Polvadera Group

The Jemez Mountains lie on the intersection of the western margin of the Rio Grande Rift and the Jemez Lineament.^[1][2] Here magma produced from the fertile rock of an ancient subduction zone^[3] has repeatedly found its way to the surface along faults produced by rifting. This has produced a long-lived volcanic field, with the earliest eruptions beginning at least 13 million years ago in both the northern (Polvadera Group) and southern (Keres Group) portions of the volcanic field.^[4] High-silica eruptions of the Tewa Group began about 1.85 million years ago and continued almost to the present day.^[5]

The Polvadera Group is a sequence of basalt, andesite, dacite, and rhyolite flows that underlie part of the central and most of the northern Jemez Mountains. It overlaps the Keres Group to the south and has a maximum thickness of about 1,100 meters (3,600 feet). It overlies the Abiquiu Formation and Santa Fe Group and is overlain by the Tewa Group.^[6]

From oldest to youngest, the formations recognized within the Polvadera Group are the Lobato Formation, the La Grulla Formation, the Tschicoma Formation, and the El Rechuelos Rhyolite.

The Lobato Formation is a sequence of mostly tholeiitic^[7] basalt flows that underlies the mesas fringing the northern and northeastern sides of the Jemez Mountains. Major flows include the basalts of Clara Peak, Lobato Mesa, Polvadera Mesa, Escoba Mesa, and Cerro Pedernal. The formation was named for Lobato Mesa (36°07′34″N 106°18′32″W / 36.126°N 106.309°W / 36.126; -106.309), where the formation is particularly thick and extensive, by H. T. U. Smith in 1938. The formation has a maximum thickness of 180 meters (590 feet) and is a succession of numerous flows ranging from 6 meters (20 feet) to 15 meters (49 feet) in thickness. The flows are mostly olivine-augite basalts, but hypersthene-, pigeonite-, and titaniferous augite-bearing basalts are also found.^[6] The formation was erupted between 14 and 7 million years ago, peaking between 10.8 million and 7.8 Mya.^[8][7]

The Lobato Formation is separated from the underlying Abiquiu Formation and Santa Fe Group by an erosional surface locally veneered by boulders and cobbles of Precambrian basement. The formation in turn is overlain by dacites and quartz latites of the Tschicoma Formation.^[6] The earliest flows mapped as Lobato Formation are interbedded with Santa Fe Group sediments and have been dated at 14.1 + 0.3 Mya.^[7]

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  Lobato Mesa
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  Thin lava and cinder beds of the Lobato Formation exposed in road cut southwest of Clara Peak.
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  Gabbro from the interior of the Clara Peak eruptive center of the Lobato Formation.
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  Window Rock Dike, in the badlands between Medanales and Lobato Mesa.

The La Grulla Formation consists of flows underlying the La Grulla Plateau (36°07′34″N 106°33′58″W / 36.126°N 106.566°W / 36.126; -106.566) that were originally assigned to the Lobato Formation or the Tschicoma Formation. However, these are distinct in age and geochemistry,^[9] and were assigned to the La Grulla Formation by Shari A. Kelley and coinvestigators in 2013. The formation includes low-silica (mafic) lavas erupted from Encino Point between 8.7 and 7.8 Mya and trachyandesite and dacite erupted on the La Grulla Plateau between 7.7 and 7.2 Mya. The contact of the La Grulla Formation with the underlying Paliza Canyon Formation (Keres Group) is described as a sedimentary break.^[10]

The Tschicoma Formation is a sequence of mostly dacite and rhyodacite flows, with lesser amounts of andesite, trachyandesite, and rhyolite,^[7] that overlies the Lobato Formation and is in turn overlain by Tewa Group flows. Its flows are exposed as the Sierra de los Valles west of the city of Los Alamos (35°53′46″N 106°25′01″W / 35.896°N 106.417°W / 35.896; -106.417). It was named by R.L. Griggs in 1964.^[11] This formation marked a reduction in tectonic activity in the region. Whereas previous eruptions were vented along active faults, the Tschicoma hybrid magmas formed from coalescence of pockets of mantle- and lower-crust-derived magmas.^[12] The eruptions took place between 6.8 and 2.7 Mya, with a peak between 5.0 and 2.7 Mya.^[8][13]

The flows were erupted from multiple dome complexes that can be readily distinguished by their geochemistry and petrographic characteristics. The Rhyodacite of Rendija Canyon contains 11-16% phenocrysts of quartz and plagioclase, lesser amounts of sanidine and anorthoclase, and traces (<0.5%) of biotite, clinopyroxene, and hornblende. It is a low-silica rhyolite with an age ranging from 4.98 to 5.36 Ma. The Dacite of Sawyer Dome contains 32-34% phenocrysts of plagioclase, hornblende, and orthopyroxene, and has an ⁴⁰Ar/³⁹ age between 3.18 and 3.67 Ma. The Dacite of Cerro Grande contains about 21% phenocrysts of plagioclase, hornblende, orthopyroxene, and subordinate clinopyroxene, with an age ranging from 2.88 to 3.35 Ma.

The Dacite of Pajarito Mountain is divided into two series of lavas. The lower is a two-pyroxene dacite with 10.3-16.4% phenocrysts of plagioclase and subequal orthopyroxene and clinopyroxene, while the upper flows are slightly more silicic, with 23-24% phenocrysts of plagioclase, orthopyroxene, and subordinate clinopyroxene. The age of the upper flows ranges from 2.93 and 3.09 Ma.

The Dacite of Caballo Mountain (New Mexico) is also divided into two sets of flows. The lower flows include to 24% phenocrysts of plagioclase and hornblende with lesser amounts of quartz and biotite and traces of sanidine, orthopyroxene, and clinopyroxene. The summit of Caballo Mountain is underlain by a relatively crystal-poor dacite containing about 2% phenocrysts of plagioclase and hornblende with lesser amounts of clinopyroxene and traces of quartz and orthopyroxene. The lower beds are about 4.66 Ma in age while the summit is 3.06 Ma in age.

After about 2.88 Ma, Tschicoma volcanism shifted from the Sierra de los Valles eastwards to the western Española basin. Here several small-volume dacite lavas erupted between 2.36 and 2.74 Ma that are now buried under the Bandelier Tuff of the Pajarito Plateau.^[13]

Tschicoma dacite contains andesitic inclusions consistent with injection of mafic magma into melted crust.^[14]

The Puye Formation of the Santa Fe Group consists largely of debris eroded off the Tschicoma Formation. It contains 25 pyroclastic flows, including pumiceous ignimbrites and block and ash flows, erupted by vents of the Tschicoma Formation. Erosion has denuded the Tschicoma Formation domes of these units.^[15]

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  Tschicoma Mountain, the highest point in the Jemez Mountains, is underlain by Tschicoma Formation.
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  Dacite boulder of Rendija Canyon Member of the Tschicoma Formation
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  Block and ash flow in the Tschicoma Formation exposed at Rendija Canyon

The El Rechuelos Rhyolite is named for El Rechuelos, a small steep drainage on the western side of Polvadera Peak (36°03′50″N 106°26′46″W / 36.064°N 106.446°W / 36.064; -106.446). It was originally defined as a set of five small rhyolite domes and a small pumice cone in the northern Jemez Mountains. These rest on dacites of the Tschicoma Formation and are overlain by Bandelier Tuff.^[16] Petrological and radiometric age measurements have shown that only two of the domes, plus a vent discovered later, properly belong to the El Rechuelos Rhyolite and have an age of 2 million years. The remaining rhyolite domes are much older and resemble units of the Keres Group to the south.^[17][8]

The ages and chemistries point to five distinct batches of magma for the El Rechuelos Rhyolite as originally defined. The Early Rhyolite has an ⁴⁰Ar/³⁹ age of 7.10 + 0.04 Ma and is characterized by phenocrysts of plagioclase, quartz, biotite, and sanidine; the Intermediate Rhyolite has an age of 7.05 + 0.24 Ma and is characterized by phenocrysts of plagioclase, sanidine, and biotite; the Pumice Ring Rhyolite has an age of 5.61 + 0.48 and is characterized by plagioclase, biotite, quartz, and amphibole phenocrysts in a finely crystalline groundmass; the El Rechuelos Rhyolite (sensu stricto) is 2.23 +0.15 Ma old and is sparsely porphyritic rhyolite glass; and the Young Rhyolite is 1.19 + 0.01 Ma old and has phenocrysts of sanidine, quartz, plagioclase, and sparse fayalite. All have a total rock composition characteristic of rhyolite. The Young Rhyolite appears to be part of the Bandelier Tuff.^[18]

The El Rechuelos Rhyolite has geochemistry consistent with an origin in a lower crustal magma chamber generated from a mantle‐derived mafic magma, probably the nearby Lobato Basalt, by fractional crystallization with limited assimilation (less than six percent) of lower crust. This system was likely distinct from the Bandelier Tuff magma system.^[17]

The group was first defined by Bailey, Smith, and Ross in 1969 as part of their work establishing the stratigraphy of the Jemez Mountains. The group was named for Polvadera Peak, which is a major eruptive center for the group and the second highest peak in the Jemez Mountains (36°03′36″N 106°24′18″W / 36.060°N 106.405°W / 36.060; -106.405). They included in the group the Lobato Basalt, the Tschicoma Formation, and the El Rechuelos Rhyolite.^[6] Bruce M. Loeffler and coinvestigators narrowed the definition of the El Rechuelos Rhyolite in 1988,^[17] and Shari A. Kelley and coinvestigators defined the La Grulla Formation in 2013.^[10]

The division of the precaldera formations of the Jemez Mountains into the Polvadera and Keres Groups, based largely on geography, has been criticized as artificial, and the Polvadera Group itself includes formations of disparate origins and ages.^[19][20] Fraser Goff and his coinvestigators abandoned the Polvadera Group in their 2011 mapping of the Valles Caldera, assigning its formations to the Keres Group,^[21] as did Shari A. Kelley and coinvestigators in their 2013 study.^[10]

Obsidian obtained from the Polvadera Group has been found in Paleoindian archaeological sites as far east as Oklahoma.^[22]

• Aldrich, M. J. Jr. (1986). "Tectonics of the Jemez Lineament in the Jemez Mountains and Rio Grande Rift". Journal of Geophysical Research. 91 (B2): 1753–1762. Bibcode:1986JGR....91.1753A. doi:10.1029/JB091iB02p01753.
• Bement, Leland C.; Larrick, Dakota; Hughes, Richard E.; Carlson, Kristen (31 January 2020). "Evidence for Late Paleoindian Scavenging of Early Paleoindian Obsidian, Oklahoma Panhandle". PaleoAmerica. 6 (2): 194–198. doi:10.1080/20555563.2019.1709323. S2CID 213251095.
• Broxton, David; Woldegabriel, Giday; Peters, Lisa; Budahn, James; Luedemann, Gary (2007). "Pliocene volcanic rocks of the Tshicoma Formation, east-central Jemez volcanic field: chemistry, petrography, and age constraints" (PDF). New Mexico Geological Society Field Conference Series. 58: 284–295. Retrieved 16 May 2020.
• Gardner, Jamie N.; Goff, Fraser; Garcia, Sammy; Hagan, Roland C. (1986). "Stratigraphic relations and lithologic variations in the Jemez Volcanic Field, New Mexico". Journal of Geophysical Research. 91 (B2): 1763. Bibcode:1986JGR....91.1763G. doi:10.1029/JB091iB02p01763.
• Goff, Fraser; Gardner, Jamie N.; Reneau, Steven L.; Kelley, Shari A.; Kempter, Kirt A.; Lawrence, John R. (2011). "Geologic map of the Valles caldera, Jemez Mountains, New Mexico". New Mexico Bureau of Geology and Mineral Resources Map Series. 79: V13C–2606. Bibcode:2011AGUFM.V13C2606G. Retrieved 18 May 2020.
• Griggs, R. L. (1964). "Geology and ground-water resources of the Los Alamos area, New Mexico". U.S. Geol. Survey Water-Supply Paper. 1753. CiteSeerX 10.1.1.939.251.
• Heiken, G; Goff, F; Gardner, J N; Baldridge, W S; Hulen, J B; Nielson, D L; Vaniman, D (May 1990). "The Valles/Toledo Caldera Complex, Jemez Volcanic Field, New Mexico". Annual Review of Earth and Planetary Sciences. 18 (1): 27–53. Bibcode:1990AREPS..18...27H. doi:10.1146/annurev.ea.18.050190.000331.
• Justet, Leigh (1 January 2003). Effects of basalt intrusion on the multi-phase evolution of the Jemez volcanic field, New Mexico (dissertation). University of Nevada, Las Vegas. Retrieved 16 May 2020.
• Kelley, Shari A.; McIntosh, William C.; Goff, Fraser; Kempter, Kirt A.; Wolff, John A.; Esser, Richard; Braschayko, Suzanne; Love, David; Gardner, Jamie N. (June 2013). "Spatial and temporal trends in pre-caldera Jemez Mountains volcanic and fault activity". Geosphere. 9 (3): 614–646. Bibcode:2013Geosp...9..614K. doi:10.1130/GES00897.1.
• Konkright, Kelsy Jo (2016). Petrogenesis of the El Rechuelos Rhyolite, Jemez Mountains Volcanic Field, New Mexico, USA. Vol. 3632. UNLV Theses, Dissertations, Professional Papers, and Capstones. Retrieved 23 November 2020.
• Loeffler, Bruce M.; Vaniman, David T.; Baldridge, W. Scott; Shafiqullah, Muhammed (1988). "Neogene rhyolites of the northern Jemez volcanic field, New Mexico". Journal of Geophysical Research. 93 (B6): 6157. Bibcode:1988JGR....93.6157L. doi:10.1029/JB093iB06p06157.
• Rowe, M. C.; Wolff, J. A.; Gardner, J. N.; Ramos, F. C.; Teasdale, R.; Heikoop, C. E. (November 2007). "Development of a Continental Volcanic Field: Petrogenesis of Pre-caldera Intermediate and Silicic Rocks and Origin of the Bandelier Magmas, Jemez Mountains (New Mexico, USA)". Journal of Petrology. 48 (11): 2063–2091. Bibcode:2007JPet...48.2063R. doi:10.1093/petrology/egm050.
• Singer, Bradley S.; Kudo, Albert M. (November 1986). "Assimilation-fractional crystallization of Polvadera Group rocks in the northwestern Jemez Volcanic Field, New Mexico". Contributions to Mineralogy and Petrology. 94 (3): 374–386. Bibcode:1986CoMP...94..374S. doi:10.1007/BF00371445. S2CID 129818680.
• Smith, R.L.; Bailey, R.A.; Ross, C.S. (1969). "Stratigraphic Nomenclature of ' Volcanic Rocks in the Jemez Mountains, New Mexico" (PDF). Geological Survey Bulletin (1274-P). Retrieved 4 May 2020.
• Turbeville, B.N; Waresback, Damon B; Self, Stephen (February 1989). "Lava-dome growth and explosive volcanism in the Jemez Mountains, New Mexico: Evidence from the plio-pleistocene puye alluvial fan". Journal of Volcanology and Geothermal Research. 36 (4): 267–291. Bibcode:1989JVGR...36..267T. doi:10.1016/0377-0273(89)90074-7.
• Whitmeyer, Steven; Karlstrom, Karl E. (2007). "Tectonic model for the Proterozoic growth of North America". Geosphere. 3 (4): 220. doi:10.1130/GES00055.1.
• Wolff, J. A. (14 October 2004). "Petrogenesis of Pre-caldera Mafic Lavas, Jemez Mountains Volcanic Field (New Mexico, USA)". Journal of Petrology. 46 (2): 407–439. Bibcode:2004JPet...46..407W. doi:10.1093/petrology/egh082.
• Zimmerer, Matthew J.; Lafferty, John; Coble, Matthew A. (January 2016). "The eruptive and magmatic history of the youngest pulse of volcanism at the Valles caldera: Implications for successfully dating late Quaternary eruptions". Journal of Volcanology and Geothermal Research. 310: 50–57. Bibcode:2016JVGR..310...50Z. doi:10.1016/j.jvolgeores.2015.11.021.