{"id":20,"date":"2015-01-11T19:09:24","date_gmt":"2015-01-12T03:09:24","guid":{"rendered":"http:\/\/faculty.epss.ucla.edu\/~ttreude\/?page_id=20"},"modified":"2026-04-16T10:56:51","modified_gmt":"2026-04-16T18:56:51","slug":"publications","status":"publish","type":"page","link":"https:\/\/faculty.epss.ucla.edu\/~ttreude\/?page_id=20","title":{"rendered":"Publications"},"content":{"rendered":"
\n

\"snoopy<\/a><\/h3>\n

Visit my Google Scholar Page<\/a> for further\u00a0information<\/h3>\n

Peer-reviewed Journal Articles and Book Chapters<\/h3>\n

(underlined authors<\/span> highlight\u00a0students or postdocs from my group)<\/p>\n<\/div>\n

——<\/b>\u00a0submitted\/accepted ——<\/b><\/h3>\n

97.<\/strong> Scott, P., Cockell, C., \u00a0Fischer, W., Sharma, S., Lloyd, K., Wilhelm, Mary, B. \u00a0Corsetti, F., Treude, T.<\/strong>, Leadbetter, J., Giovannelli, D., \u00a0Foreman, C., \u00a0Freedman, K., \u00a0Lynch, K., \u00a0Homann, M., \u00a0Som, S., \u00a0Wilson, L., Karunatillake, S., \u00a0Drake, H., \u00a0Bywaters, K., \u00a0Mikucki, J., \u00a0Celestian, A., \u00a0Chen, P., \u00a0Guan, L., Ibarra, Y., \u00a0Boland, J., \u00a0Hossieini, S., \u00a0Tosi, P., \u00a0Nisson, D., \u00a0Murphy, A., \u00a0Garner, M., Thei, F., \u00a0Biondi, M., \u00a0Propster, P. (submitted) Biological Validation and Agnostic Experiments for Extant and Extinct Microbial Life within the Martian Subsurface, Astrobiology<\/p>\n

96. <\/strong>Raven, M.R., Amiel, N., Angel, D.L., Barry, J.P., Blattmann, T.M., Boicenco, L., Cr\u00e9mi\u00e8re, A., Evans, N., Gallarotti, N., Haas, S., \u00a0Hehemann, J.-H., Lal, P., Lordkipanidze, D., Luostarinen, T., Martinez, A.M., \u00a0Matzelle, A.J., Menabit, S., Muresan, M., Neumann, A., \u00a0Paris, J.-D., Pearce, C.R., Reynard, N., Sanchez, D.L., \u00a0Schubotz, F., Slabakova, V., \u00a0Stanica, A., Sweetman, A.K., Treude, T.<\/strong>, Voynova, Y.G., and Zarokanellos D.N. (in revision) Max MACS \u2013 constraining the potential global scale of Marine Anoxic Carbon Storage for CO2 removal, EGUsphere\/Biogeosciences,<\/p>\n

95.<\/strong> Klonicki-Ference, E., <\/u>Waters, T., Jones, C., Hung, C., \u00a0Diamond, C., McCormick, M. , Lyons, T.,Treude, T.<\/strong> \u00a0(in prep for re-submission) Microbial Redox Cycling Sustains Euxinia and Limits Methane Escape in a Proterozoic Ocean Analog<\/p>\n

94.<\/strong> Yousavich, D.J.<\/u>, Diamond, C., Hung, C., Vetushko, G.<\/u>, Xuefeng, P., Lyons, T., Treude, T.<\/strong> (in revision) Microbial Metabolisms in the Salton Sea: Responses to Seasonal Anoxia in a Rapidly Drying Inland Lake, Great Lakes Research<\/em><\/p>\n

93.<\/strong> Robinson, D.,<\/u> Schulterbrandt Gragg III, R., Bianchi, D.,
\nTreude, T.<\/strong> (in revision) Addressing Ocean Deoxygenation in the Biodiversity Beyond National Jurisdiction Agreement: Opportunities for Science, Scale Governance & Management. Frontiers<\/em><\/p>\n

——\u00a0published ——<\/b><\/h3>\n

92.<\/strong> Robinson, D.<\/u>, Bianchi, D., Liu, N., \u00a0Valentine, D.L., \u00a0Treude, T.<\/strong> (2026) Spatial Distribution and Temporal Variability of Dissolved O2 in the Santa Barbara Channel and Basin, California, JGR-Oceans, 131, e2025JC022779, https:\/\/doi.org\/10.1029\/2025JC022779<\/em><\/p>\n

91.<\/strong> Krause, S.J.E.,<\/u> Wipfler, R., Liu, J., Yousavich, D.J., \u00a0Robinson, D.<\/u>, Hoyt, D.W., Orphan, V.J., \u00a0Treude, T.<\/strong> (2025) Spatial evidence of cryptic methane cycling and methylotrophic metabolisms along a land-ocean transect in a southern California salt marsh, Geochim. Cosmochim. Acta, <\/em>404, 53-71<\/p>\n

90.<\/strong> Liu, J.,<\/u> Young, E.D., Pellerin, A., Ash, J.L., Barrett, G.T., Feng, X., Girguis, P.R., Krause, S.J.E.<\/u>, Leavitt, W.D., Murphy, K., Qin, Q., Sivan, O., Teske, A.P., Valentine, D.L., Walter Anthony, K.M., Treude, T.<\/strong> (2025) Clumped isotopes of methane trace bioenergetics in the environment, Science Advances, <\/em>11, DOI: 10.1126\/sciadv.adu1401<\/p>\n

89.<\/strong> Liu, J., Klonicki-Ference, E., Krause, S.J.E.,<\/u> Treude, T.<\/strong> (2025) Iron oxides fuel anaerobic oxidation of methane in the presence of sulfate in hypersaline coastal wetland sediment, Environmental Science & Technology, https:\/\/doi.org\/10.1021\/acs.est.4c10639<\/em><\/p>\n

88.<\/strong> Peng, X., Yousavich, D.J.<\/u>, Bourbonnais, A., Wenzhoefer, F., Janssen, F., Treude, T.<\/b>, Valentine, D.L.: The fate of fixed nitrogen in Santa Barbara Basin sediments during seasonal anoxia (2024): Biogeosciences, 21, 3041\u20133052<\/p>\n

87.<\/strong> Lindsay, M.R., \u00a0D’Angelo, T., Munson-McGee, J.H., \u00a0Saidi-Mehrabad, A., Devlin, M., McGonigle, J., Goodell, E., Herring, M., Lubelczyk, L., Mascena, C., Brown, J., Gavelis, G., Liu, J., Yousavich, D.J.,<\/u> Hamilton-Brehm, S.D., Hedlund, B., Lang, S.Q., Treude, T.<\/strong>, Poulton, N.J., Stepanauskas, R., Moser, D.P., Emerson, D., Orcutt, B.N. (2024): Species-resolved, single-cell respiration rates reveal dominance of sulfate reduction in a deep continental subsurface ecosystem, PNAS, <\/em>121 (15), DOI: 10.1073\/pnas.230963612<\/p>\n

86. <\/strong>Yousavich, D. J., Robinson, D.,<\/u> Peng, X., Krause, S. J. E.,<\/u> Wenzhoefer, F., Jan\u00dfen, F., Liu, N., Tarn, J., Kinnaman, F., Valentine, D. L., and Treude, T. <\/strong>(2024): Marine anoxia initiates giant sulfur-bacteria mat proliferation and associated changes in benthic nitrogen, sulfur, and iron cycling in the Santa Barbara Basin, California Borderland, Biogeosciences, 21, 789\u2013809, https:\/\/doi.org\/10.5194\/bg-21-789-2024<\/p>\n

85.<\/strong> Robinson, D.<\/u>, \u00a0Pham, A.L.D., Yousavich, D.J., Janssen, F., Wenzh\u00f6fer, F., Arrington, E.C., Gosselin, E.M., Sandoval-Belmar, M., Mar, M., Valentine, D.L., Bianchi, D., Treude, T. <\/strong>(2024): Iron \u201cOre\u201d Nothing: Benthic iron fluxes from the oxygen-deficient Santa Barbara Basin enhance phytoplankton productivity in surface waters, Biogeosciences, 21, 773\u2013788, https:\/\/doi.org\/10.5194\/bg-21-773-2024<\/p>\n

84.<\/strong> Liu, L.<\/u>, Treude, T.<\/strong>, Abbasov, O., Baloglanov, E., Aliyev, A., Harris, C., \u00a0Leavitt, W., and Young, E. (2024): Clumped isotope evidence for microbial alteration of thermogenic methane in terrestrial mud volcanoes, Geology, <\/em>DOI https:\/\/doi.org\/10.1130\/G51667.1<\/p>\n

83.<\/strong> Krause, S.J.E, Liu, L., Yousavich, D.J., Robinson,<\/u> D., Hoyt, D., Qin, Q., Wenzh\u00f6fer, F., Janssen, F., Valentine, D, Treude, T. <\/strong>(2023): Evidence of cryptic methane cycling and non-methanogenic methylamine consumption in the sulfate-reducing zone of sediment in the Santa Barbara Basin, California. Biogeosciences, 20(20), pp.4377-4390.<\/p>\n

82.<\/strong> Liu, J.<\/u>, Harris, R.J., Ash, J.L., Ferry, J.G., Labidi, J.,\u00a0Krause, S.J.E.<\/u>, \u00a0Prakash, D., Sherwood Lollar, B., Treude, T.<\/strong>,\u00a0Warr, O., Young, E.D. (2023): Reversibility controls on extreme methane clumped isotope signatures from anaerobic oxidation of methane. Geochim. Cosmochim. Acta,<\/em> 348, 165-186<\/p>\n

81. <\/strong>Figueroa, M.C., S. van de Velde, S. Lemieux, J. Drake<\/u>, T, Treude<\/strong>, N. Kemnitz, W. Berelson, D.D. Gregory, K. Choumiline, S. Bates, R. Kukkadapu, M. Fogel, N. Riedinger, T.W. Lyons (2023): Early Diagenetic Processes in an Exceptionally Iron-Dominated Marine Depositional System: The Santa Monica Basin, California, Geochim. Cosmochim. Acta, <\/em>341, 183-199<\/p>\n

80.<\/strong> Melaniuk, K., Sztybor, K., Treude, T.<\/strong>, Sommer, S., Zaj\u0105czkowski, M. and Rasmussen, T.L. (2022): Response of benthic foraminifera to environmental successions of cold seeps from Vestnesa Ridge, Svalbard: Implications for interpretations of paleo-seepage environments. Frontiers in Marine Science, 9, p.999902.<\/p>\n

79. Treude, T. <\/strong>(2022): Vertebrates-skate\/shark egg capsules. In Kaim, A., Cochran, J.K., and Landman, N.H. (eds.). Ancient Hydrocarbon Seeps. Topics in Geobiology, Vol. 50, p. 419-421, Springer, Cham, Switzerland.<\/p>\n

78.\u00a0<\/strong>Qin, Q., Kinnaman, F.S., Gosselin, K.M., Liu, N., Treude, T.<\/strong>, Valentine, D.L. (2022): Seasonality of Water Column Methane Oxidation and Deoxygenation in a Dynamic Marine Environment, Geochim. Cosmochim. Acta, 336,\u00a0<\/em>219\u2013230<\/span><\/p>\n

77. <\/strong>Krause, S.J.E., Liu, J.,<\/u> Young, E.D., Treude, T.<\/strong> (2022): \u25b313CH3D and \u25b312CH2D2 signatures of aerobic oxidation of methane by Methylosinus trichosporium<\/em>, EPSL, 593, 117681, https:\/\/doi.org\/10.1016\/j.epsl.2022.117681<\/em><\/p>\n

76.<\/strong> Beulig, F., Schubert, F., Adhikari, R.R., Glombitza, C., Heuer, V.B., Hinrichs, K.-U., Homola, K.L., Inagaki, F., J\u00f8rgensen, B.B., Kallmeyer, J., Krause, S.J.E.<\/u>, Morono, Y., Sauvage, J., Spivack, A.J., Treude, T.<\/strong> (2022): Rapid metabolism fosters microbial survival in the deep, hot, subseafloor biosphere, Nature Comm., 3: 312, 10.1038\/s41467-021-27802-7<\/em><\/p>\n

75.<\/strong> Melaniuk, K., Sztybor, K., \u00a0Treude, T.<\/strong>, Sommer, S., Rasmussen, T.L. (2022): Evidence for influence of methane seepage on isotopic signatures in living deep-sea foraminifera, 79 \u00b0N. Sci. Rep. 12:1169, https:\/\/doi.org\/10.1038\/s41598-022-05175-1<\/em><\/p>\n

74. <\/strong>Jordan, S.F.A., Gr\u00e4we, U., Treude, T.<\/strong>, van der Lee, E.M., Schneider von Deimling, J., Rehder, G., \u00a0Schmale, O. (2021): Pelagic methane sink enhanced by benthic methanotrophs ejected\u00a0from a gas seep. GRL <\/em>https:\/\/doi.org\/10.1029\/2021GL094819<\/p>\n

73.<\/strong> Treude, T.<\/strong>, L. Hamdan, S. Lemieux<\/u>, A.W. Dale, S. Sommer (2021): Rapid sulfur cycling in sediments from the Peruvian oxygen minimum zone featuring simultaneous sulfate reduction and sulfide oxidation. Limn. Oceanogr. 66<\/em>, 2661\u20132671, doi: 10.1002\/lno.11779<\/p>\n

72<\/strong>. Krause, S.J.E<\/u>, T. Treude<\/strong> (2021): Deciphering cryptic methane cycling: Coupling of methylotrophic methanogenesis and anaerobic oxidation of methane in hypersaline coastal wetland sediment. Geochim. Cosmochim. Acta <\/em>302, 160-174 \u00a0https:\/\/doi.org\/10.1016\/j.gca.2021.03.021<\/em><\/p>\n

71<\/strong><\/em>.\u00a0<\/strong>Fichtner, V., S. Lange<\/u>, T. Huthwelker, C. Borca, S. Krause<\/u>, A. Immenhauser, S. Schurr, T. Treude<\/strong>, A. Erhardt, C. Pederson, H. Strauss\u00a0(2021):\u00a0Microbial activity affects sulfur in biogenic aragonite. The Depositional Record, <\/em>DOI: 10.1002\/dep2.133<\/p>\n

70.<\/strong> Heuer, V.B., F. Inagaki, Y. Morono, Y. Kubo, A. J. Spivack,B. Viehweger, T. Treude<\/strong>, F. Beulig, F. Schubotz, S. Tonai, S. A. Bowden, M. Cramm, S. Henkel, T. Hirose, K. Homola, T. Hoshino, A. Ijiri, H. Imachi, N. Kamiya, M. Kaneko, L. Lagostina, H. Manners, H.-L. McClelland, K. Metcalfe, N. Okutsu, D. Pan, M. J. Raudsepp, J. Sauvage, M.-Y. Tsang, D. T. Wang, E. Whitaker, Y. Yamamoto, K. Yang, L. Maeda, R. Adhikari, C. Glombitza, Y. Hamada, J. Kallmeyer, J. Wendt, L. W\u00f6rmer, Y. Yamada, M. Kinoshita, K.-U. Hinrichs (2020): Temperature limits to deep subseafloor life in the Nankai Trough subduction zone. Science 370,\u00a01230\u20131234<\/p>\n

69.<\/strong> Wilson, S. T., Al-Haj, A. N., Bourbonnais, A., Frey, C., Fulweiler, R. W., Kessler, J. D., Marchant, H. K., Milucka, J., Ray, N. E., Suntharalingham, P., Thornton, B. F., Upstill-Goddard, R. C., Weber, T. S., Ar\u00e9valo-Mart\u00ednez, D. L., Bange, H. W., Benway, H. M., Bianchi, D., Borges, A. V., Chang, B. X., Crill, P. M., del Valle, D. A., Far\u00edas, L., Joye, S. B., Kock, A., Labidi, J., Manning, C. C., Pohlman, J. W., Rehder, G., Sparrow, K. J., Tortell, P. D., Treude, T<\/strong>., Valentine, D. L., Ward, B. B., Yang, S., and Yurganov, L. N. (2020): Ideas and perspectives: A strategic assessment of methane and nitrous oxide measurements in the marine environment, Biogeosciences 17, 5809-5828 https:\/\/doi.org\/10.5194\/bg-2020-270<\/p>\n

68. <\/strong>Kemnitz, N., W. Berelson, D. Hammond, L. Morine, M. Figueroa, T. Lyons, S. Scharf, N. Rollins, E. Petsios, S. Lemieux<\/u>, T. Treude<\/strong> (2020): Evidence of Changes in Sedimentation Rate and Sediment Fabric in a Low Oxygen Setting: Santa Monica Basin, CA. Biogeosciences 17, 2381\u20132396, https:\/\/doi.org\/10.5194\/bg-17-2381-2020<\/p>\n

67. Treude, T.<\/strong>, S. Krause<\/u>, L. Steinle<\/u>, E. Burwicz, L.J. Hamdan, H. Niemann, T. Feseker, V. Liebetrau, S. Krastel, C. Berndt (2020): Biogeochemical consequences of non-vertical methane transport in sediment offshore\u00a0northwestern Svalbard. JGR Biogeosciences\u00a0<\/em>125, e2019JG005371. https:\/\/doi.org\/ 10.1029\/2019JG005371<\/p>\n

66. <\/strong>Jordan, S.F.A., T. Treude<\/strong>, I. Leifer, R. Jan\u00dfen, J. Werner, H. Schulz-Vogt, O. Schmale (2020): Bubble-mediated transport of benthic microorganisms into the water column:\u00a0Identification of methanotrophs and implication of seepage intensity on\u00a0transport efficiency. Scientific Reports 10:4682<\/em><\/p>\n

65.\u00a0<\/strong>Ash, J.L., \u00a0M. Egger, T. Treude<\/strong>, I. Kohl, B. Cragg, R. J. Parkes, C.P. Slomp, B. Sherwood Lollar, E.D. Young (2019): Exchange catalysis during anaerobic methanotrophy revealed by 12<\/sup>CH2<\/sub>D2<\/sub> and 13<\/sup>CH3<\/sub>D in methane.<\/strong>\u00a0Geochem. Persp. Let. <\/em>10, 26-30<\/p>\n

64.<\/strong> Krause, S.,<\/span>\u00a0V. Liebetrau, C. R. L\u00f6scher, F. B\u00f6hm, S. Gorb, A. Eisenhauer, <\/span>T. Treude<\/strong> (2018): Marine ammonification and carbonic anhydrase activity induce rapid calcium carbonate precipitation. <\/span>Geochim. Cosmochim. Acta.<\/em> 243, 116-132<\/span><\/p>\n

63.\u00a0<\/strong>Steinle, L.<\/span>, \u00a0K. Knittel, N. Felber, C. Casalino, G. de Lange, C. Tessarolo, A. Stadniskaia, J.S. Sinninghe Damst\u00e9, J. Zopfi, M.F. Lehmann, T. Treude<\/strong>, H. Niemann (2018):\u00a0Life on the edge: Active microbial communities within the Kryos MgCl2<\/sub>-brine basin at very low water activity. ISME Journal\u00a0<\/em>12, 1414\u20131426<\/p>\n

62.<\/strong> Lange, S.M<\/span>.,\u00a0S. Krause<\/span>, A.-C. Ritter, V. Fichtner,\u00a0<\/span>\u00a0A. Immenhauser, H. Strau\u00df, T. Treude<\/strong> (2018):\u00a0<\/strong>Anaerobic microbial activity affects early diagenetic pathways of bivalve shells. Sedimentology.\u00a0<\/em>doi: 10.1111\/sed.12428<\/p>\n

61.<\/strong> Maltby, J.<\/span>, , L. Steinle<\/span>, C. R. L\u00f6scher, H. W. Bangea, M. A. Fischer, M. Schmidt, T. Treude<\/strong> (2018): Microbial methanogenesis in the sulfate-reducing zone in sediments from Eckernf\u00f6rde Bay, SW Baltic Sea. Biogeosciences<\/em> 15, 137\u2013157.<\/p>\n

60.<\/strong>\u00a0Heuer, V.B., F.Inagaki, Y. Morono, Y. Kubo, L. Maeda, S. Bowden, M. Cramm, S. Henkel, T. Hirose, K. Homola, T. Hoshino, A. Ijiri, H. Imachi, N. Kamiya, M. Kaneko, L. Lagostina, H. Manners, H.L. McClelland, K. Metcalfe, N. Okutsu, D. Pan, M.J. Raudsepp, J. Sauvage, F. Schubotz, A. Spivack, S. Tonai, T. Treude<\/strong>, M.Y. Tsang, B. Viehweger, D.T. Wang, E. Whitaker, Y. Yamamoto, K. Yang (2017):\u00a0Expedition 370 summary. Proceedings of the International Ocean Discovery Program 370. \u00a0doi:10.14379\/iodp.proc.370.101.2017<\/p>\n

59<\/strong>. Krause, S.<\/span>, \u00a0H. Niemann,\u00a0T. Treude<\/strong>\u00a0(2017): Methane Seeps in a Changing Climate\u00a0(pp 1-32), In:\u00a0Kallmeyer, J. (Ed.). Life at Vents and Seeps. Berlin, Boston: De Gruyter.<\/p>\n

58.<\/strong>\u00a0Gier J.<\/span>, C.R. L\u00f6scher, A.W. Dale, S. Sommer, U. Lomnitz, T. Treude<\/strong> \u00a0(2017): Benthic dinitrogen fixation traversing the oxygen minimum zone off Mauritania (NW Africa). Front. Mar. Sci.<\/em> 4:390. doi: 10.3389\/fmars.2017.00390<\/p>\n

57.<\/strong> Stagars, M., \u00a0S. Mishra<\/span>, T. Treude<\/strong>, R. Amann, \u00a0K. Knittel (2017):\u00a0Microbial community response to simulated petroleum seepage in Caspian Sea sediments. Frontiers in Microbiology\u00a0Frontiers in Microbiology <\/i>(8) 764, <\/i>doi: 10.3389\/fmicb.2017.00764<\/p>\n

56.<\/strong> Mishra, S<\/span>, \u00a0P. Wefers , M. Schmidt, K. Knittel, M. Kr\u00fcger, M. Stagars, and T. Treude<\/strong> (2017):\u00a0Hydrocarbon degradation in Caspian Sea sediment cores subjected to simulated petroleum seepage in a newly designed sediment-oil-flow-through system.\u00a0Frontiers in Microbiology (<\/i>8) 763\u00a0doi: 10.3389\/fmicb.2017.00763<\/p>\n

55.\u00a0<\/span><\/strong>Steinle, L.<\/span>, J. Maltby<\/span>, T. Treude<\/strong>, A. Kock, H. W. Bange, N. Engbersen, J. Zopfi, M. F. Lehmann, H. Niemann (2017): \u00a0Effects of low oxygen concentrations on aerobic methane oxidation in seasonally hypoxic coastal waters. Biogeosciences\u00a0<\/em>14, 1631\u20131645<\/p>\n

54.\u00a0<\/strong>Steinle, L<\/span>., M. Schmidt, L. Bryant, M. Haeckel, P. Linke, S. Sommer, J. Zopfi, M. F. Lehmann,\u00a0T. Treude<\/strong>, H. Niemann (2016): Linked sediment and water-column methanotrophy at a man-made gas blowout in the North Sea: Implications for methane budgeting in seasonally stratified shallow seas.\u00a0Limnol. Oceanogr. 61,\u00a0<\/em>S367\u2013S386<\/p>\n

53.<\/strong>\u00a0Gier, J.<\/span>\u00a0, S. Sommer, C.R. L\u00f6scher, A.W. Dale, R.A. Schmitz,\u00a0T. Treude<\/strong>\u00a0(2016):\u00a0Nitrogen fixation in sediments along a depth transect through the Peruvian oxygen minimum zone.\u00a0Biogeosciences\u00a0<\/em>13,\u00a04065-4080<\/p>\n

52.<\/strong>\u00a0<\/strong><\/strong><\/strong><\/strong><\/b><\/b><\/b><\/b><\/b>Sommer, S., J. Gier<\/span>, T. Treude<\/strong>, <\/strong><\/strong><\/strong><\/strong><\/b><\/b><\/b><\/b><\/b>U. Lomnitz, M. Dengler, J. Cardich, A. W. Dale (2016):\u00a0Depletion of oxygen, nitrate and nitrite in the Peruvian oxygen minimum zone cause an imbalance of benthic nitrogen fluxes. Deep Sea Res. I, <\/em>112, 113-122<\/p>\n

51.<\/strong>\u00a0<\/strong><\/strong><\/strong><\/b><\/b><\/b><\/b><\/b>James, R.H., \u00a0P. Bousquet, I. Bussmann, M. Haeckel, R. Kipfer, I. Leifer, \u00a0H. Niemann, I. Ostrosky, J. Piskozub, G. Rehder, T. Treude<\/strong>, L. Vielst\u00e4dte, and J. Greinert (2016):\u00a0Effects of climate change on methane emissions from seafloor sediments in the Arctic Ocean: A review. Limnol. Oceanogr.\u00a066,\u00a0S283\u2013S299 <\/em><\/p>\n

50.<\/strong> <\/strong><\/strong><\/b><\/b><\/b><\/b><\/b>Jim\u00e9nez, N., H.H. Richnow, C. Vogt, T. Treude<\/strong>, <\/strong><\/strong><\/b><\/b><\/b><\/b><\/b>M. Kr\u00fcger (2016):\u00a0Methanogenic hydrocarbon degradation: evidence from field and laboratory studies.\u00a0J. Mol. Microbiol. Biotech., <\/em>26 (1-3), 227-242 (Special Issue: Anaerobic Hydrocarbon Degradation)<\/em><\/p>\n

49.<\/strong> <\/strong><\/b><\/b><\/b><\/b><\/b>Nauendorf, A<\/span>., \u00a0S. Krause<\/span>, N.K. Bigalke, E.V. Gorb, S.N. Gorb, M. Haeckel, M. Wahl, T. Treude<\/strong> (2016):\u00a0Microbial colonization and degradation of polyethylene and biodegradable plastic bags in temperate fine-grained organic-rich marine sediments. Marine Pollution Bulletin,<\/em> 103, 168-178<\/p>\n

48.<\/strong>\u00a0\u00a0<\/b><\/b><\/b><\/b><\/b>Maltby, J.,<\/span> \u00a0S. Sommer, A.W. Dale, and T. Treude<\/strong> (2016):\u00a0Microbial methanogenesis in the sulfate-reducing zone of surface sediments traversing the Peruvian margin. Biogeosciences\u00a0<\/em>13, 283\u2013299<\/p>\n

47. <\/b><\/b><\/b><\/b><\/b>Liebenau, K., S. Kiel, D. Vardeh<\/span>, T. Treude<\/strong>, V. Thiel (2015): \u00a0A quantitative study on the degradation of whale bone lipids: implications for the preservation of fatty acids in marine sediments.\u00a0Org. Geochem. <\/em>89-90, 23-30<\/p>\n

46.<\/b><\/b><\/b><\/b><\/b>\u00a0Wilfert, P., S. Krause, <\/span>V. Liebetrau, J. Sch\u00f6nfeld, M. Haeckel, P. Linke,\u00a0T. Treude<\/strong>\u00a0(2015): Response of anaerobic methanotrophs and benthic foraminifera on 20 years of methane emission from a gas blowout in the North Sea. J.<\/em>\u00a0Mar. Petrol. Geolog. (Special Issue)<\/i>, 68, 731\u2013742<\/p>\n

45<\/b><\/b><\/b><\/b>.\u00a0Steeb, P., \u00a0S. K. Krause,<\/span> P. L. Linke, C. H. Hensen, A. D. Dale, M. N. Nuzzo, and\u00a0T. Treude<\/strong>\u00a0(2015): Efficiency and adaptability of the benthic methane filter at Quepos Slide cold seeps, offshore Costa Rica.\u00a0Biogeosciences, <\/i>12, 6687\u20136706<\/p>\n

44<\/b><\/b>.\u00a0Schmale, O., I. Leifer, J. Schneider v. Deimling, C. Stolle, S. Krause<\/span>, K. Kie\u00dflich, A. Frahm,\u00a0T. Treude<\/strong>\u00a0(2015):\u00a0 The Bubble Shuttle Process: A gas bubble-mediated bentho-pelagic transport mechanism for methanotrophic microorganisms,\u00a0Contin. Shelf Res. <\/i>103, 70-78<\/p>\n

43<\/b>. Steinle, L.<\/span>, C.A. Graves,\u00a0T. Treude<\/strong>, B. Ferr\u00e9, A. Biastoch, I. Bussmann, C. Berndt, S. Krastel, R.H. James, E. Behrens, C.W. B\u00f6ning, J. Greinert, S. Sommer, C.-J. Sapart, M.F. Lehmann and H. Niemann (2015): A rapid oceanographic switch controls aerobic methane oxidation in the water column above cold seeps off Svalbard.\u00a0Nature Geosciences,\u00a0<\/i>8, 378-382<\/p>\n

42.\u00a0<\/b>Dale, A.W., S. Sommer, U. Lomnitz, I. Montes,\u00a0T. Treude<\/b>, J. Gier<\/span>, C. Hensen, M. Dengler, K. Stolpovsky, L. D. Bryant, and K. Wallmann (2015): Organic carbon production, mineralization and preservation on the Peruvian margin.\u00a0Biogeosciences\u00a0<\/i>12, 1537-1559<\/p>\n

41.<\/b>\u00a0Niemann, H., L. Steinle<\/span>, J. Blees, I. Bussmann,\u00a0T. Treude<\/b>, S. Krause<\/span>, M. Elvert, Lehmann, M. (2015): Toxic effects of lab-grade butyl rubber stoppers on aerobic methane oxidation.\u00a0Limnol. Oceanogr. Methods <\/i>13, 40-52
\n<\/i><\/p>\n

40.\u00a0<\/b>Smith, C.R., A.G. Glover,\u00a0T. Treude<\/b>, N.D. Higgs, D.J. Amon (2015): Whale-fall ecosystems: recent insights into ecology, paleoecology and evolution. Annual Review of Marine Science<\/em>, 7: 571-596<\/p>\n

39. Treude, T.<\/strong>, K. Rose,\u00a0S.B. Joye,\u00a0L.A. Levin,\u00a0G. Dickens,\u00a0E.S. Andersen,\u00a0G. Claypool, M.\u00a0Kastner,\u00a0C. Smith,\u00a0A. Thurber (2014): “Methane Gas Hydrate and the Natural Carbon Cycle”, In: “Y.C. Beaudoin, W. Waite, R. Boswell, and S.R. Dallimore (eds): “Frozen Heat: UNEP Global Outlook on Methane Gas Hydrates, Volume 1”,\u00a0United Nations Environment Programme<\/em>, GRID-Arendal, p31-50, ISBN: 978-92-807-3319-8<\/p>\n

38. Treude<\/b>, T.<\/strong>, S. Krause, J. Maltby<\/span>, R. Coffin, L.J. Hamdan (2014): Sulfate reduction and methane oxidation activity below the sulfate-methane transition zone in Alaskan-Beaufort continental margin sediments: Implications for deep sulfur cycling,\u00a0Geoch. Cosmoch. Acta,<\/i>\u00a0144, 217-237<\/p>\n

37.\u00a0<\/b>\u00a0Krause, S.<\/span>, G. Aloisi, A. Engel, V. Liebetrau,\u00a0T. Treude<\/b>\u00a0(2014): Enhanced calcite dissolution in the presence of the aerobic methanotroph\u00a0Methylosinus trichosporium<\/i>,\u00a0Geomirobiol. J.<\/i>, 31, 325-337<\/p>\n

36.<\/b>\u00a0Steeb, P.<\/span>, \u00a0P. Linke,\u00a0T. Treude<\/b>\u00a0(2014): A sediment flow\u2010through system to study the impact of shifting fluid and methane flow regimes on the efficiency of the benthic methane filter,\u00a0Limnology and Oceanography<\/i>\u00a0Methods<\/i>, 12, 25-45
\n<\/i><\/p>\n

35.<\/b>\u00a0Berndt, C., \u00a0T. Feseker,\u00a0T. Treude<\/b>, S. Krastel, H. Niemann, V.J. Bertics<\/span>, I. Dumke, K. D\u00fcnnbier, B. Ferr\u00e9, C. Graves, F. Gross, K. Hissmann, V. H\u00fchnerbach, S.Krause<\/span>, V. Liebetrau, K. Lieser , J. Schauer, L. Steinle<\/span> (2014): Temporal constraints on hydrate-controlled methane seepage off Svalbard,\u00a0Science,\u00a0<\/i>343, 284-287
\n<\/i><\/p>\n

34.<\/b>\u00a0Thiel, V., \u00a0M. Blumenberg, S. Kiel, K. Liebennau, J. Lindgren, P. Sj\u00f6vall,\u00a0T. Treude<\/b>, T. Zilla (2014):\u00a0 Occurrence and fate of fatty acyl biomarkers in an ancient whale bone (Oligocene, El Cien Formation, Mexico),\u00a0Org. Geochem.,\u00a0<\/i>68, 71-81<\/p>\n

33.<\/b>\u00a0Krause, S., P. Steeb<\/span>, C. Hensen, V. Liebetrau, A.W. Dale, M. Nuzzo,\u00a0T. Treude\u00a0<\/b>(2014): Microbial activity and carbonate isotope signatures as a tool for identification of spatial differences in methane advection: A case study at the Pacific Costa Rican margin,\u00a0Biogeosciences,\u00a0<\/i>11, 507-523<\/p>\n

32.<\/b>\u00a0Hamdan, L., R.B. Coffin, M. Sikaroodi, J. Greinert,\u00a0T. Treude<\/b>, and P.M. Gillevet (2013): Ocean currents shape the microbiome of Arctic marine sediments,\u00a0ISME<\/i>, 7, 685\u2013696<\/p>\n

31.<\/b>\u00a0Bertics, V.J.<\/span>, C.R. L\u00f6scher, I. Salonen, A.W. Dale, R. A. Schmitz,\u00a0T. Treude <\/b>(2013): Occurrence of benthic microbial nitrogen fixation coupled to sulfate reduction in the seasonally hypoxic Eckernf\u00f6rde Bay, Baltic Sea,\u00a0Biogeosciences,<\/i>10, 1243\u20131258<\/p>\n

30.<\/b>\u00a0Dale, A.W., V.J. Bertics<\/span>,\u00a0T. Treude<\/b>, S. Sommer, K. Wallmann (2013): Modeling benthic-pelagic nutrient exchange processes and porewater distributions in a seasonally-hypoxic sediment: evidence for massive phosphate release by\u00a0Beggiatoa<\/i>?\u00a0Biogeosciences<\/i>, 10, 629-651<\/p>\n

29.<\/b>\u00a0Krause, S<\/span>., V. Liebetrau, S. Gorb, M. S\u00e1nchez-Rom\u00e1n, J.A. McKenzie,\u00a0T. Treude<\/b>\u00a0(2012): Microbial nucleation of Mg-rich dolomite in exopolymeric substances (EPS) under anoxic modern seawater salinity: New insight into an old enigma,\u00a0Geology\u00a0<\/i>40 (7), 587-590<\/p>\n

28.\u00a0<\/b>Van Dover, C.L., C.R. Smith, J. Ardron, D. Dunn, K. Gjerde, L. Levin, S. Smith, S. Arnaud-Haond, Y. Beaudoin, J. Bezaury, G. Boland. D. Billett, M. Carr, G. Cherkashov, A. Cook, F. DeLeo, C. Fisher, L. Godet, P. Halpin, M. Lodge, L. Menot, K. Miller, L. Naudts, C. Nugent, L. Pendleton, S. Plouviez, A. Rowden, R. Santos, T. Shank, C. Tao, A. Thurnherr,\u00a0T. Treude\u00a0<\/b>(2012): Designating Networks of Chemosynthetic Ecosystem Reserves in the Deep Sea,\u00a0Marine Policy,\u00a0<\/i>36, 378-381<\/p>\n

27<\/b>.<\/b>\u00a0Treude, T.,\u00a0<\/b>, S. Kiel, P. Linke, J. Peckmann, J. Goedert (2011): “Elasmobranch egg capsules associated with modern and ancient cold seeps: A nursery for marine deep-water predators”,\u00a0MEPS<\/i>, 437: 175-181<\/p>\n

26.\u00a0<\/b>Dale, A.W., S. Sommer, L. Bohlen,\u00a0T. Treude<\/b>, V.J. Bertics<\/span>, H.W. Bange; O. Pfannkuche, T. Schorp, M. Mattsdotter, K. Wallmann (2011): Rates and regulation of nitrogen cycling in seasonally-hypoxic sediments during winter (Boknis Eck, SW Baltic Sea): sensitivity to environmental variables”,\u00a0Estuarine, Coastal and Shelf Science,\u00a0<\/i>95: 14-18<\/p>\n

25.<\/b>\u00a0Joye, S.B., I. Leifer, I.R. MacDonald, J.P. Chanton, C.D. Meile, A.P. Teske, J.E. Kostka, L. Chistoserdova, R. Coffin, D. Hollander, M. Kastner, J.P. Montoya, G. Rehder, E. Solomon,\u00a0T. Treude<\/b>, T.A. Villareal (2011): “Comment on \u201cA Persistent Oxygen Anomaly Reveals the Fate of Spilled Methane in the Deep Gulf of Mexico\u201d”Science<\/i>, 332: 1033<\/p>\n

24.<\/b>\u00a0Biastoch, A.,\u00a0T. Treude<\/b>, L.H. R\u00fcpke, C. Roth, E.B. Burwicz, W. Park, M. Latif, C.W. B\u00f6ning, G. Madec, U. Riebesell, K. Wallmann (2011): “Rising Arctic Ocean temperatures cause gas hydrate destabilization and ocean acidification”,\u00a0Geophys. Res. Let.<\/i>38: L08602<\/p>\n

23. Treude, T.\u00a0<\/b>(2011): “Biogeochemical reactions in marine sediments underlying anoxic water bodies”, In: “Anoxia: Paleontological Strategies and Evidence for Eukaryote Survival”, A. Altenbach, J. Bernhard, J. Seckbach (Eds.), Cellular Origins, Life in Extreme Habitats and Astrobiology (COLE) Book Series,\u00a0Springer,<\/i>\u00a0p 19-38, ISBN:\u00a0978-9400718951<\/p>\n

22. Treude, T.<\/b>\u00a0(2011): “Methanhydrate: Erw\u00e4rmung, Freisetzung und mikrobiologischer Abbau”, In: “Warnsignal Klima: Die Meere \u2013 \u00c4nderungen und Risiken” J.L. Loz\u00e1n (Eds.),\u00a0Wissenschaftliche Auswertungen ,<\/i>\u00a0p 178-182,\u00a0ISBN:\u00a0978-3980966856<\/p>\n

21. Treude, T.<\/b>, W. Ziebis (2010): “Methane oxidation in permeable sediments at hydrocarbon seeps in the Santa Barbara Channel, California”,\u00a0Biogeosciences,<\/i>\u00a07: 1-14<\/p>\n

20.\u00a0<\/b>\u00a0Orcutt, B., S.B. Joye, S. Kleindienst, K. Knittel, A. Ramette, A. Reitz, V. Samarkin,\u00a0T. Treude<\/b>, and A.Boetius (2010): \u201cImpact of natural oil and higher hydrocarbons on microbial diversity, distribution and activity in Gulf of Mexico cold seep sediments\u201d,\u00a0Deep-Sea Research II,<\/i>\u00a057: 2008-2021<\/p>\n

19.\u00a0<\/b>Bertics, V.J., J.A. Sohm,\u00a0T. Treude<\/b>, C-E.T. Chow, D.G. Capone, J.A. Fuhrman, W. Ziebis (2010): \u201cBurrowing deeper into the benthic nitrogen cycling: the impact of bioturbation on nitrogen fixation coupled to sulfate reduction\u201d,\u00a0Mar. Ecol. Prog. Ser.\u00a0<\/i>409: 1-15, Feature Article<\/p>\n

18.<\/b>\u00a0Sommer, S., P. Linke, O. Pfannkuche,\u00a0 H. Niemann,\u00a0T. Treude\u00a0<\/b>(2010): Benthic respiration in a novel seep habitat dominated by dense beds of ampharetid polychaetes at the Hikurangi Margin (New Zealand) ‘,\u00a0Marine Geology\u00a0<\/i>272(1-4): 223-232<\/p>\n

17. Treude, T.<\/b>, C.R. Smith, F. Wenzh\u00f6fer, E. Carney, A.F. Bernardino, A.K. Hannides, M. Kr\u00fcger, A. Boetius (2009): ‘ Biogeochemistry of a deep-sea whale fall: sulfate reduction, sulfide efflux and methanogenesis’,\u00a0Mar. Ecol. Prog. Ser.\u00a0<\/i>382, 1-21, Feature Article<\/p>\n

16.<\/b>\u00a0Engelen, B., K. Ziegelm\u00fcller, L. Wolf, B. K\u00f6pke, A. Gittel,\u00a0T. Treude<\/b>, S. Nakagawa, F. Inagaki, M.A. Lever, B.O. Steinsbu, H. Cypionka (2008): ‘Fluids from the oceanic crust support microbial activities within the deep biosphere’\u00a0Geomicrobiol. J.<\/i>\u00a025 (1) 56-66<\/p>\n

15. Treude, T.<\/b>, V. Orphan, K. Knittel, A. Gieseke, C.H. House, A. Boetius (2007): ‘Consumption of methane and CO2 by methanotrophic microbial mats from gas seeps of the anoxic Black Sea’,\u00a0Appl. Environ. Microbiol.\u00a0<\/i>73 (7), 2271-2283<\/p>\n

14.<\/b>\u00a0Inagaki, F., , M.M.M. Kuypers, U. Tsunogai, J. Ishibashi, K. Nakamura,\u00a0T. Treude<\/b>, S. Ohkubo, M. Nakaseama, K. Gena, H. Chiba, H. Hirayama,T. Nunoura1, K. Takai, B.B. J\u00f8rgensen, K. Horikoshi, A. Boetius (2006): ‘Microbial community in a sediment-hosted CO2 lake of the southern Okinawa Trough hydrothermal system’,\u00a0PNAS<\/i>\u00a0103 (38), 14164-14169<\/p>\n

13.<\/b>\u00a0Palacios, C., M. Zbinden, A.R. Baco,\u00a0T. Treude<\/b>, C.R. Smith, F. Gaill, P. Lebaron, A. Boetius (2006). ‘Microbial ecology of deep-sea sunken wood: quantitative measurements of bacterial biomass and cellulolytic activities’,\u00a0Cahiers de Microbiologie Marine\u00a0<\/i>47(4), 415-420<\/p>\n

12.\u00a0<\/b>Alain, K., T. Holler, F. Musat, M. Elvert,\u00a0T. Treude<\/b>, and M. Kr\u00fcger (2006): ‘Microbiological investigation of methane- and hydrocarbon-discharging mud volcanoes in the sub-Carpathes, Romania.’\u00a0Environmental Microbiology\u00a0<\/i>8(4), 574-590<\/p>\n

11.<\/b>\u00a0Elvert, M., E.C. Hopmans,\u00a0T. Treude<\/b>, A. Boetius, E. Suess (2005): ‘Spatial variations of methanotrophic consortia at cold methane seeps: Implications from a high-resolution molecular and isotopic approach’.\u00a0Geobiology 3<\/i>, 195-209<\/p>\n

10. Treude, T.<\/b>, M. Kr\u00fcger, A. Boetius, B.B. J\u00f8rgensen (2005): ‘Environmental control on anaerobic oxidation of methane in the gassy sediments of Eckernf\u00f6rde Bay (German Baltic)’.\u00a0Limnol. Oceanogr.<\/i>\u00a050, 1771-1786<\/p>\n

9. Treude, T.<\/b>, K. Knittel, M. Blumenberg, R. Seifert, A. Boetius (2005): ‘Subsurface microbial methanotrophic mats in the Black Sea’.\u00a0Appl. Environ. Microbiol.\u00a0<\/i>71(10), pp 6375-6378<\/p>\n

8.<\/b>\u00a0Kr\u00fcger, M.,\u00a0T. Treude<\/b>, H. Wolters, K. Nauhaus, A. Boetius (2005): ‘Microbial methane turnover in different marine habitats’.\u00a0Palaeogeography,<\/i>Palaeoclimatology, Palaeoecology,\u00a0<\/i>227(1-3), pp 6-17<\/p>\n

7.\u00a0<\/b>Kr\u00fcger, M.,\u00a0\u00a0T. Treude\u00a0<\/b>(2005): ‘New insights into the physiology and regulation of the anaerobic oxidation of methane’. In: Microorganisms and earth systems \u2013 Advances in Geomicrobiology. SGM Microbiology 65, Eds. G.M. Gadd, K.T. Temple, and H.M. Lappin-Scott.\u00a0Cambridge University Press<\/em>, 303-320.<\/p>\n

6.<\/b>\u00a0Treude, T.<\/b>, J. Niggemann, J. Kallmeyer, P. Wintersteller, C.J. Schubert, A. Boetius, B.B. J\u00f8rgensen (2005): ‘ Anaerobic oxidation of methane and sulfate reduction along the Chilean continental margin’.\u00a0Geochim. Cosmochim. Acta<\/i>, 69(11), pp 2767-2779<\/p>\n

5.<\/b>\u00a0Nauhaus, N.,\u00a0\u00a0T. Treude<\/b>, A. Boetius, M. Kr\u00fcger (2005): ‘Environmental regulation of the anaerobic oxidation of methane: a comparison of ANME-I- and ANME-II- communities’.\u00a0Environmental Microbiology<\/i>, 7(1), pp 98-106<\/p>\n

4. Treude, T.,\u00a0<\/b>, A. Boetius, K. Knittel, K. Wallmann, B.B. J\u00f8rgensen (2003): ‘Anaerobic oxidation of methane above gas hydrates at Hydrate Ridge, NE Pacific Ocean’.\u00a0Mar. Ecol. Prog. Ser.,\u00a0<\/i>264, pp 1-14<\/p>\n

3.\u00a0<\/b>Michaelis, W., R. Seifert, K. Nauhaus,\u00a0T. Treude<\/b>, V. Thiel, M. Blumenberg, K. Knittel, A. Gieseke, K. Peterknecht, T. Pape, A. Boetius, R. Amann, B.B. J\u00f8rgensen, F. Widdel, J. Peckmann, N.V. Pimenov, M.B. Gulin (2002): ‘Microbial reefs in the Black Sea fueled by anaerobic oxidation of methane’.\u00a0Science,<\/i>\u00a0297, pp. 1013-1015<\/p>\n

2. Treude, T.<\/b>, F. Jan\u00dfen, W. Queisser, U. Witte (2002): ‘Metabolism and decompression tolerance of scavenging lysianassoid deep-sea amphipods’.\u00a0Deep-Sea Research I,<\/i>\u00a049, pp. 1281-1289<\/p>\n

1.<\/b>\u00a0Jan\u00dfen, F.,\u00a0T. Treude<\/b>, U. Witte (2000): ‘Scavenger assemblages under different trophic conditions: a case study in the deep Arabian Sea’.\u00a0Deep-Sea Research II<\/i>, 47, pp. 2999-3026.\u00a0PDF<\/a><\/p>\n

Non-reviewed\u00a0Publications<\/h3>\n
\n

4.\u00a0<\/b>Temps, F.,\u00a0T. Treude\u00a0<\/b>(2010): ‘Abbau des \u00d6ls’, In: Die \u00d6lkatastrophe im Golf von Mexiko \u2013 was bleibt, press release,\u00a0Cluster of Excellence: The Future Ocean<\/p>\n<\/div>\n

3. Treude, T.<\/b>\u00a0(2010): ‘Wirkung des Klimawandels auf Methanhydrate’, In: World Ocean Review, maribus Verlag<\/em><\/p>\n

2. Treude, T.\u00a0<\/b>und G. Bohrmann (2004) “Da en tsunami ramte Norden”, BioNyt<\/em> (128), pp. 16-24.<\/p>\n

1. Treude, T.\u00a0<\/b>and A. Boetius (2003): ‘Researching anaerobic oxidation of methane: A co-evolution of knowledge and applied methods’. In: T. Hattori (eds.), ‘Biogeochemical aspects of Earth system and bioremediation of polluted environments’, The 16th International Symposium on Environmental Biogeochemistry and its OECD Session<\/em><\/p>\n","protected":false},"excerpt":{"rendered":"

Visit my Google Scholar Page for further\u00a0information Peer-reviewed Journal Articles and Book Chapters (underlined authors highlight\u00a0students or postdocs from my group) ——\u00a0submitted\/accepted —— 97. Scott, P., Cockell, C., \u00a0Fischer, W., Sharma, S., Lloyd, K., Wilhelm, Mary, B. \u00a0Corsetti, F., Treude, T., Leadbetter, J., Giovannelli, D., \u00a0Foreman, C., \u00a0Freedman, K., \u00a0Lynch, K., \u00a0Homann, M., \u00a0Som, S., … Continue reading Publications<\/span> →<\/span><\/a><\/p>\n","protected":false},"author":1,"featured_media":0,"parent":26,"menu_order":4,"comment_status":"closed","ping_status":"open","template":"","meta":{"footnotes":""},"class_list":["post-20","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/faculty.epss.ucla.edu\/~ttreude\/index.php?rest_route=\/wp\/v2\/pages\/20","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/faculty.epss.ucla.edu\/~ttreude\/index.php?rest_route=\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/faculty.epss.ucla.edu\/~ttreude\/index.php?rest_route=\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/faculty.epss.ucla.edu\/~ttreude\/index.php?rest_route=\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/faculty.epss.ucla.edu\/~ttreude\/index.php?rest_route=%2Fwp%2Fv2%2Fcomments&post=20"}],"version-history":[{"count":224,"href":"https:\/\/faculty.epss.ucla.edu\/~ttreude\/index.php?rest_route=\/wp\/v2\/pages\/20\/revisions"}],"predecessor-version":[{"id":1340,"href":"https:\/\/faculty.epss.ucla.edu\/~ttreude\/index.php?rest_route=\/wp\/v2\/pages\/20\/revisions\/1340"}],"up":[{"embeddable":true,"href":"https:\/\/faculty.epss.ucla.edu\/~ttreude\/index.php?rest_route=\/wp\/v2\/pages\/26"}],"wp:attachment":[{"href":"https:\/\/faculty.epss.ucla.edu\/~ttreude\/index.php?rest_route=%2Fwp%2Fv2%2Fmedia&parent=20"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}