits at dam sites and other locales in the valley thalweg limit the maximum possible depths of Bullhead strata (blue Xs). (B) Dates (red, in Ma) in the Bullhead strata are from Faulds et al. (2001), House et al. (2008b), and Matmon et al. (2012); dated speleothems are from Polyak et al. (2008; elevations from Polyak, 2013, written commun.). Envelopes on the elevation extent of the late Pleistocene Chemehuevi Formation (0.07 Ma; Malmon et al., 2011) are shown for comparison with the Bullhead profiles.

Longitudinal profile of elevations of exposed Pliocene Bullhead Alluvium (d... Open Access

Published: 01 February 2015
Figure 3. Longitudinal profile of elevations of exposed Pliocene Bullhead Alluvium (dots) and tentatively identified exposed and subsurface Bullhead Alluvium (squares) projected to the historic Colorado River (red curve from La Rue, 1925 ). Bedrock canyons are shown in gray. Pre-Bullhead Bouse
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Geologic maps of type and reference sections of Bullhead Alluvium (located in Fig. 2). (A) Geologic map of proposed stratotype Bullhead Alluvium in the Tyro Wash area, Arizona. Rectangle outlines an area of easily accessible typical exposures. Map is modified from House et al. (2005a). (B) Geologic map of reference section for the basal Bullhead Alluvium (area near box west of the river) near Laughlin, Nevada, where it rests with erosional unconformity on Bouse Formation limestone and Miocene conglomerate (House et al., 2005). Scattered exposures on the Bullhead City, Arizona piedmont (east of the river) occur up to the apparent top of the formation at the highest exposures at 402 m above sea level. Map is modified from Faulds at al. (2003).

Geologic maps of type and reference sections of Bullhead Alluvium (located ... Open Access

Published: 01 February 2015
Appendix Figure A1. Geologic maps of type and reference sections of Bullhead Alluvium (located in Fig. 2 ). (A) Geologic map of proposed stratotype Bullhead Alluvium in the Tyro Wash area, Arizona. Rectangle outlines an area of easily accessible typical exposures. Map is modified from House et
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Photographs of Bullhead Alluvium (E–K) and probably correlative Pliocene Colorado River fluvial sediments, arranged from upstream to downstream. (A–B) Conglomerate and cross-bedded sandstone stratigraphically above 4.4 Ma basalt of Sandy Point. (C) Imbricated conglomerate and underlying cross-bedded sandstone. (D) Typical conglomerate showing roundness. (E) Interbedded conglomerate and sandstone. (F) Boulder conglomerate resting on light-toned Miocene fanglomerate. (G) Cross-stratified sandstone and conglomerate in the proposed type section. (H) Cross-bedded pebbly sandstone. (I) Cross-bedded sandstone and conglomerate containing 0.3 m clay balls (arrows). (J) Interbedded clay and fine sand and overlying loose sand high in the Bullhead Alluvium (270 m above sea level). (K) Cross-bedded sandstone and mudstone interbeds (Sacramento Wash). (L) Interbedded very fine sand, silt, and silty clay. (M) Cross-bedded conglomerate and sandstone. (N) Reddish, thick-bedded, cross-bedded C-suite sandstone typical of Arroyo Diablo Formation above gray, thinner-bedded, biotite-rich, locally derived interbeds typical of Olla Formation.

Photographs of Bullhead Alluvium (E–K) and probably correlative Pliocene Co... Open Access

Published: 01 February 2015
Figure 8. Photographs of Bullhead Alluvium (E–K) and probably correlative Pliocene Colorado River fluvial sediments, arranged from upstream to downstream. (A–B) Conglomerate and cross-bedded sandstone stratigraphically above 4.4 Ma basalt of Sandy Point. (C) Imbricated conglomerate and underlying
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Examples of Bullhead alluvium. (A) Well-rounded, lithologically diverse river gravel lag on the Black Mountain piedmont at 400 m above sea level (asl), northern Mohave Valley. Clasts in the foreground range from pebbles to small cobbles. (B) Coarse rounded gravel on an approximately 2.5-m-high pedestal in Lake Mohave (195 m asl) in Cottonwood Valley. (C) Moderately indurated, cross-stratified, quartz-rich sand and rounded gravel at river level (150 m asl) near Fort Mohave in northern Mohave Valley (note woman and dogs for scale). Photo locations are shown on Figure 12 where corresponding elevations (A: 400 m; B: 195 m; and C: 150 m) are listed.

Examples of Bullhead alluvium. (A) Well-rounded, lithologically diverse riv... Open Access

Published: 01 December 2014
Figure 11. Examples of Bullhead alluvium. (A) Well-rounded, lithologically diverse river gravel lag on the Black Mountain piedmont at 400 m above sea level (asl), northern Mohave Valley. Clasts in the foreground range from pebbles to small cobbles. (B) Coarse rounded gravel on an approximately
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Lateral and vertical extent of the Bullhead alluvium. Map of Mohave and Cottonwood Valleys showing extent of mapped Bullhead alluvium in pink; mapped Bouse deposits are in red. Dashed purple lines encompass the highest Bullhead outcrops in various parts of these valleys. Minimum and maximum elevations of the outcrops are noted with purple numbers.

Lateral and vertical extent of the Bullhead alluvium. Map of Mohave and Cot... Open Access

Published: 01 December 2014
Figure 12. Lateral and vertical extent of the Bullhead alluvium. Map of Mohave and Cottonwood Valleys showing extent of mapped Bullhead alluvium in pink; mapped Bouse deposits are in red. Dashed purple lines encompass the highest Bullhead outcrops in various parts of these valleys. Minimum
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Longitudinal profile focused on the lower Colorado River corridor showing the locations of Chemehuevi Formation, Bullhead Alluvium, and Quaternary travertine deposits from geologic mapping and subsurface data sets. When the mapped outcrops being depicted were queried due to uncertainty about the deposit’s identity or if composite map units were used because of interbedding or partial concealment by another unit, a unique color is used to distinguish those outcrops. Also shown is the tread of the Bullhead Alluvium, which is deformed across faults in the Lake Mead area. Downstream from Lake Mead, the strath of the Bullhead Alluvium projects toward Pliocene sea-level estimates. In the same area, the treads of the Chemehuevi Formation and the Bullhead Alluvium have nearly identical slopes. PD, DD, and HD indicate Parker, Davis, and Hoover dams, respectively. BB—Boulder Basin. See the text for mapping, subsurface, and geochronology references. max.—maximum; min.—minimum.

Longitudinal profile focused on the lower Colorado River corridor showing t... Open Access

Published: 16 October 2019
Figure 4. Longitudinal profile focused on the lower Colorado River corridor showing the locations of Chemehuevi Formation, Bullhead Alluvium, and Quaternary travertine deposits from geologic mapping and subsurface data sets. When the mapped outcrops being depicted were queried due to uncertainty
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Detrital zircon U-Pb results from Lake Mohave and Cottonwood Valley. Sample locations are shown in Figure 5B and listed in Table 3. (A–I) Relative probability plots. (A) Bullhead alluvium sample 30 (06322–37). (B) Bullhead alluvium sample 29 (06322–6). (C) Bullhead alluvium sample 26 (32103–1). (D) Bullhead alluvium sample 27 (320013–13). (E) Bouse Formation sample 28 (32003–7). (F) Bouse Formation sample 25 (32506–1). (G) Sub-Bouse fluvial sediments sample 23 (32706–3). (H) Late Miocene Lost Cabin Beds sample 24 (32306–175). (I) Cumulative probability plots of above samples; also includes Holocene Colorado River (HCR) reference. Samples 26, 28, 29, and 30 are included in PCR reference.

Detrital zircon U-Pb results from Lake Mohave and Cottonwood Valley. Sample... Open Access

Published: 01 December 2015
Figure 10. Detrital zircon U-Pb results from Lake Mohave and Cottonwood Valley. Sample locations are shown in Figure 5B and listed in Table 3 . (A–I) Relative probability plots. (A) Bullhead alluvium sample 30 (06322–37). (B) Bullhead alluvium sample 29 (06322–6). (C) Bullhead alluvium sample
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Conceptual stratigraphic architecture of the Bouse Formation (modified from Buising, 1990) in relation to the Bullhead Alluvium. Locally derived gravels (not shown) form interbeds in the Bouse and Bullhead units. Elevation difference between the lowest and highest exposures of the Bullhead Alluvium typically exceeds 200 m. Relations between the Bullhead and uppermost Bouse Formations and between the Bouse Formation interbedded unit and basin-margin carbonates are subjects of ongoing research. C.R.—Colorado River.

Conceptual stratigraphic architecture of the Bouse Formation (modified from... Open Access

Published: 01 February 2015
Figure 5. Conceptual stratigraphic architecture of the Bouse Formation (modified from Buising, 1990 ) in relation to the Bullhead Alluvium. Locally derived gravels (not shown) form interbeds in the Bouse and Bullhead units. Elevation difference between the lowest and highest exposures
Journal Article

Timing and geometry of the Chemehuevi Formation reveal a late Pleistocene sediment pulse into the Lower Colorado River Open Access

Harrison J. Gray, P. Kyle House, Adam M. Hudson, Jorge A. Vazquez, Ryan Crow, Miriam Primus, Shannon Mahan, Tammy Rittenour, Keith A. Howard
Journal: GSA Bulletin
Published: 28 October 2024
GSA Bulletin (2025) 137 (3-4): 1582–1606.
DOI: https://doi.org/10.1130/B37579.1
... system to a significant perturbation, in contrast to the Bullhead Alluvium, which is likely a unique result of Pliocene river integration. The aggradation of the Chemehuevi Formation in the Lower Colorado River corridor may be similarly due to a unique event in the Colorado River system, or it may...
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Journal Article

Redefining the age of the lower Colorado River, southwestern United States Available to Purchase

R.S. Crow, J. Schwing, K.E. Karlstrom, M. Heizler, P.A. Pearthree, P.K. House, S. Dulin, S.U. Jänecke, M. Stelten, L.J. Crossey
Journal: Geology
Published: 22 February 2021
Geology (2021) 49 (6): 635–640.
DOI: https://doi.org/10.1130/G48080.1
... of hundreds of meters of Bullhead Alluvium downstream of Grand Canyon after 4.6 Ma as the river adjusted to its lower base level. We present dating results from >1300 single grains from eight samples. The youngest population of dates from a DS sample as defined by the mean square of weighted deviates...
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Journal Article

Insights into post-Miocene uplift of the western margin of the Colorado Plateau from the stratigraphic record of the lower Colorado River Open Access

Ryan S. Crow, Keith A. Howard, L. Sue Beard, Philip A. Pearthree, P. Kyle House, Karl E. Karlstrom, Lisa Peters, William McIntosh, Colleen Cassidy, Tracey J. Felger, Debra Block
Journal: Geosphere
Published: 16 October 2019
Geosphere (2019) 15 (6): 1826–1845.
DOI: https://doi.org/10.1130/GES02020.1
...Figure 4. Longitudinal profile focused on the lower Colorado River corridor showing the locations of Chemehuevi Formation, Bullhead Alluvium, and Quaternary travertine deposits from geologic mapping and subsurface data sets. When the mapped outcrops being depicted were queried due to uncertainty...
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Includes: Supplemental Content
Book Chapter

A river is born: Highlights of the geologic evolution of the Colorado River extensional corridor and its river: A field guide honoring the life and legacy of Warren Hamilton Available to Purchase

Author(s)
Keith A. Howard*, P. Kyle House*, Barbara E. John*, Ryan S. Crow*, Philip A. Pearthree*
Book: Geologic Excursions in Southwestern North America
Series: GSA Field Guides
Publisher: Geological Society of America
Published: 04 September 2019
DOI: 10.1130/2019.0055(03)
EISBN: 9780813756554
... of its upstream lake breached the divide and led the river southward. The Bouse Formation in this and other basins records the pre–river integration water bodies. Younger riverlaid deposits including the Bullhead Alluvium (Pliocene) and the Chemehuevi Formation (Pleistocene) record subsequent evolution...
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ABSTRACT The Colorado River extensional corridor, which stretched by a factor of 2 in the Miocene, left a series of lowland basins and intervening bedrock ranges that, at the dawn of the Pliocene, were flooded by Colorado River water newly diverted from the Colorado Plateau through Grand Canyon. This water and subsequent sediment gave birth, through a series of overflowing lakes, to an integrated Colorado River flowing to the newly opened Gulf of California. Topock Gorge, which the river now follows between the Chemehuevi and Mohave Mountains, is a major focus of this field guide, as it very nicely exposes structural, stratigraphic, and magmatic aspects of the Miocene extensional corridor, a core complex, and detachment faults as well as a pre-Cenozoic batholith. Topock Gorge also is the inferred site of a paleodivide between early Pliocene basins of newly arrived Colorado River water. Overspilling of its upstream lake breached the divide and led the river southward. The Bouse Formation in this and other basins records the pre–river integration water bodies. Younger riverlaid deposits including the Bullhead Alluvium (Pliocene) and the Chemehuevi Formation (Pleistocene) record subsequent evolution of the Colorado River through a succession of aggradational and re-incision stages. Their stratigraphic record provides evidence of local basin deepening after river inception, but little deformation on a regional scale of the river valley in the last 4 m.y. except in the Lake Mead area. There, faults interrupt both the paleoriver grade and incision rates, and are interpreted to record 100’s of m of true uplift of the Colorado Plateau. Warren Hamilton’s insightful work beginning in the 1950s helped set the stage for interpretation of Mesozoic orogeny and Cenozoic extension in this region, as well as the record of the Bouse Formation.

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Schematic figure showing the generalized inset relationships between the paleo–Colorado River deposits (House, 2016) in the lower Colorado River corridor. This paper focuses on the ca. 4 Ma Bullhead Alluvium and the ca. 70 ka Chemehuevi Formation. See the text for details about the geochronologic constraints on the units. The Hualapai Limestone is not shown as it does not crop out in the same areas as the Bouse Formation. However, geochronologic constraints suggest that the Hualapai Limestone predated the Bouse Formation; in this diagram it would share a position with the axial-basin deposits. The main units focused on in the paper, the Bullhead Alluvium and Chemehuevi Formation, are colored according to their geologic map color here and in the other figures.

Schematic figure showing the generalized inset relationships between the pa... Open Access

Published: 16 October 2019
Figure 3. Schematic figure showing the generalized inset relationships between the paleo–Colorado River deposits ( House, 2016 ) in the lower Colorado River corridor. This paper focuses on the ca. 4 Ma Bullhead Alluvium and the ca. 70 ka Chemehuevi Formation. See the text for details about
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Topographic profile across Lake Mead (see Fig. 2 for location) showing the locations of Chemehuevi Formation, Bullhead Alluvium, and Hualapai Limestone deposits from geologic mapping. Deformed Hualapai Limestone deposits across the Lost Basin Range–Wheeler faults can be used to estimate fault throw and regional vertical offset.

Topographic profile across Lake Mead (see Fig. 2 for location) showing th... Open Access

Published: 16 October 2019
Figure 6. Topographic profile across Lake Mead (see Fig. 2 for location) showing the locations of Chemehuevi Formation, Bullhead Alluvium, and Hualapai Limestone deposits from geologic mapping. Deformed Hualapai Limestone deposits across the Lost Basin Range–Wheeler faults can be used
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Schematic stratigraphy of the Bouse Formation in the southern Blythe Basin, not to scale. Orange band at the top of unit Tfg1 represents a ravinement surface produced by sediment reworking and sorting during regional transgression. Bouse upper bioclastic member (unit Tbu) overlies older deposits of the Bouse Formation along a regional unconformity that represents an unknown amount of time, possibly ~100–200 k.y. Fossil symbol in Tbu represents branching calcareous red algae that are common in this unit, not found in the basal carbonate member. Abbreviations: carb—carbonate, C.R.—Colorado River, Bullhead—Bullhead Alluvium, mbr—member, mudst—mudstone, sst—sandstone, siltst—siltstone. See Figures 4 and 10 for further definition of lithologic unit symbols.

Schematic stratigraphy of the Bouse Formation in the southern Blythe Basin,... Open Access

Published: 14 May 2021
River, BullheadBullhead Alluvium, mbr—member, mudst—mudstone, sst—sandstone, siltst—siltstone. See Figures 4 and 10 for further definition of lithologic unit symbols.
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Bullhead gravel and sand from the Tyro Wash section in southern Cottonwood Valley. (A) The Tyro Wash section is dominated by thick tabular beds of cross-stratified rounded cobbles and boulders, and elaborately cross-bedded sand and finer gravel beds. The vertical section here is 45 m thick, and is part of a composite section that ranges from ∼200 to 420 m above sea level (asl) in Cottonwood Valley. (B) Moderate close-up of the western end of the section shows complexly interbedded sands and rounded gravel beds typical of the Bullhead alluvium. (C) Tan quartz-rich river sand beds (white arrows) interfingered with darker tributary fan gravel beds farther upsection and away from the valley axis.

Bullhead gravel and sand from the Tyro Wash section in southern Cottonwood ... Open Access

Published: 01 December 2014
thick, and is part of a composite section that ranges from ∼200 to 420 m above sea level (asl) in Cottonwood Valley. (B) Moderate close-up of the western end of the section shows complexly interbedded sands and rounded gravel beds typical of the Bullhead alluvium. (C) Tan quartz-rich river sand beds
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Map of southern Cottonwood, Mohave, and northern Chemehuevi Valleys showing the general distribution of outcrops of the Bouse Formation (red) and Bullhead alluvium (pink). Outcrops are slightly generalized, and many isolated Bouse outcrops are too small to depict at this scale. Estimated extents of paleolakes are depicted with shades of blue, and rough extents of paleodivides are shown. Key locations discussed in the text are identified by number. The approximate area of the Needles deformation zone is outlined with a dashed box.

Map of southern Cottonwood, Mohave, and northern Chemehuevi Valleys showing... Open Access

Published: 01 December 2014
Figure 2. Map of southern Cottonwood, Mohave, and northern Chemehuevi Valleys showing the general distribution of outcrops of the Bouse Formation (red) and Bullhead alluvium (pink). Outcrops are slightly generalized, and many isolated Bouse outcrops are too small to depict at this scale
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Geologic cross section across the Lost Trigo fault in Hart Mine Wash; location in Figures 4 and 7A. See Figure 4 for lithologic unit descriptions. Thin red line shows the ground surface. Here the fault is a NE-dipping oblique dextral-normal fault with an anomalously thick section of Bouse Formation siliciclastic member (unit Tbs) in its hanging wall. Consistent 15°–20° bedding dip toward the fault over a distance of at least 350 m combined with known stratigraphic relations in the map area indicate at least ~100 m dip-slip component of offset on the fault in this area. Surface data that constrain dipping unit Tbs and an angular unconformity at the base of Bullhead Alluvium (Tcb) are projected into the cross section from exposures along and near the line of section (Fig. 4).

Geologic cross section across the Lost Trigo fault in Hart Mine Wash; locat... Open Access

Published: 14 May 2021
that constrain dipping unit Tbs and an angular unconformity at the base of Bullhead Alluvium (Tcb) are projected into the cross section from exposures along and near the line of section ( Fig. 4 ).
Journal Article

Paleogeomorphology and evolution of the early Colorado River inferred from relationships in Mohave and Cottonwood valleys, Arizona, California, and Nevada Open Access

Philip A. Pearthree, P. Kyle House
Journal: Geosphere
Published: 01 December 2014
Geosphere (2014) 10 (6): 1139–1160.
DOI: https://doi.org/10.1130/GES00988.1
...Figure 11. Examples of Bullhead alluvium. (A) Well-rounded, lithologically diverse river gravel lag on the Black Mountain piedmont at 400 m above sea level (asl), northern Mohave Valley. Clasts in the foreground range from pebbles to small cobbles. (B) Coarse rounded gravel on an approximately...
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