Soledad Mountain Deposit

The Soledad Mountain Deposit is a gold and silver mine located in Kern county, California at an elevation of 3,510 feet.

About the MRDS Data:

All mine locations were obtained from the USGS Mineral Resources Data System. The locations and other information in this database have not been verified for accuracy. It should be assumed that all mines are on private property.

Mine Info

Name: Soledad Mountain Deposit  

State:  California

County:  Kern

Elevation: 3,510 Feet (1,070 Meters)

Commodity: Gold, Silver

Lat, Long: 34.98541, -118.19305

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Soledad Mountain Deposit MRDS details

Site Name

Primary: Soledad Mountain Deposit
Secondary: Golden Queen
Secondary: Queen Esther
Secondary: Silver Queen
Secondary: Soledad Extension
Secondary: Starlight
Secondary: Echo
Secondary: Gray Eagle
Secondary: Elephant
Secondary: Karma
Secondary: Bobtail


Commodity

Primary: Gold
Primary: Silver
Secondary: Antimony
Secondary: Lead
Secondary: Copper


Location

State: California
County: Kern
District: Mojave District


Land Status

Land ownership: BLM Administrative Area
Note: the land ownership field only identifies whether the area the mine is in is generally on public lands like Forest Service or BLM land, or if it is in an area that is generally private property. It does not definitively identify property status, nor does it indicate claim status or whether an area is open to prospecting. Always respect private property.
Administrative Organization: Ridgecrest Field Office (BLM)


Holdings

Not available


Workings

Not available


Ownership

Owner Name: Golden Queen Mining Company, Ltd.


Production

Not available


Deposit

Record Type: Site
Operation Category: Past Producer
Deposit Type: Hydrothermal vein
Operation Type: Underground
Discovery Year: 1894
Years of Production:
Organization:
Significant: Y
Deposit Size: M


Physiography

Not available


Mineral Deposit Model

Model Name: Epithermal vein, Sado


Orebody

Form: Tabular


Structure

Type: L
Description: Significant veins from east to west include the Karma, Queen Esther, Silver Queen, Golden Queen, Starlight, Soledad Extension, Hope, Elephant, and Bobtail-Excelsior. These trend N10-40W and dip 60o or more to the NE or SW. Two other younger minor sets trend N50-80W and N-S.

Type: R
Description: San Andreas Fault; Garlock Fault


Alterations

Alteration Type: L
Alteration Text: Silicic; quartz Advanced Argillic; quartz, kaolinite, alunite Oxidation; limonite


Rocks

Name: Quartz Monzonite
Role: Associated
Age Type: Associated Rock
Age Young: Late Cretaceous

Name: Porphyry
Role: Host
Description: rhyolite
Age Type: Host Rock
Age in Years: 16.900000+-
Dating Method: K-Ar
Material Analyzed: sanidine
Age Young: Early Miocene

Name: Rhyolite
Role: Host
Description: Porphyritic
Age Type: Host Rock
Age in Years: 16.900000+-
Dating Method: K-Ar
Age Young: Early Miocene

Name: Rhyolite
Role: Host
Description: flows
Age Type: Host Rock
Age in Years: 21.500000+-
Dating Method: K-Ar
Age Young: Early Miocene

Name: Rhyolite
Role: Host
Description: Pyroclastic
Age Type: Host Rock
Age Young: Early Miocene

Name: Quartz Latite
Role: Host
Age Type: Host Rock
Age in Years: 21.500000+-
Dating Method: K-Ar
Age Young: Early Miocene


Analytical Data

Not available


Materials

Ore: Proustite
Ore: Stibnite
Ore: Gold
Ore: Cerargyrite
Ore: Argentite
Ore: Galena
Ore: Chalcopyrite
Gangue: Pyrite
Gangue: Calcite
Gangue: Quartz


Comments

Comment (Economic Factors): The Soledad Mountain deposit is one of the most productive in southern California. The Golden Queen Mine and its precursors alone produced at least $10,000,000 in gold and silver from 1894 to the 1950s (Troxel and Morton, 1962). This ranked second in Kern County to the Yellow Aster Mine at Randsburg, which is to the northeast. Production of gold and silver in the other mines of the deposit may be about $500,000. Other important mines include the Elephant Group, Bobtail, and Karma. Reserves at the deposit today are reportedly large. The Golden Queen Mining Company, Ltd., reported a drillhole-indicated resource of 86.5 million metric tons with an average grade of about 1 gram/metric ton gold and 14.4 grams/metric ton silver (Golden Queen Mining Company, Ltd., 1998); at a gold-equivalent cutoff grade of 0.4 grams/metric ton, the deposit is estimated to contain 2.43 million ounces of gold and 39.6 million ounces of silver, which would make it the largest known precious-metal deposit in Kern County.

Comment (Deposit): Soledad Mountain is an eroded constructional volcanic edifice composed of a calc-alkaline suite of silicic domes, flows, and pyroclastic rock. The edifice was intruded into and built upon a plutonic basement. The Soledad Mountain deposit consists of many subparallel NW-trending fissure-filling quartz veins that cut this volcanic complex. The veins are exposed at the surface, which indicates shallow depth of formation. Descriptions of the textures of the quartz veins are scarce, but there are many references to brecciation and oxidation. A layer of silica (siliceous sinter?), interbedded with lacustrine deposits associated with the volcanic complex, was reported by McCusker (1982) to be on the eastern flank of the mountain. Hydrothermal alteration includes extensive silicification and local development of kaolinite and alunite. According to Julihn and Horton (1937), most of the values in the ore are derived from gold in exceedingly fine particles, together with silver sulfides (argentite) and silver chloride (cerargyrite), which likewise are seldom apparent; the ore commonly appears to be merely quartz or silicified country rock, which are often brecciated and recemented. Best ore typically occurred in the ?felsite? unit (Julihn and Horton, 1937), which may be equivalent to the aphyric rhyolite unit of McCusker (1982). The above evidence indicates that the deposit was formed under shallow epithermal conditions.

Comment (Geology): The western Mojave Desert is part of what is termed the ?Mojave Desert block.? the geologic history of this structural block, particularly the western part, is still controversial. The western area is considered by Dokka (1989) to be part of what he termed the Mojave Extensional Belt (MEB), an approximately E-W-trending zone that is inferred to underlie much of the western two-thirds of the Mojave Desert including Soledad Mountain. The westernmost part of the belt, which includes Soledad Mountain, was termed the Edwards Terrane by Dokka (1989). In this model, the upper and middle crust of the MEB was extended in early Miocene (24 to 21 Ma) by low- and high-angle normal faulting accompanied by intrusion and eruption of intermediate to silicic magmas (Dokka and others, 1998). According to Dokka and Ross (1995), the MEB was overprinted about 20-18 Ma by a zone of dextral shear known as the Trans-Mojave-Sierran shear zone. This zone produced clockwise vertical-axis rotation of both the western Mojave Desert and the southernmost Sierra Nevada. Dokka and Ross (1995) believed that interaction of the Pacific and North American plates during this period of time was directly responsible for regional extension in the western Mojave Desert. The interaction may have been highlighted by transtensional pulling away of the Pacific Plate from the North American Plate (Atwater, 1989) which caused the edge of the North American Plate to extensionally collapse, perhaps by gravitational failure. This inferred extensional activity between 24 and 18 Ma overlaps the known ages of all Cenozoic volcanic activity at Soledad Mountain as determined by McCusker (1982). Based on surface mapping and seismic-reflection surveys, Dokka (1989) concluded that the inliers discussed above are tilted upper-plate normal-fault blocks that are floored by detachment faults in the subsurface. The current orientation of structural features indicate that the extensional direction for the MEB is NE-SW; however, Dokka and Ross (1995) cited paleomagnetic evidence that suggests the western part of the Mojave Desert block may have been rotated clockwise since extension in the early Miocene such that the true extensional direction was originally N-S. Glazner and others (1996) believed, however, that the observations cited by Dokka and Ross (1995) were not convincing evidence of extension and rotation in the western Mojave Desert. Indeed, the tectonic history and causes of the Cenozoic magmatism are still not satisfactorily understood; several tectonic models have been proposed over the last few decades for this region as well as the western U.S., but none have yet satisfactorily explained all observable features and events. Metallogeny Albers (1981) and Albers and Fraticelli (1984) interpreted the westernmost part of the Mojave Desert geomorphic province to be underlain by a composite terrane of oceanic and island-arc crust with a few localized areas that are geologically favorable terrane for gold deposits; Soledad Mountain is one of these terranes. Various silicic eruptive centers of Tertiary age in this region have been the sites of epithermal precious-metal mineralization. Besides Soledad Mountain, other deposits of a similar epithermal nature within these volcanic centers include Standard Hill, Middle Buttes, and Tropico Hill. The determination of whether extension, as described above, has taken place in this region is important regarding metallogeny of the region. Extensional environments are favorable for the migration of magmas and associated metal-bearing hydrothermal fluids. The potential for future discoveries of ore deposits in this region may depend largely on exploration beneath the alluvial fringes adjacent to the known deposits or in areas that may have formed in extensional environments.

Comment (Geology): INTRODUCTION This part of California consists of a complex intersection of three geomorphic provinces: the Mojave Desert province forms a west-pointing wedge between the Sierra Nevada province on the north and the Transverse Ranges province on the south. Within this region of intersection are various precious-metal deposits, a few of which are considered significant. Most important is Soledad Mountain, which is situated within the Mojave Desert province. REGIONAL SETTING Several generations of geologic study have been applied to this region of California. Earlier work by Simpson (1934) and Dibblee (1963, 1967) established a regional framework of stratigraphy and structure upon which later, more detailed local studies have been conducted. One of these important local studies, which centered on the volcanic features of Soledad Mountain, is that of McCusker (1982) who mapped the mountain at a scale of 1:6,000. Other older technical papers also present information on the geology of the mountain (Bateson, 1907; Simpson, 1934; Julihn and Horton, 1937; Dibblee, 1963). On a broader scale, many papers have been published in the last 20 years that attempt to reconstruct this region?s geologic history in the light of plate tectonics; among these are papers or volumes by Dickinson (1981, 1997), Burchfiel and others (1992), Dokka and Ross (1995), Atwater (1989), and Atwater and Stock (1998). Stratigraphy The rocks of the western part of the Mojave Desert province can be generalized as topographic ?islands,? or inliers, that are surrounded by plains of Quaternary alluvium. These inliers consist of Mesozoic plutonic basement with pendants of older metamorphic rock, which are overlain by an eroded Tertiary cover. The Mesozoic plutonic basement ranges in composition from quartz diorite to granite and is present beneath the alluvial plains. The Tertiary cover consists of volcanic and sedimentary rocks. Simpson (1934) originally mapped the Tertiary cover as the ?Rosamond series,? but Dibblee (1963, 1967) later remapped it as the ?Tropico Group.? Within the Tropico Group, Dibblee (1963, 1967) mapped a volcanic unit known as the Gem Hill Formation, which includes a subunit at Soledad Mountain called the Bobtail quartz latite member. Dibblee placed the pyroclastic phases at Soledad Mountain in the Gem Hill and the hypabyssal and lava phases in the Bobtail. Structure Although the basement complex is part of the Sierra Nevada plutonic arc, which was associated with subduction tectonics during the Mesozoic, it is regional tectonism during the Late Cenozoic that was important in the development of the ore deposit at Soledad Mountain. Tectonics of this region during the Late Cenozoic were first dominated by subduction of plates to the west of this region and then by subsequent movements along the northwest-trending right-lateral San Andreas Fault System, which progressively formed when the Farallon-Pacific spreading center collided with the subduction zone (Atwater, 1989). This tectonic activity was part of the larger interaction of the North American Plate, Pacific Plate, and intervening Farallon Plate (and its subsidiary plates, which formed upon breakup of the Farallon within subduction zones) as they collided along the west coast of North America. With shutting off of subduction along the coast and resultant development of a slab window inboard of the newly developed San Andreas transform boundary that replaced the trench, magma may have ascended from the mantle to fill the void between the transform fault system and the broken-off slab that was still descending to the east of the system. The volcanism at Soledad Mountain may have been a local expression of this process.

Comment (Environment): Soledad Mountain is an approximately 6-square-mile rugged topographic prominence that rises above the flat alluvial plain of the westernmost Mojave Desert geomorphic province. It is the most conspicuous of many isolated hills and buttes that rise from this plain, which forms a triangular west-pointing wedge bordered by the Tehachapi Mountains on the north and the San Gabriel Mountains on the south. The mountain reaches an elevation of 4,190 feet from a base level of about 2,700 feet and is the eroded remnant of a complex of volcanic vents. Many dry washes and gullies cut the slopes of Soledad Mountain. The surrounding alluvial plain is typical of the Mojave Desert hydrographically in that washes are dry except during storms. Drainage is internal, with no significant channels in the immediate area around the mountain. Based on water well measurements, the water table is about 300 feet deep beneath the plain on the north side of Soledad Mountain, while it is about 100 feet deep on the south side. Vegetation is typical of the high desert of this latitude: sparse, characterized by creosote, burroweed, bunch grass, and scattered Joshua trees. Climate of this area is arid, with an average total precipitation of slightly less than 8 inches in nearby Lancaster. Temperatures reach freezing during the winter, but commonly rise to over 100oF during the summer. Soledad Mountain itself is undeveloped except for the remnants of extensive mining activity over the last century. The surrounding plain has scattered residences, some of which are clustered. The small town of Mojave is less than 5 miles to the north. A major freeway (State Highway 14) and railroad run north-south on the east edge of the mountain.

Comment (Workings): The historic workings at the Soledad Mountain are extensive. The mountain is riddled with numerous shafts, adits, glory holes, and open cuts as well as tunnels, raises, and winzes. Most are concentrated on the northern slope of the mountain where the mineralized quartz veins are most abundant. Over the rest of Soledad Mountain, workings associated with prospects are common. Workings were developed as deep as about 1,000 feet below the surface at the Starlight and Golden Queen mines. Total lateral extent of the underground workings is unknown, but is conservatively estimated to exceed many tens of kilometers. Detailed information and maps of underground development are presented in Troxel and Morton (1962) and Julihn and Horton (1937). The veins were developed by drifts and crosscuts. Methods of mining during the 1930s included shrinkage stoping, where backs were stable and the veins under 20 feet in width, and a square-set slot-and-pillar method where backs were unstable (Julihn and Horton, 1937). Golden Queen Mining Company, Ltd., the current operator of the property, has rehabilitated about 13 miles of underground workings.

Comment (Geology): GEOLOGY AT SOLEDAD MOUNTAIN DEPOSIT Stratigraphy At Soledad Mountain proper, a suite of Miocene calc-alkaline volcanic rocks constitutes almost the entire mountain. They comprise a silicic volcanic-dome complex, which was the site of many eruptions. The magma was intrusive into a basement of Mesozoic quartz monzonite and minor metavolcanic rock. More specifically, McCusker (1982) reported seven coalescing volcanic domes as well as lava flows, dikes, and pyroclastic deposits that were erupted during at least three episodes. Compositions of these rocks range from rhyolite to quartz latite. McCusker (1982) mapped, from oldest to youngest, the following main units: quartz latite, ?middle? pyroclastic unit, and aphyric rhyolite, all dated at about 21.5 Ma; a minor sequence of lacustrine sediments and andesite flows; and an upper unit of pyroclastic material and porphyritic rhyolite, dated at about 17 Ma. This complex is surrounded by Quaternary alluvium from various sources. Because of the complexity of the volcanic stratigraphy, its subsequent hydrothermal alteration, and the scarcity of chemical analyses, there is some complication in the literature regarding the use of nomenclature to describe the volcanic rocks. McCusker (1982) interpreted his aphyric rhyolite unit to be the same as the felsite of Dibblee?s (1963) Bobtail quartz latite member. He interpreted his porphyritic rhyolite unit to be the same as the porphyritic felsite of Dibblee?s (1963) Bobtail quartz latite member. Distinction of the lithologic units could be important in the overall evaluation of potential of this deposit for future mining because of their variability as hosts for mineralization. Structure The Soledad Mountain deposit is about 40 miles east-northeast of the intersection of the northwest-trending right-lateral San Andreas Fault Zone and the northeast-trending left-lateral Garlock Fault. Within the deposit itself, the most significant structure by far is the set of northwest-trending faults on the north and northwest flanks of Soledad Mountain that cut the Tertiary volcanic rock. These average about N10-40W in strike and dip steeply either northeast or southwest. Slickensides and other evidence indicate that displacements are dominantly normal. The faults have been filled with quartz veins, which range from a few feet to tens of feet in thickness and have been traced for lengths of several thousands of feet in places. Where observed in underground workings, the dips of the faults shallow with depth. Some of the veins continue to the southern flank of the mountain. Post-ore faults subparallel to the quartz veins cut the veins displacing them as much as 200 feet along the dip of the faults. McCusker (1982) also mapped two younger sets of faults, one that trends N50-80W and the other N-S. Alteration and Mineralization The Soledad Mountain deposit consists fundamentally of precious -metal epithermal quartz veins superimposed on a Miocene silicic volcanic complex. Knowledge of the location and attitudes of faults within this area is important as the faults served as the loci for mineral deposition. Most of the higher-grade ore bodies are in veins that fill faults in flow-banded rhyolite lava; much of the vein material is a breccia. Some of the outcrops of the veins are stained with iron and manganese oxides. According to McCusker (1982), all volcanic units of the Soledad Mountain complex have been affected by hydrothermal alteration, which is most extensive adjacent to the veins; he concluded that the most productive of the veins appear temporally and spatially related to the porphyritic rhyolite unit on the north part of Soledad Mountain. Some ore shoots were several hundred feet long.

Comment (Identification): The individual properties listed above under ?Other Names? are the most productive ones on Soledad Mountain that have been described in the literature.

Comment (Location): The main area of the deposit occupies portions of four contiguous sections. The location point selected for latitude and longitude is the approximate location of the original discovery site for the Golden Queen Mine as shown on the USGS Soledad Mountain 7.5-minute quadrangle map. This location is approximately in the center of Section 6.

Comment (Commodity): Commodity Info: Although this property would be mined in the future for its gold, it is dominantly a silver deposit, with an overall silver:gold ratio of about 5:1 at the Golden Queen Mine (locally the ratio is up to about 25:1). The minor commodities listed have had negligible production. Ore grades along the quartz veins varied from tenths of ounces to ounces of gold and silver per ton of ore.

Comment (Commodity): Ore Materials: Native gold, cerargyrite, argentite, proustite, chalcopyrite, galena, stibnite

Comment (Commodity): Gangue Materials: Quartz, pyrite, calcite, hydrous iron oxides

Comment (Development): Soledad Mountain has been the most important gold-silver deposit in the Mojave Mining District. Discovery of gold in float at nearby Bowers (now Standard) Hill about two miles to the north in 1894, led to discovery and development of the Queen Esther Mine at Soledad Mountain in the same year. Underground mining expanded rapidly with discoveries of gold-silver mineralization along the Queen Esther, Karma, Echo, Elephant, and Gray Eagle veins. This first phase of mining ended about 1914, with about $5 million in gold and silver produced. Grubstaking by the Burton Brothers during the Depression-era 1930s led to renewed mining of Soledad Mountain deposit as well as neighboring deposits in the Mojave Mining District. This activity continued work on the previously discovered veins and resulted in new discoveries. In particular, discovery of the Silver Queen vein by George Holmes in 1933 significantly revived the entire Mojave Mining District. Much of the important parts of the Soledad Mountain deposit were consolidated in 1935 as the Golden Queen Mine under ownership of the Golden Queen Mining Company. The company conducted extensive exploration and development, including diamond drilling, until shut down in 1942 by the War Production Board during World War II. Increased mining costs prevented renewal of operations after World War II, with the mill dismantled in 1950 and remaining assets liquidated in 1954. In the early 1950s, a few lessees processed a minor amount of ore from the deposit. All mines were idle in 1958 except for minor work by lessees. In 1983, the Anaconda Mining Company (unpublished document) concluded from reconnaissance that it appeared unlikely that there was potential for a bulk-tonnage gold-silver deposit here. Golden Queen Mining Company, Ltd., the current operator of this idle property, assumed control in about 1985, but has not begun mining because of the low price for gold. The Golden Queen Project is expected to be economic at a price of $325 per ounce. In this project, the company proposes to develop an open-pit, heap-leach operation, which will be capable of mining 5.67 million metric tons per year over a mine-life of 11 years. In 1999, the company conducted extensive exploration including about 32,000 feet of drilling and surface sampling. To improve the economics of the project, it is proposed to sell waste rock from the mining operation as aggregate to surrounding markets, which can be reached via an adjacent freeway and railroad. As of 2001, the company had reportedly secured all permits, but was still waiting for improvement in the price of gold to commence mining. Past processing at a large mill operated by the Golden Queen Mining Company on the northwest side of Soledad Mountain included use of cyanide for vat leaching. Water for the mill was obtained from two nearby wells at depths between 200-300 feet. Several other cyanide mills were active on the north side of the mountain during the first phase of mining in the early 1900s. In early years, some of the mills used amalgamation. Reclamation has not taken place at the deposit because mining took place before requirement of reclamation by the State of California in the 1970s. Many dumps and tailings are present on the mountain, particularly on the northern flank. In addition, numerous shafts, tunnels, and daylighted stopes are still open.

Comment (Geology): Mineralization consists of native gold, cerargyrite above the oxidized zone (water table), and argentite below it. These form the main ore minerals for precious metals at the deposit. Chalcopyrite and galena are also present in minor amounts. Alteration minerals are dominated by microcrystalline quartz, clays, and oxides, with alunite of undetermined extent. Discovery of additional ore bodies at Soledad Mountain will depend on additional exploration over the entire mountain. Age of the mineralization was interpreted by McCusker (1982) to have occurred during the waning stages of eruption of the upper silicic volcanic unit (upper pyroclastic and porphyritic rhyolite) about 17 Ma.


References

Reference (Deposit): Dibblee, T.W., Jr., 1967, Areal geology of the western Mojave Desert: U.S. Geological Survey Professional Paper 522, 153 p.

Reference (Deposit): Dickinson, W.R., 1981, Plate tectonic evolution of the southern Cordillera, in Dickinson, W.R. and Payne, W.D., editors, Relations of tectonics to ore deposits in the southern Cordillera: Arizona Geological Society Digest, v. 14, 288 p.

Reference (Deposit): Dokka, R.K., 1989, The Mojave Extensional Belt of southern California: Tectonics, v. 8, no. 2, p. 363-390.

Reference (Deposit): Dickinson, W.R., 1997, Tectonic implications of Cenozoic volcanism in coastal California: Geological Society of America Bulletin, v. 109, no. 8, p. 936-954.

Reference (Deposit): Dokka, R.K. and Ross, T.M., 1995, Collapse of southwestern North America and the evolution of early Miocene detachment faults, metamorphic core complexes, the Sierra Nevada orocline, and the San Andreas fault system: Geology, v. 23, no. 12, p. 1075-1078.

Reference (Deposit): Dokka, R.K. and others, 1998, The Trans Mojave-Sierran shear zone and its role in early Miocene collapse of southwestern North America, in Holdsworth, R.E. and others, editors, Continental transpressional and transtensional tectonics: Geological Society of London Special Publication 135, p. 183-202.

Reference (Deposit): Albers, J.P., 1981, A lithologic-tectonic framework for the metallogenic provinces of California: Economic Geology, v. 76, no. 4, p. 765-790.

Reference (Deposit): Golden Queen Mining Company, Ltd., 1998, Golden Queen increases ore reserve gold grade by 16%: Golden Queen Mining Company, Ltd., News Release, October 2, 1998, 2 p.

Reference (Deposit): Albers, J.P. and Fraticelli, L.A., 1984, Preliminary mineral resource assessment map of California: U.S. Geological Survey Map MR-88, scale 1:1,000,000.

Reference (Deposit): Atwater, T., 1989, Plate tectonic history of the northeast Pacific and western North America, in Winterer, E.L. and others, editors, The eastern Pacfic Ocean and Hawaii: Geological Society of America, The Geology of North America, v. N, p. 21-72.

Reference (Deposit): Atwater, T. and Stock, J, 1998, Pacific-North America plate tectonics of the Neogene southwestern United States: An update, in Ernst, W.G. and Nelson, C.A., editors, Integrated earth and environmental evolution of the southwestern United States: Geological Society of America, Clarence A. Hall, Jr. volume, p. 393-420.

Reference (Deposit): Bateson, G.E.W., 1907, The Mojave Mining District of California: Transactions of American Institute of Mining Engineers, v. 37, p. 160-177.

Reference (Deposit): Burchfiel, B.C. and others, 1992, The Cordilleran Orogen: Conterminous U.S.: Geological Society of America, The Geology of North America, v. G-3, 724 p.

Reference (Deposit): Golden Queen Mining Company, Ltd., 1997, Annual report: Spokane, Washington, 24 p.

Reference (Deposit): Miscellaneous information on the deposit is contained in File Number 339-5009 (CDMG Mineral Resources Files, Sacramento) and in files of the Anaconda Geological Documents Collection at the University of Wyoming.

Reference (Deposit): Julihn, C.E. and Horton, F.W., 1937, The Golden Queen and other mines of the Mojave District, California: U.S. Bureau of Mines Information Circular 6931, 42 p.

Reference (Deposit): McCusker, R.T., 1982, Geology of the Soledad Mountain volcanic complex, Mojave Desert, California: San Jose State University, M.S. thesis, 113 p.

Reference (Deposit): Simpson, E.C., 1934, Geology and mineral deposits of the Elizabeth Lake quadrangle, California: California Journal of Mines and Geology, v. 30, no. 4, p. 371-415.

Reference (Deposit): Troxel, B.W. and Morton, P.K., 1962, Mines and mineral resources of Kern County, California: California Division of Mines and Geology County Report 1, 370 p.

Reference (Deposit): Tucker, W.B., 1935, Mining activity at Soledad Mountain and Middle Buttes - Mojave Mining District: California Journal of Mines and Geology, v. 31, no. 4, p. 465-485.

Reference (Deposit): Tucker, W.B., 1923, Kern County, Mojave Mining District: California State Mining Bureau 19th Report of the State Mineralogist, p. 156-164.

Reference (Deposit): Tucker, W.B. and others, 1949, Mineral resources of Kern County: California Journal of Mines and Geology, v. 45, no. 2, p. 220-223.

Reference (Deposit): Nielsen, R.L., 1987, Soledad Mountain gold, Mojave Mining District, Kern County, California: Geocon, Incorporated, consulting report, Evergreen, Colorado, 6 p.

Reference (Deposit): Dibblee, T.W., Jr., 1963, Geology of the Willow Springs and Rosamond quadrangles, California: U.S. Geological Survey Bulletin 1089-C, p. 141-253.

Reference (Deposit): Christiansen, R.L. and Yeats, R.S., 1992, Post-Laramide geology of the U.S. Cordilleran region, in Burchfiel, B.C. and others, editors, The Cordilleran Orogen: Conterminous U.S.: Geological Society of America, The Geology of North America, v. G-3, p. 261-406.


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