| Deposit ID | 10310645 |
|---|---|
| Record type | Site |
| Current site name | McLaughlin Mine |
| Alternate or previous names | Manhattan |
| Geographic coordinates: | -122.3613, 38.83705 (WGS84) |
|---|---|
| Elevation | 597 |
| Location accuracy | 100(meters) |
| Relative position | 14 miles east-southeast of Lower Lake. |
Political divisions (FIPS codes)
Napa(county)
California(state)
United States(country)
North America(continent)
Land(continent)
USGS map quadrangles
Knoxville(quadrangle 1:24,000 scale)
Healdsburg(quadrangle 1:100,000 scale)
Santa Rosa(quadrangle 1:250,000 scale)
Hydrologic units (watersheds)
Lower Sacramento(hydrologic accounting unit)
Sacramento(hydrologic subregion)
California(hydrologic region)
| Country | State | County |
|---|---|---|
| United States | California | Napa |
| United States | California | Yolo |
| Meridian | Township | Range | Section | Fraction | State |
|---|---|---|---|---|---|
| Mount Diablo | 011N | 005W | 01 | California | |
| Mount Diablo | 011N | 004W | 06 | California | |
| Mount Diablo | 012N | 005W | 36 | California |
| Commodity | Importance |
|---|---|
| Gold | Primary |
| Silver | Primary |
| Mercury | Secondary |
| Antimony Critical | Tertiary |
| Arsenic Critical | Tertiary |
| Thallium | Tertiary |
| Copper | Tertiary |
| Lead | Tertiary |
| Zinc Critical | Tertiary |
| Iron | Tertiary |
| Materials | Type of material |
|---|---|
| Electrum | Ore |
| Pyrargyrite | Ore |
| Gold | Ore |
| Pyrite | Ore |
| Miargyrite | Ore |
| Freibergite | Ore |
| Polybasite | Ore |
| Cinnabar | Ore |
| Metacinnabar | Ore |
| Mercury | Ore |
| Chalcedony | Ore |
| Quartz | Ore |
| Adularia | Ore |
| Alunite | Ore |
| Pyrite | Ore |
| Stibnite | Ore |
| Pyrite | Ore |
| Arsenic | Ore |
| Realgar | Ore |
| Orpiment | Ore |
| Arsenopyrite | Ore |
| Sphalerite | Ore |
| Chalcopyrite | Ore |
| Galena | Ore |
| Opal | Gangue |
| Model code | 104 |
|---|---|
| USGS model code | 25a |
| Deposit model name | Hot-spring Au-Ag |
| Mark3 model number | 45 |
| Host or associated | Host | ||||
|---|---|---|---|---|---|
| Rock type | Metamorphic Rock > Serpentinite | ||||
| Rock unit name | Coast Range Ophiolite | ||||
| |||||
| Host or associated | Host | ||||
|---|---|---|---|---|---|
| Rock type | Sedimentary Rock > Clastic Sedimentary Rock > Mudstone | ||||
| Rock unit name | Knoxville Formation | ||||
| |||||
| Host or associated | Host | ||||
|---|---|---|---|---|---|
| Rock type | Tectonite > Tectonic Melange | ||||
| Rock type qualifier | polymictic melange | ||||
| Rock unit name | Coast Range Ophiolite | ||||
| |||||
| Host or associated | Host | ||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|
| Rock type | Volcanic Rock (Aphanitic) > Mafic Volcanic Rock > Basalt | ||||||||||
| Rock type qualifier | plagioclase | ||||||||||
| Rock unit name | Clear Lake Volcanics | ||||||||||
| |||||||||||
| Host or associated | Host | ||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|
| Rock type | Volcanic Rock (Aphanitic) > Intermediate Volcanic Rock > Andesite | ||||||||||
| Rock type qualifier | basaltic | ||||||||||
| Rock unit name | Clear Lake Volcanics | ||||||||||
| |||||||||||
| Host or associated | Host | ||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|
| Rock type | Sedimentary Rock > Mixed Clastic/Volcanic Rock | ||||||||||
| Rock type qualifier | volcaniclastic rock | ||||||||||
| Rock unit name | Clear Lake Volcanics | ||||||||||
| |||||||||||
| (1) | -122.3613, 38.83705 |
|---|
| Type of structure | Local |
|---|---|
| Structure description | Stony Creek Fault OR (alternatively) The segment of the Stony Creek Fault associated with the ore deposit dips moderately (30o-45o) to the northeast, although it is near vertical along strike to the northwest and southeast of the deposit. Tosdal and others (1996) believed that the precious-metal-bearing veins associated with the fault formed during two distinct stages, which resulted from a major change in the regional stress field. The first stage produced a local pressure shadow in the fault zone, which was invaded by hydrothermal fluids to form the high-grade sheeted vein complex. The second stage produced a larger but lower-grade set of veins spread over a 6,000-foot segment of the fault zone. The metalliferous veins are mostly within the tectonic melange in the immediate footwall side of the fault, although some mineralization is present in hydrothermally Knoxville Formation on the immediate hanging wall side of the fault. Width of the deposit appears to be restricted to the southwest by a large mass of serpentinite melange in the footwall and to the northeast by non-altered Knoxville Formation in the hanging wall. Vein thicknesses range from less than an inch to about two feet, but typically are no more than six inches. In general, stage 1 veins strike northeasterly, while stage 2 veins strike southeasterly. |
| Type of structure | Regional |
| Structure description | Stony Creek Fault |
| Type of structure | Local |
| Structure description | Changes from barren rock to high-grade ore were notably very abrupt. Ore grade was observed to correlate more with density of veins rather than type of veins; the sheeted vein complex was notable for its multiple episodes of cross-cutting (at least five have been recognized). The main ore body extended to about 1,000 feet depth, although Sherlock and others (1995) show detected gold down to at least 1,600 feet. |
| General form | Wedge |
|---|
| Operation type | Surface |
|---|---|
| Development status | Producer |
| Commodity type | Metallic |
| Deposit size | Large |
| Significant | Yes |
| Discovery year | 1978 |
| District name | Knoxville District |
|---|
| Ownership category | Private |
|---|---|
| Area name | Napa County Planning Department |
| Ownership category | BLM Administrative Area |
| Area name | BLM Ukiah District |
| Type | Owner-Operator |
|---|---|
| Owner | Homestake Mining Co. |
Averitt, P., 1945, Quicksilver deposits of the Knoxville District, Napa, Yolo, and Lake counties, California: California Journal of Mines and Geology, v. 41, no. 2, p. 65-89.
Bailey, E.H. and others, 1964, Franciscan and related rocks and their significance in the geology of western California: California Division of Mines and Geology Bulletin 183, 177 p.
Berger, B.R., 1986, Descriptive model of hot-spring Au-Ag, in Cox, D.P. and Singer, D.A., editors, Mineral deposit models: U.S. Geological Survey Bulletin 1693, p. 143-144.
Carlson, C., 1981a, Sedimentary serpentinites of the Wilbur Springs area -a possible Early Cretaceous structural and stratigraphic link between the Franciscan Complex and the Great Valley Sequence: Master's thesis, Stanford University, 105p.
Carlson, C., 1981b, Upwardly mobile melanges, serpentinite protrusions, and transport of tectonic blocks in accretionary prisms: Geological Society of America Abstracts with Programs, v. 13, no. 2, p. 48.
Carlson, C., 1984a, Depositional environments and sedimentary facies of foliate serpentinite breccias, Wilbur Springs, in Carlson, C., editor, Depositional facies of sedimentary serpentinite: Selected examples from the Coast Ranges, California: Society of Economic Paleontologists and Mineralogists Field Trip Guidebook No. 3, Tulsa, Oklahoma, p. 113-116.
Carlson, C., 1984b, Stratigraphic and structural significance of foliate serpentinite breccias, Wilbur Springs, in Carlson, C., editor, Depositional facies of sedimentary serpentinite: Selected examples from the Coast Ranges, California: Society of Economic Paleontologists and Mineralogists Field Trip Guidebook No. 3, Tulsa, Oklahoma, p. 108-112.
Chapman, R.H. and others, 1982, Gravity, structure, and geothermal resources of the Calistoga area, Napa and Sonoma counties: California Geology, v. 35, no. 8, p. 175-183.
Dickinson, W.R., 1981, Plate tectonics and the continental margin of California, in Ernst, W.G., editor, The geotectonic development of California (Rubey volume 1), Prentice-Hall, Englewood Cliffs, New Jersey, p. 1-28.
Forstner, W., 1903, The quicksilver resources of California: California State Mining Bureau Bulletin 27, p. 81-89.
Fox, K.F., Jr., 1983, Tectonic setting of Late Miocene, Pliocene, and Pleistocene rocks in part of the Coast Ranges north of San Francisco, California: U.S. Geological Survey Professional Paper 1239, 33 p.
Fryer, P., 1992, Volcanoes of the Marianas: Scientific American, v. 266, no. 2, p. 46-52.
Gustafson, D.L., 1991, Anatomy of a discovery: The McLaughlin gold mine, Napa, Yolo, and Lake counties, California: Economic Geology Monograph 8, p. 350-359.
Hopson, C.A. and others, 1981, Coast Range ophiolite, western California, in Ernst, W.G., editor, The geotectonic development of California: Prentice-Hall, Englewood Cliffs, New Jersey, p. 418-510.
Jennings, C. W., 1994, Fault activity map of California and adjacent areas with locations and ages of recent volcanic eruptions: California Division of Mines and Geology, Geologic Data Map No. 6, scale 1:750,000.
McLaughlin, R. J. and others, 1980, Structure of Late Mesozoic rocks in the core of the Wilbur Springs Antiform, northern Coast Ranges, California: Geological Society of America Abstracts with Programs, v. 12, no. 3 , p. 119.
McLaughlin, R. J. and others, 1990, Geologic map and structure sections of the Little Indian Valley-Wilbur Springs geothermal area, northern Coast Ranges, California: U. S. Geological Survey Miscellaneous Investigations Series Map I-1706, scale 1:24,000.
Nelson, C.E., 1987, Gold deposits in the hot springs environment, in Schafer, R.W. and others, editors, Bulk mineable precious metal deposits of the western United States: Symposium Proceedings of the Geological Society of Nevada, p. 417-432.
Phipps, S.P., 1992, Late Cenozoic wedging and blind thrusting beneath the Sacramento Valley and eastern Coast Ranges, in Erskine, M.C. and others, editors, Field guide to the tectonics of the boundary between the California Coast Ranges and the Great Valley of California: American Association of Petroleum Geologists, Pacific Section, p. 63-84.
Phipps, S.P. and Unruh, J.R., 1992, Crustal-scale wedging beneath an imbricate roof-thrust system: Geology of a transect across the western Sacramento Valley and northern Coast Ranges, California, in Erskine, M.C. and others, editors, Field guide to the tectonics of the boundary between the California Coast Ranges and the Great Valley of California: American Association of Petroleum Geologists, Pacific Section, p. 117-140.
Thorkelson, D.J. and Taylor, R.P., 1989, Cordilleran slab windows: Geology, v. 17, no. 9, p. 833-836.
Tosdal, R.M. and others, 1995, Structural evolution of the McLaughlin precious metal deposit, northern California, in Geology and ore deposits of the American Cordillera; a symposium: Geological Society of Nevada, United States, 76 p.
Tosdal, R.M. and others, 1996, Precious metal mineralization in a fold and thrust belt: The McLaughlin hot spring deposit, northern California, in Coyner, A.R. and Fahey, P.L., editors, Geology and ore deposits of the American Cordillera: Geological Society of Nevada Symposium Proceedings, Reno/Sparks, Nevada, April 1995, p. 839-854.
D?Appolonia Consulting Engineers, Inc., 1983, Project description and environmental assessment report, prepared for Homestake Mining Company: unpublished report (CDMG Library, Sacramento).
| Subject category | Comment text |
|---|---|
| Deposit | The ore deposit developed in a shallow epithermal, hot-spring environment, centered around a sheeted vein complex, which was immediately below a siliceous sinter terrace. Hydrothermal explosion breccias, chalecedony veins, and maar deposits indicate periodically explosive fluid flow. The geochemistry of the ore fluids is similar to that observed at Cherry Hill, an active gold-depositing hot-spring, located about 14 miles to the north. Oxygen and hydrogen isotope studies and fluid inclusions studies show that the ore fluids developed as a boiling, low-salinity (~2.4 weight % NaCl equivalent), low-CO2 mixture of three distinct fluids: evolved, isotopically heavy, petroleum- and methane-rich connate water, magmatic fluids, and meteroic water. The gold, found in the hydrocarbon-bearing opal occurs 1) as a coating in large pores containing fluid inclusions, 2) as small crystals, which coalesce to form dendrites, and 3) within syneresis cracks that cut the vein banding (Rytuba, 1993). Gold and silver mineralization are confined largely to less than about 1,100 feet depth below the original ground surface of the deposit as represented by the sinter terrace. In the sheeted vein complex, gold was locally more abundant than silver only in the upper 700 feet; from 700 feet to 1,100 feet silver was dominant with minor gold. Below this depth, base metals are dominant. Shallow conditions of ore formation are also indicated by geochemical evidence of a system dominated by meteoric fluid and a boiling phase as well as open textures in veins and the presence of opal and chalcedony. Boiling of the hydrothermal system is interpreted to be the dominant control on gold mineralization and the vertical metal zoning in the deposit. Temperature of formation of the deposit, based on fluid inclusion studies, ranged from 121o-263oC. |
| Type | Date | Name | Affiliation | Comment |
|---|---|---|---|---|
| Reporter | 04-MAY-2000 | Fuller, Michael S. (Higgins, Chris T.) | California Division of Mines and Geology | |
| Editor | 01-SEP-2007 | Schruben, Paul G. | U.S. Geological Survey | Converted from S&A FileMaker format to Oracle. Edit checks on rocks, units, and ages with Geolex search, and other fields. |
Supplemental information added by qvyshift.com. Not part of the original USGS MRDS record.
MRDS records operators as of each record's last update (≤ 2019). Some of the operators listed here have since changed hands or dissolved:
Curated by qvyshift.com from publicly-reported M&A activity (SEC filings, press releases, USGS Mineral Yearbooks). Not authoritative — verify against primary sources before relying on it. The MSHA panel above is the current authoritative source for actively-permitted mines.
These are landing pages for further research — the state agencies don't currently expose per-mine deep links.