Export 2610 results:
Author Title [ Type(Asc)] Year
Journal Article
Z. A. Filatova, Thermophylic communities of deep-sea bottom fauna in rift zones of the Pacific Ocean, Oceanology, vol. 20, pp. 339–341, 1980.
Z. A. Filatova, On the thermophilic deep-sea bottom faunal communities of the Pacific Ocean rift zones, Oceanology, vol. 20, pp. 520–524, 1980.
B. B. Jorgensen, Zawacki, L. X., and Jannasch, H. W., Thermophilic bacterial sulfate reduction in deep-sea sediments at the Guaymas Basin hydrothermal vent site (Gulf of California), Deep-Sea Research. Part A, Oceanographic Research Papers, vol. 37, pp. 695–710, 1990.
J. F. Holden, Summit, M., and Baross, J. A., Thermophilic and hyperthermophilic microorganisms in 3–30°C hydrothermal fluids following a deep-sea volcanic eruption, FEMS Microbiology Ecology, vol. 25, pp. 33–41, 1998.
T. Holler, Widdel, F., Knittel, K., Amann, R., Kellermann, M. Y., Hinrichs, K. - U., Teske, A., Boetius, A., and Wegener, G., Thermophilic anaerobic oxidation of methane by marine microbial consortia, ISME JOURNAL, vol. 5, pp. 1946–1956, 2011.
G. W. Luther III, Findlay, A. J., MacDonald, D. J., Owings, S. M., Hanson, T. E., Beinart, R. A., and Girguis, P. R., Thermodynamics and kinetics of sulfide oxidation by oxygen: a look at inorganically controlled reactions and biologically mediated processes in the environment, FRONTIERS IN MICROBIOLOGY, vol. 2, 2011.
G. W. Luther, Findlay, A. J., MacDonald, D. J., Owings, S. M., Hanson, T. E., Beinart, R. A., and Girguis, P. R., Thermodynamics and kinetics of sulfide oxidation by oxygen: a look at inorganically controlled reactions and biologically mediated processes in the environment, Frontiers in Microbiology, vol. 2, p. 62, 2011.
A. Neuner, Jannasch, H. W., Belkin, S., and Stetter, K. O., Thermococcus litoralis sp. nov.: a novel species of extremely thermophilic marine archaebacteria, Archives of Microbiology, vol. 153, pp. 205–207, 1990.
E. E. Davis, LaBonte, A., He, J., Becker, K., and Fisher, A., Thermally stimulated ``runaway\''\} downhole flow in a superhydrostatic ocean crustal borehole: Observations, simulations, and inferences regarding crustal permeability}, JOURNAL OF GEOPHYSICAL RESEARCH-SOLID EARTH, vol. 115, 2010.
L. McKay, Klokman, V. W., Mendlovitz, H. P., LaRowe, D. E., Hoer, D. R., Albert, D., Amend, J. P., and Teske, A., Thermal and geochemical influences on microbial biogeography in the hydrothermal sediments of Guaymas Basin, Gulf of California, ENVIRONMENTAL MICROBIOLOGY REPORTS, vol. 8, pp. 150–161, 2016.
D. M. Karl, Burns, D., Orrett, K., and Jannasch, H. W., Themophilic microbial activity in samples from deep sea hydrothermal vents, Marine Biology Letters, vol. 5, pp. 227–231, 1984.
P. Blondel, Sempéré, J. C., Robigou, V., and Delaney, J. R., Textural analysis and geological mapping of high-resolution sonar images: Applications to Endeavour Segment, Juan de Fuca Ridge, EOS, Transactions, American Geophysical Union, vol. 74, p. 573, 1993.
A. M. Quattrini, Baums, I. B., Shank, T. M., Morrison, C., and Cordes, E. E., Testing the depth-differentiation hypothesis in a deepwater octocoral, Proceedings of the Royal Society B: Biological Sciences, vol. 282, p. 20150008, 2015.
H. L. Hunt, Metaxas, A., Jennings, R. L., Halanych, K. M., and Mullineaux, L. S., Testing biological control of colonization by vestimentiferan tubeworms at deep-sea hydrothermal vents (East Pacific Rise, 9 degrees 50'N), Deep-Sea Research. Part I: Oceanographic Research Papers, vol. 51, pp. 225–234, 2004.
K. Mitsuzawa, Sugawara, T., Nakamura, K., Urabe, T., and Fujioka, K., Ten-days observation period on a low-temperature hydrothermal field at the Southern East Pacific Rise, JAMSTEC Journal of Deep Sea Research, pp. 79–90, 1999.
J. W. Mavor, Ten months with Alvin, Geomarine Technology, vol. 2, pp. 8–18, 1966.
D. J. Fornari, Perfit, M. R., Smith, M., Haymon, R. M., Edwards, M. H., Cochran, J. R., Coakely, B., Von Damm, K. L., and Lilley, M., Temporal variation in the morphology and structure of the axial summit caldera and young volcanic flows, and relationship to hydrothermal venting on the East Pacific Rise crest 9 30-51'N, EOS, Transactions, American Geophysical Union, vol. 75, p. 618, 1994.
S. E. Beaulieu and Baldwin, R., Temporal variability in currents and the benthic boundary layer at an abyssal station off central California, Deep-Sea Research. Part II: Topical Studies in Oceanography, vol. 45, pp. 587–615, 1998.
M. Yuecel and Luther, G. W., Temporal trends in vent fluid iron and sulfide chemistry following the 2005/2006 eruption at East Pacific Rise, 9 degrees 50 ' N, Geochemistry, Geophysics, Geosystems, vol. 14, pp. 759–765, 2013.
S. Hirano, Ogawa, Y., Yujiro, F., Fujioka, K., and Kawamura, K., Temporal changes of cracks in the oceanward slope of northern Japan Trench off Sanriku: Six-year observation by submersibles, JAMSTEC Journal of Deep Sea Research, pp. 445–454, 1999.
R. R. Hessler, Smithey, W. M., Boudrias, M. A., Keller, C. H., Lutz, R. A., and Childress, J. J., Temporal change in megafauna at the Rose Garden hydrothermal vent (Galapagos Rift; eastern tropical Pacific), Deep-Sea Research. Part A, Oceanographic Research Papers, vol. 35, pp. 1681–1710, 1988.
M. Sheader and Van Dover, C. L., Temporal and spatial variation in the reproductive ecology of the vent-endemic amphipod Ventiella sulfuris in the eastern Pacific, Marine Ecology Progress Series, vol. 331, pp. 181–194, 2007.
R. W. Lee, Robert, K., Matabos, M., Bates, A. E., and Juniper, S. K., Temporal and spatial variation in temperature experienced by macrofauna at Main Endeavour hydrothermal vent field, Deep-Sea Research Part I: Oceanographic Research Papers, vol. 106, pp. 154–166, 2015.
G. J. Massoth, Baker, E. T., Lupton, J. E., Feely, R. A., Butterfield, D. A., Von Damm, K. L., Roe, K. K., and Lebon, G. T., Temporal and spatial variability of hydrothermal manganese and iron at Cleft segment, Juan de Fuca Ridge, Journal of Geophysical Research, vol. 99, pp. 4905–4923, 1994.
M. A. Pollock, Klein, E. M., Karson, J. A., and Tivey, M. A., Temporal and spatial variability in the composition of lavas exposed along the Western Blanco Transform Fault, Geochemistry, Geophysics, Geosystems, vol. 6, p. Q11009, 2005.

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