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| "now a quiet, remote monument to that violent geological time." (Smith 2025) |
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| Desert Mountain's peaks and ridges lower right quarter of photo; white mark is high point (Google Earth). |
Desert Mountain is small mountain—an isolated cluster of low peaks, ridges and knobs in Utah's West Desert. The first geologist to write about it thought "Desert Hills" more appropriate (Loughlin 1920). But its story is huge—complicated and filled with drama. And being geological, it's long.
My visit to Desert Mountain was about 80 miles round trip from Delta. I took UT Hwy 6 north to the Jericho Callao Road, then drove west. Pavement soon gave way to gravel, a bit rough in places but generally good. The road crossed open juniper woodlands and sparse dry grasslands, with expansive playas to the south. After 22.5 miles, with Desert Mountain visible nearby, I stayed left at a junction and was soon at its base.
We could start 300 million years ago, when collisions on both sides of a young North America were deforming it far inland, for example in today's western Utah. Or we could start 300 million years before that, when western Utah was covered in shallow water of the great Paleozoic Sea. Or we could go back yet another 300 million years to the creation of that sea, when the supercontinent Rodinia was coming apart. But we won't. Instead we'll start three months ago, on a hot spring day.
Shortly before I left home, the spring issue of Survey Notes showed up in my mailbox. Inside was a GeoSight—a new one, and in the general area of my travels. Of course I would go there! Of the many resources offered by the Utah Geological Survey (UGS), my favorite is GeoSights. I visited my first, the Honeycombs, in 2012. Awed by the rocks and their story, I've been geotripping to GeoSights ever since.
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| Sunset on the Honeycombs, 2012. |
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| Approaching Desert Mountain from the north. Kelly Hewitt photo via Google Earth. |
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| Rocks abound, trees not so much; pale band close to road is a fence, covered in tumbleweeds. |
Desert Mountain was born c. 30 to 40 million years ago, during the Great Ignimbrite Flareup which ravaged much of Nevada and western Utah. For 15 million years large volcanoes, supervolcanoes and complexes of supervolcanoes (1) produced on the order of 5.5 million km3 of volcanic material—great clouds of ash that blocked the sun, huge volumes of rock fragments hurled hundreds of miles, and searing pyroclastic flows that destroyed everything in their path. For comparison, the 1980 Mount St. Helens eruption produced only one km3 of material (source).
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| Geologic map shows rock units discussed here. Blue B's mark shoreline of glacial Lake Bonneville, black lines are faults, labeled arrows are mine (Smith 2025). |
But while the lava oozed ever so slowly, trouble was brewing below. Gas was accumulating in the viscous magma, increasing in pressure until it literally exploded. Massive amounts of rock fragments and ash were sent flying. These pyroclastic deposits are said to be common east of the mountain, a project for a cooler day.
The eruption largely emptied the magma chamber, causing the roof of the volcano to collapse. The result was a caldera—a very large bowl-shaped depression. When the roof collapsed it broke up into a mishmash of preexisting rocks and erupted material, forming today's volcanic breccia. I may have seen it at Desert Mountain Pass, adjacent to the beautiful pale granite outcrops.
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| A close look at the volcanic breccia of Desert Mountain (UGS). |
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| Desert Mountain Pass. Is that volcanic breccia behind the granite? I thought so at the time. |
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| Utah Juniper on pale granite; dark granodiorite in distance. |
That may have been the final eruption but obviously there's more to the story, for the granite no longer is fully buried. Exhumation started about 17 million years ago, when the part of North America between the Wasatch Mountains and the Sierra Nevada (today's Basin and Range Province) began to stretch east to west. This extension deformed and fragmented older landscapes, including Desert Mountain. The caldera was uplifted, tilted and fractured, allowing erosion to slowly expose and sculpt the lovely granite.
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| Desert Mountain granite. Sonny Wilson photo, via Google Earth (cropped). |
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| Granite on the west side of Desert Mountain. gjagiels photo, via Summit Post. |
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| Spectacular outcrop at south end of Desert Mountain. Hmmm ... what are those black and white bands? |
Sometime after the granite was intruded—perhaps while the magma was cooling or later during extension (or both)—molten material filled fractures forming dikes. Whitish aplite dikes formed first, followed by dark andesitic dikes (3). How do we know the order? By their cross-cutting relationships! These are fun to find and worthy of attention for the story they tell. At Desert Mountain, the white dikes cross the pale granite and are therefore younger. The dark dikes cross both the white dikes and the granite and are therefore the youngest of the three.
I considered camping at the base of this outcrop but it was much too hot for me. On the drive to Delta, I stopped and took one more photo of the beautiful pale granite. Then I continued south.
Notes
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| Wonderful display of cross-cutting relationships; white arrows mark less conspicuous aplite. |
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| See the dike? |
Notes
(1) Desert Mountain is part of the Thomas-Keg-Desert mountains caldera complex (DeCourten 2003). The Honeycombs, mentioned early in the post, may be related.
(2) The pale granite at Desert Mountain was called leucogranite early on (e.g., Kattelman 1968). Now "leucogranite" is increasingly used for a pale granite formed in collisional tectonic settings, for example in the Himalayas (E. H. Christiansen, personal communication). For more, see Miller's excellent Perspective (2024). He explains that though collisional is by far the most common tectonic setting for leucogranite formation, it can form in others, including extensional, if certain conditions are met (e.g., composition low in aluminum). In any case, "leucogranite" is used in Jackson's GeoSights article; Christiansen prefers "granite". [Suggestion to UGS: In GeoSights articles, cite a few sources for additional information.]
(3) The dark dikes also are controversial. According to Jackson, the rock "apparently" is very dark lamprophyre—a catch-all term for various peculiar ultramafic rocks not amenable to the usual classifications (source). Christiansen and colleagues prefer andesite.
Sources (in addition to links in post)
I'm grateful to Eric Christiansen, Professor Emeritus at Brigham Young University, for answering my questions about igneous rocks at Desert Mountain, and for his appreciation of cross-cutting relationships.
Brigham Young University. 2013. Supervolcano in Utah: massive ancient volcano discovered by BYU geologists. YouTube.
DeCourten, FL. 2003. The Broken Land; adventures in Great Basin geology. U. Utah Press.
Loughlin, G. F., 1920, Desert Mountain, in B. S. Butler, and others, Ore deposits of Utah: U. S. Geol. Survey Prof. Paper III, 444-445. PDF
Miller, CF. 2024. Granites, leucogranites, Himalayan leucogranites ... Elements 20(6):359–364. doi: https://doi.org/10.2138/gselements.20.6.359
Rees, DC, Erickson, MP, Whelan, JA. 1973. Geology and diatremes of Desert Mountain, Utah. Utah Geological & Mineralogical Survey Special Studies 42. PDF
Smith, J. 2025. Geosights: Desert Mountain, Juab County, Utah. Utah Geological Survey, Survey Notes.
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