reading_list - Deep Carbon Observatory

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Yellowstone National Park References of Interest:
Boyd, E. S., K. M. Fecteau, J. R. Havig, E. L. Shock, and J. W. Peters. (2012) Modeling the
habitat range of phototrophic microorganisms in Yellowstone National Park: Toward the
development of a comprehensive fitness landscape. Frontiers in Microbiology Submitted.
Chang, W. L. Smith, R.B. Wicks, C. Farrell, J. and Puskas, C.M. (2007) Accelerated uplift and
magmatic intrusion of the Yellowstone caldera, 2004 to 2006, Science 318, 952–956.
Chang, W.-L., R. B. Smith, J. Farrell, and C. M. Puskas (2010) An extraordinary episode of
Yellowstone caldera uplift, 2004–2010, from GPS and InSAR observations, Geophysical
Research Letters 37, L23302.
Christiansen, R. L., Lowenstern, J. B., Smith, R. B., Heasler, H., Morgan, L. A., Nathenson, M.,
Mastin, L.G., Muffler, L., and Robinson, J.E. (2007) Preliminary assessment of volcanic and
hydrothermal hazards in Yellowstone National Park and vicinity: USGS Open File Report
2007-1071.
Evans, W. C., Bergfeld, D., McGeehin, J. P., King, J. C., and Heasler, H. (2010) Tree-ring 14C
links seismic swarm to CO2 spike at Yellowstone, USA. Geology 38, 1075-1078.
Fournier, R. O. (1989) Geochemistry and dynamics of the Yellowstone National Park
hydrothermal system. Annual Review of Earth and Planetary Sciences 17, 13-53.
Friedman, I., and Norton D. R. (2007) Is Yellowstone losing its steam? Chloride flux out of
Yellowstone National Park. In: Morgan, L.A., (Ed.), Integrated geoscience studies in the
Greater Yellowstone Area: Volcanic, Hydrothermal and tectonic processes in the
Yellowstone Geoecosystem, U.S. Geologic Survey Professional Paper 1717, 275-297.
Hamilton, T. L., Vogl, K., Bryant, D. A., Boyd, E. S., and Peters, J. W. (2012) Environmental
constraints defining the distribution, composition, and evolution of chlorophototrophs in
thermal features of Yellowstone National Park. Geobiology 10, 236–249.
Hamilton, T. L., Lange, R. K., Boyd, E. S., and Peters, J. W. (2011) Biological nitrogen fixation in
acidic high-temperature geothermal springs in Yellowstone National Park, Wyoming.
Environmental Microbiology 13, 2204-2215.
Hildreth, W., and Halliday, A.N. (1991) Isotopic and chemical evidence concerning the genesis
and contamination of basaltic and rhyolitic magma beneath the Yellowstone Plateau
volcanic field. Journal of Petrology 32, 63–138.
Hurwitz, S., Kumar, A., Taylor, R., and Heasler, H. (2008) Climate-induced variations of geyser
periodicity in Yellowstone National Park, USA. Geology 36, 451-454.
Hurwitz, S., Harris, R.N., Werner, C.A., and Murphy, F. (2012) Heat flow in vapor dominated
areas of the Yellowstone Plateau Volcanic Field: Implications for the thermal budget of the
Yellowstone Caldera. Journal of Geophysical Research. 117, B10207.
Inskeep, W. P., Jay, Z. J., Herrgard, M. J., Kozubal, M. A., Rusch, D. B., Tringe, S. G., Macur,
R. E., Jennings, R. deM., Boyd, E. S., Spear, J. R., and Roberto, F. F. (2013) Phylogenetic
and functional analysis of metagenome sequence from high-temperature archaeal habitats
demonstrate linkages between metabolic potential and geochemistry. Frontiers in
Microbiology 4:95, 1-21.
Lowenstern, J.B. Bergfeld, D. Evans, W.C. and Hurwitz, S. (2012) Generation and evolution of
hydrothermal fluids at Yellowstone: Insights from the Heart Lake Geyser Basin.
Geochemistry, Geophysics, Geosystems 13, Q01017.
Meyer-Dombard, D.R. Shock, E.L. and Amend, J.P. (2005) Archaeal and bacterial communities
in geochemically diverse hot springs of Yellowstone National Park, USA. Geobiology 3, 211227.
Morgan, L.A., (Ed.), (2007) Integrated geoscience studies in the Greater Yellowstone Area:
Volcanic, Hydrothermal and tectonic processes in the Yellowstone Geoecosystem, U.S.
Geologic Survey Professional Paper 1717.
Morgan, L. A., Shanks III, W. C pat and Pierce, K. L. (2009) Hydrothermal processes above the
Yellowstone Magma chamber: large hydrothermal systems and large hydrothermal explosions.
Geol. Soc. Amer. Spec. Paper 459.
Nordstrom, D.K. McCleskey, R.B. and Ball, J.W. (2009) Sulfur geochemistry of hydrothermal
waters in Yellowstone National Park: IV Acid-sulfate waters. Applied Geochemistry 24, 191207.
Pritchard, C. J., and Larson, P. B. (2012) Genesis of the post-caldera eastern Upper Basin
Member rhyolites, Yellowstone, WY: from volcanic stratigraphy, geochemistry, and
radiogenic isotope modeling. Contributions to Mineralogy and Petrology 164, 205–228.
Shock, E.L. Holland, M. Meyer-Dombard, D. Amend, J.P. Osburn, G.R. and Fischer, T.P. (2010)
Quantifying inorganic sources of geochemical energy in hydrothermal ecosystems,
Yellowstone National Park, USA. Geochimica et Cosmochimica Acta 74, 4005-4043.
Shock, E.L. Holland, M. Meyer-Dombard, D.R. and Amend, J.P. (2005) Geochemical sources of
energy for microbial metabolism in hydrothermal ecosystems: Obsidian Pool, Yellowstone
National Park, USA, in: Inskeep, W. McDermott, T. (Eds.), Geothermal Biology and
Geochemistry in Yellowstone National Park. Thermal Biology Institute, Montana State
University, pp. 95-112.
Swingley, W. D., Meyer-Dombard, D. R., Shock, E. L., Alsop, E. B., Falenski, H. D., Havig, J. R.,
and Raymond, J. (2012) Coordinating environmental genomics and geochemistry reveals
metabolic transitions in a hot spring ecosystem. PLoS ONE 7, e38108 1-15.
Vazquez, J. A., and Reid, M. R. (2002) Time scales of magma storage and differentiation of
voluminous high-silica rhyolites at Yellowstone caldera, Wyoming. Contributions to
Mineralogy and Petrology 144, 274–285.
White, D. E., R. O. Fournier, L., Muffler, J. P., and Truesdell, A. H. (1975) Physical results of
research drilling in Yellowstone National Park, Wyoming. USGS Professional Paper 892.
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