1-20 OF 146 RESULTS FOR

lithophysae

Results shown limited to content with bounding coordinates.
Save search
Follow your search
Access your saved searches in your account
Would you like to receive an alert when new items match your search?
Close Modal
Sort by
Image
Lithophysae in the silicic rocks of the study area. (a) Small lithophysae exposed in plan in the Khalsa Kanthariya Ridge (KKR) dacite. Pen cap is 3 cm long. (b) Cluster of many small intergrown lithophysae in the rhyolite of Moti Kherali Ridge (MKR) at Barbtana. Coin at photo centre is 2.5 cm wide. (c) Local bonanza of lithophysae in the Ghanshyamnagar Ridge (GNR) at Ghanshyamnagar. Vertical section view, hammer 33 cm long. (d) A cluster of lithophysae in the rhyolite of Khakhbai Hill. Plan view, hand-held GPS for scale. (e) Vertical section through the fresh Kagvadar pitchstone containing many lithophysae. Hammer is 28 cm long. (f) Close-up of a single lithophysa in the Kagvadar pitchstone shown in (e), with a 2.7 cm coin for scale. (g) Lithophysae jackpot about halfway between Bhaguda and Longdi. Some 15 lithophysae (indicated by white and black arrows) are seen within weathered pale green tuff. Oblique plan view; 14 cm long pen (encircled) is vertical. (h) Close-up of a lithophysa at the location in g, showing apparent budding (white arrow). Coin is 2.7 cm wide. (i) Plan view of a collection of lithophysae made within minutes at the location in (g, h). See Misra (1999), Kshirsagar et al. (2012) and Sheikh et al. (2020a) for additional photographs.

Lithophysae in the silicic rocks of the study area. (a) Small lithophysae e... Available to Purchase

Published: 31 July 2023
Figure 9. Lithophysae in the silicic rocks of the study area. (a) Small lithophysae exposed in plan in the Khalsa Kanthariya Ridge (KKR) dacite. Pen cap is 3 cm long. (b) Cluster of many small intergrown lithophysae in the rhyolite of Moti Kherali Ridge (MKR) at Barbtana. Coin at photo centre
Image
Photos of the lithophysae after cutting and polishing. (a) This is a backscattered electron image of a whole fayalite crystal showing contrast variations corresponding to various degrees of oxidation. The image was taken after the removal of the FIB slice (bright mark, upper left). (b) This is a reflected light image of a small part of the crystal. The red line indicates the location of the FIB slice. It covers part of the fayalite zone (dark gray matrix), a laihunite zone (middle gray zoning), and an “oxyfayalite” zone (“oxyfa”; light gray core). Image (c) shows large euhedral osumilite crystals (light gray) that grew on small crystals of tridymite (BSE). Black areas were formerly filled with gas. The rhyolite devitrified matrix is also visible at the bottom of the picture. (d) This is a BSE image of a phlogopite crystal that has been oxidized to hematite (light-gray elongated crystals). (Color online.)

Photos of the lithophysae after cutting and polishing. ( a ) This is a back... Available to Purchase

Published: 01 May 2015
Figure 2 Photos of the lithophysae after cutting and polishing. ( a ) This is a backscattered electron image of a whole fayalite crystal showing contrast variations corresponding to various degrees of oxidation. The image was taken after the removal of the FIB slice (bright mark, upper left). ( b
Image
Figure 1. Photographs of joints in the upper lithophysae-bearing unit of the Tiva Canyon Tuff. (A) Smooth cooling joint with tubular structures defines one face of loose block (right side of photo), and later joint (at ∼90°) with rougher surface morphology cuts lithophysae (left side of photo). (B) Tubular structures on cooling joint surface shown in A. (C) Cooling joint swarm on pavement P100 (view toward the southwest). (D) Intersection of two cooling joints on pavement P100. (E) Oblique view of hand sample showing smooth cooling joint with tubular structures that are bowed adjacent to ∼5-cm-diameter lithophysa. (F) View parallel to main cooling joint surface in E shows deflection or bowing (arrows) of joint surface from overall planar geometry (dashed line). Total deflection is ∼2 mm. Note in E and F that deflection of the cooling joint surface locally occurs as discrete steps across tubular structures. (G1) Detail of smooth cooling joint with tubular structures. Inset shows small-aperture fractures and large-aperture tubes cutting one face of a cooling joint. Tubes and fracture tips have bleached walls. The expanded image shows fractures with apertures ranging from <1 mm at fracture tips to nearly 1 cm along major tubes. Regardless of aperture, fracture walls show bleaching indicative of vapor-phase mineralization and alteration of adjacent rock. Unbleached areas away from tube-bearing joints are part of the vertical joint surface that would have been forced tightly closed by lateral stress caused by gas expansion and formation of lithophysae. (G2) Restoration of tubes shown in G1 by matching sides to show volume increase using block translation without rotation. (G3) Restoration of tubes shown in G1 by matching sides to show volume increase using block translation with minor rotation (counterclockwise indicated by −2°) of some blocks.

Figure 1. Photographs of joints in the upper lithophysae-bearing unit of th... Available to Purchase

Published: 01 December 2003
Figure 1. Photographs of joints in the upper lithophysae-bearing unit of the Tiva Canyon Tuff. (A) Smooth cooling joint with tubular structures defines one face of loose block (right side of photo), and later joint (at ∼90°) with rougher surface morphology cuts lithophysae (left side of photo). (B
Image
(a) Schematic view of the formation and oxidation of fayalite in the lithophysae during Obsidian Cliffs’ rhyolite flow cooling with corresponding estimations of temperature. (1) Rhyolite emplacement. (2) Exsolution and crystallization in the core of the lava flow. (3) Crystallization of fayalite, tridymite, and osumilite in the lithophysae. (4) Fayalite oxidation. The height of the lithophysae-rich zone and the size of the lithophysae were exaggerated for clarity’s sake. (b) Schematic cartoon representing the oxidation process with time along a fluid-filled fracture inside a fayalite crystal or at a fayalite crystal edge. (Color online.)

( a ) Schematic view of the formation and oxidation of fayalite in the lith... Available to Purchase

Published: 01 May 2015
Figure 8 ( a ) Schematic view of the formation and oxidation of fayalite in the lithophysae during Obsidian Cliffs’ rhyolite flow cooling with corresponding estimations of temperature. (1) Rhyolite emplacement. (2) Exsolution and crystallization in the core of the lava flow. (3) Crystallization
Image
Figure 4. Sequence of formation of cooling joints with tubes. (A) Contractional joint surface propagates through rock prior to the formation of lithophysae, so no joints terminate or cut lithophysae. (B) Cooling joint causes formation of adjacent brittle zone. As the rock expands vertically with the formation of lithophysae, subhorizontal, tube-like fractures develop within the brittle zone. Also, large lithophysae deflect joints. (C) Continued degassing of the rock utilizes these tubes for gas flow (arrows show gas flow). (D) An expanded view of a cooling joint shows that the two sides are mirror images of each other.

Figure 4. Sequence of formation of cooling joints with tubes. (A) Contracti... Available to Purchase

Published: 01 December 2003
Figure 4. Sequence of formation of cooling joints with tubes. (A) Contractional joint surface propagates through rock prior to the formation of lithophysae, so no joints terminate or cut lithophysae. (B) Cooling joint causes formation of adjacent brittle zone. As the rock expands vertically
Image
(a) Flow banded perlitic pitchstone. (b) Perlitic pitchstone flow deposit with in-situ lithophysae. (c) A close-up view of the agate-filled lithophysae from the perlitic pitchstone. (d) Zeolitised tuff outcrop with the perlite developed above it.

( a ) Flow banded perlitic pitchstone. ( b ) Perlitic pitchstone flow deposi... Available to Purchase

Published: 01 June 2022
Figure 5. ( a ) Flow banded perlitic pitchstone. ( b ) Perlitic pitchstone flow deposit with in-situ lithophysae. ( c ) A close-up view of the agate-filled lithophysae from the perlitic pitchstone. ( d ) Zeolitised tuff outcrop with the perlite developed above it.
Image
Views of the core and thin sections of pyroclastic rocks in the Fengcheng Formation. (A) Lithophysa-rich welded breccia tuffs (well X-72, 4808.44–4808.85 m [15,775.72–15,777.07 ft]). (B) Volcanic breccia. These breccias are angular and red in color. Tuff fill in among these breccias (well X-201, 4922.21–4922.47 m [16,148.98–16,149.84 ft]). (C) Volcanic breccia–bearing tuffs (well X-201, 4924.75 m [16,157.32 ft]). (D) Core section of lithophysa-bearing welded tuffs (well FN-1, 4474.00 m [14,678.48 ft]). (E) Column sample of lithophysa-bearing welded tuffs. Secondary minerals of silica semifilled with lithophysa (well FN-1, 4474.00 m [14,678.48 ft]). (F) Photograph of crystal fragment–bearing vitroclastic welded tuff (well FN-1, 4474.00 m [14,678.48 ft], plane-polarized light). (G) Vitroclastic tuff. Vitroclasts existed with various occurrences (well X-88, 3829.16 m [12,562.86 ft], plane-polarized light).

Views of the core and thin sections of pyroclastic rocks in the Fengcheng F... Available to Purchase

Published: 15 September 2019
Figure 7. Views of the core and thin sections of pyroclastic rocks in the Fengcheng Formation. (A) Lithophysa-rich welded breccia tuffs (well X-72, 4808.44–4808.85 m [15,775.72–15,777.07 ft]). (B) Volcanic breccia. These breccias are angular and red in color. Tuff fill in among these breccias
Journal Article

Fayalite oxidation processes in Obsidian Cliffs rhyolite flow, Oregon Available to Purchase

Audrey M. Martin, Etienne Médard, Bertrand Devouard, Lindsay P. Keller, Kevin Righter, Jean-Luc Devidal, Zia Rahman
Published: 01 May 2015
American Mineralogist (2015) 100 (5-6): 1153–1164.
DOI: https://doi.org/10.2138/am-2015-5042
...Figure 2 Photos of the lithophysae after cutting and polishing. ( a ) This is a backscattered electron image of a whole fayalite crystal showing contrast variations corresponding to various degrees of oxidation. The image was taken after the removal of the FIB slice (bright mark, upper left). ( b...
FIGURES
First thumbnail for: Fayalite oxidation processes in Obsidian Cliffs rh...
Second thumbnail for: Fayalite oxidation processes in Obsidian Cliffs rh...
Third thumbnail for: Fayalite oxidation processes in Obsidian Cliffs rh...
View PDF for article title, Fayalite oxidation processes in Obsidian Cliffs rhyolite flow, Oregon
Purchase
Add to Citation Manager for Fayalite oxidation processes in Obsidian Cliffs rhyolite flow, Oregon
Journal Article

Major element and oxygen isotope geochemistry of vapour-phase garnet from the Topopah Spring Tuff at Yucca Mountain, Nevada, USA Available to Purchase

R. J. Moscati, C. A. Johnson
Published: 01 August 2014
Mineralogical Magazine (2014) 78 (4): 1029–1041.
DOI: https://doi.org/10.1180/minmag.2014.078.4.14
... that is zoned compositionally from high-silica rhyolite to latite. During cooling of the tuff, escaping vapour produced lithophysae (former gas cavities) lined with an assemblage of tridymite (commonly inverted to cristobalite or quartz), sanidine and locally, hematite and/or garnet. Vapour-phase topaz...
FIGURES
First thumbnail for: Major element and oxygen isotope geochemistry of v...
Second thumbnail for: Major element and oxygen isotope geochemistry of v...
Third thumbnail for: Major element and oxygen isotope geochemistry of v...
View PDF for article title, Major element and oxygen isotope geochemistry of vapour-phase garnet from the Topopah Spring Tuff at Yucca Mountain, Nevada, USA
Purchase
Add to Citation Manager for Major element and oxygen isotope geochemistry of vapour-phase garnet from the Topopah Spring Tuff at Yucca Mountain, Nevada, USA
Journal Article

Orthogonal jointing during coeval igneous degassing and normal faulting, Yucca Mountain, Nevada Available to Purchase

William M. Dunne, David A. Ferrill, Juliet G. Crider, Brittain E. Hill, Deborah J. Waiting, Peter C. La Femina, Alan P. Morris, Randall W. Fedors
Journal: GSA Bulletin
Published: 01 December 2003
GSA Bulletin (2003) 115 (12): 1492–1509.
DOI: https://doi.org/10.1130/B25231.1
...Figure 1. Photographs of joints in the upper lithophysae-bearing unit of the Tiva Canyon Tuff. (A) Smooth cooling joint with tubular structures defines one face of loose block (right side of photo), and later joint (at ∼90°) with rougher surface morphology cuts lithophysae (left side of photo). (B...
FIGURES
First thumbnail for: Orthogonal jointing during coeval igneous degassin...
Second thumbnail for: Orthogonal jointing during coeval igneous degassin...
Third thumbnail for: Orthogonal jointing during coeval igneous degassin...
View PDF for article title, Orthogonal jointing during coeval igneous degassing and normal faulting, Yucca Mountain, Nevada
Purchase
Add to Citation Manager for Orthogonal jointing during coeval igneous degassing and normal faulting, Yucca Mountain, Nevada
Book Chapter

Origin of pumiceous and glassy textures in rhyolite flows and domes Available to Purchase

Author(s)
Jonathan H. Fink, Curtis R. Manley
Book: The Emplacement of Silicic Domes and Lava Flows
Series: GSA Special Papers
Publisher: Geological Society of America
Published: 01 January 1987
DOI: 10.1130/SPE212-p77
... revealed in the drill core and in the fronts of several other Holocene-age silicic flows consists of a finely vesicular pumice carapace underlain successively by obsidian, coarsely vesicular pumice, obsidian with lithophysae, crystalline rhyolite, more obsidian with lithophysae, and basal breccia...
Abstract
View PDF for content titled, Origin of pumiceous and glassy textures in rhyolite flows and domes
Purchase
Add to Citation Manager for Origin of pumiceous and glassy textures in rhyolite flows and domes

Surface mapping and microscopic observation of textures in glassy and pumiceous rocks from several groups of silicic lava flows and domes, along with drill cores of the Inyo Scientific Drilling Project, indicate that development of the textural stratigraphy of the flows is controlled by a combination of cooling, microfracturing, and migration of gases released by crystallization. The Inyo cores have provided near-vent and distal views of the interior of the 550-yr-old Obsidian Dome rhyolite flow, as well as a profile through the unerupted portion of its feeder dike. The flow stratigraphy revealed in the drill core and in the fronts of several other Holocene-age silicic flows consists of a finely vesicular pumice carapace underlain successively by obsidian, coarsely vesicular pumice, obsidian with lithophysae, crystalline rhyolite, more obsidian with lithophysae, and basal breccia. The obsidian layers form where rapid cooling inhibits diffusion of ions and prevents crystallization. The transition from surface pumice to obsidian is controlled by the depth at which overburden pressure suppresses vesiculation. The thickness of the rigid crust is determined by the rapid decrease in the lava’s temperature-dependent yield strength with depth. The coarsely vesicular pumice layer forms as gases released by crystallization rise through microcracks and are trapped beneath the rigid pumiceous surface layer. Thickness and buoyancy of the coarsely vesicular pumice layer increase with flow length, eventually giving rise to diapirs that rise to the surface of the largest flows. Increasing gas content of the coarsely vesicular pumice layer in active flows can also lead to such volcanic hazards as explosive craters on distal flow surfaces or pyroclastic flows triggered by collapse of flow fronts.

Journal Article

Pumice and perlite in a rhyolite complex in Hungary Available to Purchase

Ervin G. Oetvoes
Journal: Economic Geology
Published: 01 September 1961
Economic Geology (1961) 56 (6): 1112–1122.
DOI: https://doi.org/10.2113/gsecongeo.56.6.1112
...Ervin G. Oetvoes Abstract The rhyolite complex capping the Kishegy volcanic massif was formed during the Miocene volcanism of the Matra mountain region. It contains pumice (at least 27 meters in thickness) and bands of perlite in the basal portion, overlain by spherulitic, lithophysae, and felsitic...
View PDF for article title, Pumice and perlite in a rhyolite complex in Hungary
Purchase
Add to Citation Manager for Pumice and perlite in a rhyolite complex in Hungary
Journal Article

Cordilleran Section meeting at California Institute of Technology in April Available to Purchase

Journal: GSA Bulletin
Published: 01 December 1942
GSA Bulletin (1942) 53 (12_2): 1815–1825.
DOI: https://doi.org/10.1130/GSAB-53-1815
..., red; as dikes. Perlitic obsidian, largely black but red in part, lithophysae abundant at many places; as small lenses. Porphyritic andesite, gray or red and gray in fine bands; commonly has platy parting between bands, which are contorted at places. Porphyritic andesite, dark-gray to reddish, massive...
View PDF for article title, Cordilleran Section meeting at California Institute of Technology in April
Purchase
Add to Citation Manager for Cordilleran Section meeting at California Institute of Technology in April
Image
Photos of Obsidian Cliffs rhyolite lava flow. (a) General view of the northern cliff and its debris talus, taken from an andesite lava flow of the Collier Cone (foreground). (b) Picture of a glassy obsidian rock observed at the summit of Obsidian Cliffs lava flow, containing white spherulites and deformed pink microlite flow banding (lens cap diameter is 62 mm). (c) Photo of a lithophysae-rich sample. (d and e) Close-up images of oxidized fayalite crystals oriented in two different directions (photos by B. Lechner and S. Wolfsried, respectively) showing external hematite layers (red). Black crystals in lithophysae are osumilite, flat brown-red crystals are oxidized phlogopite and white crystals are tridymite. (Color online.)

Photos of Obsidian Cliffs rhyolite lava flow. ( a ) General view of the nor... Available to Purchase

Published: 01 May 2015
spherulites and deformed pink microlite flow banding (lens cap diameter is 62 mm). ( c ) Photo of a lithophysae-rich sample. ( d and e ) Close-up images of oxidized fayalite crystals oriented in two different directions (photos by B. Lechner and S. Wolfsried, respectively) showing external hematite layers
Journal Article

The physical volcanology of large-scale effusive and explosive silicic eruptions in southeastern Saurashtra, Deccan Traps Available to Purchase

Anmol Naik, Hetu Sheth, Alok Kumar, Janisar M. Sheikh
Published: 31 July 2023
Geological Magazine (2023) 160 (7): 1395–1416.
DOI: https://doi.org/10.1017/S0016756823000432
...Figure 9. Lithophysae in the silicic rocks of the study area. (a) Small lithophysae exposed in plan in the Khalsa Kanthariya Ridge (KKR) dacite. Pen cap is 3 cm long. (b) Cluster of many small intergrown lithophysae in the rhyolite of Moti Kherali Ridge (MKR) at Barbtana. Coin at photo centre...
FIGURES
First thumbnail for: The physical volcanology of large-scale effusive a...
Second thumbnail for: The physical volcanology of large-scale effusive a...
Third thumbnail for: The physical volcanology of large-scale effusive a...
View PDF for article title, The physical volcanology of large-scale effusive and explosive silicic eruptions in southeastern Saurashtra, Deccan Traps
Purchase
Add to Citation Manager for The physical volcanology of large-scale effusive and explosive silicic eruptions in southeastern Saurashtra, Deccan Traps
Image
Lithophysa with a large agate filling from the Baker egg mine, Deming, New Mexico. ∼8 cm long. Photo by Don Roach.

Lithophysa with a large agate filling from the Baker egg mine, Deming, New ... Available to Purchase

Published: 30 November 2019
Fig. 16. Lithophysa with a large agate filling from the Baker egg mine, Deming, New Mexico. ∼8 cm long. Photo by Don Roach.
Journal Article

The genesis of agates and amethyst geodes Available to Purchase

Ingrid N. Kigai
Published: 30 November 2019
The Canadian Mineralogist (2019) 57 (6): 867–883.
DOI: https://doi.org/10.3749/canmin.1900028
...Fig. 16. Lithophysa with a large agate filling from the Baker egg mine, Deming, New Mexico. ∼8 cm long. Photo by Don Roach. ...
FIGURES
First thumbnail for: The genesis of agates and amethyst geodes
Second thumbnail for: The genesis of agates and amethyst geodes
Third thumbnail for: The genesis of agates and amethyst geodes
View PDF for article title, The genesis of agates and amethyst geodes
Purchase
Add to Citation Manager for The genesis of agates and amethyst geodes
Image
Original mean hazard curve for the site and adjustment of hazard curve to correspond to a 5% survival probability of the lithophysae. The color version of this figure is available only in the electronic edition.

Original mean hazard curve for the site and adjustment of hazard curve to c... Available to Purchase

Published: 01 June 2013
Figure 4. Original mean hazard curve for the site and adjustment of hazard curve to correspond to a 5% survival probability of the lithophysae. The color version of this figure is available only in the electronic edition.
Image
Lithophysa with a shadow flow layering and some arching above the agate core. 10 cm wide sample from Tarbal'dzhey area, Transbaikalia, Russia. Collection of Fersman Mineralogical Museum, Moscow, photo by A. Evseev.

Lithophysa with a shadow flow layering and some arching above the agate cor... Available to Purchase

Published: 30 November 2019
Fig. 15. Lithophysa with a shadow flow layering and some arching above the agate core. 10 cm wide sample from Tarbal'dzhey area, Transbaikalia, Russia. Collection of Fersman Mineralogical Museum, Moscow, photo by A. Evseev.
Image
Lithophysa (blown up by fluid) with onyx banding and nearly perpendicular flow layering of rhyolite—evidence of formation of onyx banding prior to lava eruption. Khapcheranga district, Transbaikal region, Russia. 16 cm long.

Lithophysa (blown up by fluid) with onyx banding and nearly perpendicular f... Available to Purchase

Published: 30 November 2019
Fig. 17. Lithophysa (blown up by fluid) with onyx banding and nearly perpendicular flow layering of rhyolite—evidence of formation of onyx banding prior to lava eruption. Khapcheranga district, Transbaikal region, Russia. 16 cm long.