Craig A Johnson, Ph.D.
Craig Johnson is a Research Geologist with the Geology, Geophysics, and Geochemistry Science Center.
Craig attended Dartmouth (AB), Michigan (MS), and Yale (PhD). He held a NASA postdoc and a staff position at the American Museum of Natural History in New York prior to joining the USGS in 1992. Craig is responsible for a stable isotope laboratory in which isotopes of carbon, hydrogen, nitrogen, oxygen, and sulfur are measured in rocks, waters, gases, and biological materials. Craig studies ore genesis, environmental impacts of mining, the source and fate of solutes in natural waters and crustal fluids, the isotopic record of marine sulfate, and isotopic records of paleoenvironments.
Science and Products
Major element and oxygen isotope geochemistry of vapour-phase garnet from the Topopah Spring Tuff at Yucca Mountain, Nevada, USA
Descriptive and geoenvironmental model for Co-Cu-Au deposits in metasedimentary rocks
Genesis of the Touissit-Bou Beker Mississippi Valley-type district (Morocco-Algeria) and its relation to the Africa-Europe collision
Sulfur, carbon, hydrogen, and oxygen isotope geochemistry of the Idaho cobalt belt
Phosphorite-hosted zinc and lead mineralization in the Sekarna deposit (Central Tunisia)
Genesis of the Touissit-Bou Beker Mississippi valley-type district (Morocco-Algeria) and its relationship to the Africa-Europe collision
The rise and fall of Lake Bonneville between 45 and 10.5 ka
A 50-year record of NOx and SO2 sources in precipitation in the Northern Rocky Mountains, USA
Co-Cu-Au deposits in metasedimentary rocks-A preliminary report
Geology, geochemistry, and genesis of the Greens Creek massive sulfide deposit, Admiralty Island, southeastern Alaska
Evolution of Ore Deposits and Technology Transfer Project: Isotope and Chemical Methods in Support of the U.S. Geological Survey Science Strategy, 2003-2008
Testing the limits of Paleozoic chronostratigraphic correlation via high-resolution (<500 k.y.) integrated conodont, graptolite, and carbon isotope (δ13Ccarb) biochemostratigraphy across the Llandovery–Wenlock (Silurian) boundary: Is
Non-USGS Publications**
**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.
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Major element and oxygen isotope geochemistry of vapour-phase garnet from the Topopah Spring Tuff at Yucca Mountain, Nevada, USA
Twenty vapour-phase garnets were studied in two samples of the Topopah Spring Tuff of the Paintbrush Group from Yucca Mountain, in southern Nevada. The Miocene-age Topopah Spring Tuff is a 350 m thick, devitrified, moderately to densely welded ash-flow tuff that is zoned compositionally from high-silica rhyolite to latite. During cooling of the tuff, escaping vapour produced lithophysae (former gaAuthorsRichard J. Moscati, Craig A. JohnsonDescriptive and geoenvironmental model for Co-Cu-Au deposits in metasedimentary rocks
IntroductionThis report is a revised model for a specific type of cobalt-copper-gold (Co-Cu-Au) deposit that will be evaluated in the next U.S. Geological Survey (USGS) assessment of undiscovered mineral resources in the United States (see Ferrero and others, 2012). Emphasis is on providing an up-to-date deposit model that includes both geologic and geoenvironmental aspects. The new model presenteAuthorsJohn F. Slack, Craig A. Johnson, J. Douglas Causey, Karen Lund, Klaus J. Schulz, John E. Gray, Robert G. EppingerGenesis of the Touissit-Bou Beker Mississippi Valley-type district (Morocco-Algeria) and its relation to the Africa-Europe collision
The Mississippi Valley-type deposits of the Touissit-Bou Beker district are hosted by a 25 m thick sequence of diagenetically and hydrothermally dolomitized carbonate platform rocks of Aalenian-Bajocian age. The sulfide mineralization consists principally of galena and sphalerite and occurs as open-space fillings of voids and moderate to massive replacement of the medium- to coarse-grained host doAuthorsMohammed Bouabdellah, Donald F. Sangster, David L. Leach, Alex C. Brown, Craig A. Johnson, Poul EmsboSulfur, carbon, hydrogen, and oxygen isotope geochemistry of the Idaho cobalt belt
Cobalt-copper ± gold deposits of the Idaho cobalt belt, including the deposits of the Blackbird district, have been analyzed for their sulfur, carbon, hydrogen, and oxygen isotope compositions to improve the understanding of ore formation. Previous genetic hypotheses have ranged widely, linking the ores to the sedimentary or diagenetic history of the host Mesoproterozoic sedimentary rocks, to MesoAuthorsCraig A. Johnson, Arthur A. Bookstrom, John F. SlackPhosphorite-hosted zinc and lead mineralization in the Sekarna deposit (Central Tunisia)
The Sekarna Zn–Pb deposit is located in Central Tunisia at the northeastern edge of the Cenozoic Rohia graben. Mineralization comprises two major ore types: (1) disseminated Zn–Pb sulfides that occur as lenses in sedimentary phosphorite layers and (2) cavity-filling zinc oxides (calamine-type ores) that crosscut Late Cretaceous and Early Eocene limestone. We studied Zn sulfide mineralization in thAuthorsHechmi Garnit, Salah Bouhel, Donatella Barca, Craig A. Johnson, Chaker ChtaraGenesis of the Touissit-Bou Beker Mississippi valley-type district (Morocco-Algeria) and its relationship to the Africa-Europe collision
The Mississippi Valley-type deposits of the Touissit-Bou Beker district are hosted by a 25 m thick sequence of diagenetically and hydrothermally dolomitized carbonate platform rocks of Aalenian-Bajocian age. The sulfide mineralization consists principally of galena and sphalerite and occurs as open-space fillings of voids and moderate to massive replacement of the medium- to coarse-grained host doThe rise and fall of Lake Bonneville between 45 and 10.5 ka
A sediment core taken from the western edge of the Bonneville Basin has provided high-resolution proxy records of relative lake-size change for the period 45.1–10.5 calendar ka (hereafter ka). Age control was provided by a paleomagnetic secular variation (PSV)-based age model for Blue Lake core BL04-4. Continuous records of δ18O and total inorganic carbon (TIC) generally match an earlier lake-leveAuthorsL. V. Benson, S.P. Lund, J. P. Smoot, D.E. Rhode, R. J. Spencer, K.L. Verosub, L.A. Louderback, C.A. Johnson, R. O. Rye, R.M. NegriniA 50-year record of NOx and SO2 sources in precipitation in the Northern Rocky Mountains, USA
Ice-core samples from Upper Fremont Glacier (UFG), Wyoming, were used as proxy records for the chemical composition of atmospheric deposition. Results of analysis of the ice-core samples for stable isotopes of nitrogen (δ15N, ) and sulfur (δ34S, ), as well as and deposition rates from the late-1940s thru the early-1990s, were used to enhance and extend existing National Atmospheric Deposition PrAuthorsDavid L. Naftz, Paul F. Schuster, Craig A. JohnsonCo-Cu-Au deposits in metasedimentary rocks-A preliminary report
A compilation of data on global Co-Cu-Au deposits in metasedimentary rocks refines previous descriptive models for their occurrence and provides important information for mineral resource assessments and exploration programs. This compilation forms the basis for a new classification of such deposits, which is speculative at this early stage of research. As defined herein, the Co-Cu-Au deposits conAuthorsJ. F. Slack, J. D. Causey, R. G. Eppinger, J. E. Gray, C.A. Johnson, K.I. Lund, K. J. SchulzGeology, geochemistry, and genesis of the Greens Creek massive sulfide deposit, Admiralty Island, southeastern Alaska
In 1996, a memorandum of understanding was signed by representatives of the U.S. Geological Survey and Kennecott Greens Creek Mining Company to initiate a cooperative applied research project focused on the Greens Creek massive sulfide deposit in southeastern Alaska. The goals of the project were consistent with the mandate of the U.S. Geological Survey Mineral Resources Program to maintain a leadAuthorsCliff D. Taylor, Craig A. JohnsonEvolution of Ore Deposits and Technology Transfer Project: Isotope and Chemical Methods in Support of the U.S. Geological Survey Science Strategy, 2003-2008
Principal functions of the U.S. Geological Survey (USGS) Mineral Resources Program are providing assessments of the location, quantity, and quality of undiscovered mineral deposits, and predicting the environmental impacts of exploration and mine development. The mineral and environmental assessments of domestic deposits are used by planners and decisionmakers to improve the stewardship of publicAuthorsRobert O. Rye, Craig A. Johnson, Gary P. Landis, Albert H. Hofstra, Poul Emsbo, Craig A. Stricker, Andrew G. Hunt, Brian G. RuskTesting the limits of Paleozoic chronostratigraphic correlation via high-resolution (<500 k.y.) integrated conodont, graptolite, and carbon isotope (δ13Ccarb) biochemostratigraphy across the Llandovery–Wenlock (Silurian) boundary: Is
The resolution and fidelity of global chronostratigraphic correlation are direct functions of the time period under consideration. By virtue of deep-ocean cores and astrochronology, the Cenozoic and Mesozoic time scales carry error bars of a few thousand years (k.y.) to a few hundred k.y. In contrast, most of the Paleozoic time scale carries error bars of plus or minus a few million years (m.y.),AuthorsBradley D. Cramer, David K. Loydell, Christian Samtleben, Axel Munnecke, Dimitri Kaljo, Peep Mannik, Tonu Martma, Lennart Jeppsson, Mark A. Kleffner, James E. Barrick, Craig A. Johnson, Poul Emsbo, Michael M. Joachimski, Torsten Bickert, Matthew R. SaltzmanNon-USGS Publications**
Riciputi, L.R., McSween, H.Y., Jr., Johnson, C.A., and Prinz, M., 1994, Minor and trace element concentrations in carbonates of carbonaceous chondrites, and implications for the compositions of coexisting fluids: Geochimica et Cosmochimica Acta, 58 (4), p. 1343–1351, https://doi.org/10.1016/0016-7037(94)90386-7.Johnson, C.A., and Prinz, M., 1993, Carbonate compositions in CM and CI chondrites, and implications for aqueous alteration: Geochimica et Cosmochimica Acta, 57 (12), p. 2843–2852, https://doi.org/10.1016/0016-7037(93)90393-B.Johnson, C.A., Cardellach, E., Tritlla, J., and Hanan, B.B., 1993, Origin of the Cierco Pb-Zn vein system (central Pyrenees, Spain): evidence from stable isotopes, Sr isotopes and fluid inclusions, in Fenoll Hach-Ali, P., Torrez-Ruiz, J., and Gervilla, F., eds., Current research in geology applied to ore deposits. Proceedings of the 2nd SGA Biennial Meeting, Granada, Spain, 9-11 September 1993, p. 135-138.Johnson, C.A., and Prinz, M., 1991, Chromite and olivine in type II chondrules in carbonaceous and ordinary chondrites: implications for thermal histories and group differences: Geochimica et Cosmochimica Acta, 55 (3), p. 893–904, https://doi.org/10.1016/0016-7037(91)90349-A.Johnson, C.A., Rye, D.M., and Skinner, B.J., 1990, Unusual oxygen isotopic compositions in and around the Sterling Hill and Franklin Furnace ore deposits, in Proceedings for conference on character and origin of the Franklin and Sterling Hill orebodies: Bethlehem, PA, Lehigh University, p. 63–76.Johnson, C.A., Rye, D.M., and Skinner, B.J., 1990, Petrology and stable isotope geochemistry of the metamorphosed zinc-iron-manganese deposit at Sterling Hill, New Jersey: Economic Geology, 85 (6), p. 1133–1161, https://doi.org/10.2113/gsecongeo.85.6.1133.Johnson, C.A., Prinz, M., Weisberg, M.K., Clayton, R.N., and Mayeda, T.K., 1990, Dark inclusions in Allende, Leoville and Vigarano: evidence for nebular oxidation of CV3 constituents: Geochimica et Cosmochimica Acta, 54 (3), p.819–830, https://doi.org/10.1016/0016-7037(90)90376-V.Skinner, B.J. and Johnson, C.A., 1987, Evidence for movement of ore materials during high grade metamorphism: Ore Geology Reviews, 2 (1-3), p. 191–204, https://doi.org/10.1016/0169-1368(87)90028-X.Johnson, C.A., Bohlen, S.R., and Essene, E.J., 1983, An evaluation of garnet-clinopyroxene geothermometry in granulites: Contributions to Mineralogy and Petrology, 84 (2-3), p. 191-198, https://doi.org/10.1007/BF00371285.Johnson, C.A., and Essene, E. J., 1982, The formation of garnet in olivine-bearing metagabbros in the Adirondack Mountains, New York: Contributions to Mineralogy and Petrology, 81 (3), p. 240-251, https://doi.org/10.1007/BF00371301.**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.
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