Book 2.indb - US Climate Change Science Program

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The U.S. Climate Change Science ProgramReferencesZickfeld, K., A. Levermann, M.G. Morgan, T. Kuhlbrodt, S.Rahmstorf, and D. Keith, 2007: Expert judgements on theresponse of the Atlantic meridional overturning circulationto climate change. Climatic Change, 82, doi:10.1007/s10584-007-9246-3.CHAPTER 5 REFERENCESAlley, R.B. and A.M. Agustsdottir, 2005: The 8k event: Causeand consequences of a major Holocene abrupt climate change.Quaternary Science Reviews, 24(10–11), pp. 1123–1149.Anisimov, O.A. and F.E. Nelson, 1997: Permafrost zonationand climate change in the northern hemisphere: Results fromtransient general circulation models. Climatic Change, 35,pp. 241–258, doi:10.1023/A:1005315409698.Aoki, Y., S. Shimizu, T. Yamane, T. Tanaka, K. Nakayama, T.Hayashi, and Y. Okuda, 2000: Methane hydrate accumulationalong the western Nankai Trough. In: Gas Hydrates: Challengesfor the Future [Holder, G.D. and Bishnoi, P.R. (eds.)]. Annalsof the New York Academy of Sciences, 912, pp. 136–145.Archer, D., 2005: Fate of fossil-fuel CO 2 in geologic time. Journalof Geophysical Research, 110, doi:10.1029/2004JC002625.Archer, D., 2007: Methane hydrate stability and anthropogenicclimate change. Journal of Geophysical Research—Biogeosciences,4, pp. 521–544.Archer, D. and B. Buffett, 2005: Time-dependent response of theglobal ocean clathrate reservoir to climatic and anthropogenicforcing. Geochemistry, Geophysics, Geosystems, 6(3), doi:10.1029/2004GC000854.Archer, D., H. Kheshgi, and E. Maier-Riemer, 1997: Multipletimescales for neutralization of fossil fuel CO 2 . GeophysicalResearch Letters, 24, pp. 405–408.Archer, D., P. Martin, B. Buffett, V. Brovkin, S. Rahmstorf, andA. Ganopolski, 2004: The importance of ocean temperature toglobal biogeochemistry. Earth and Planetary Science Letters,222, pp. 333–348, doi:10.1016/j.epsl.2004.03.011.Bartlett, K.B. and R.C. Harriss, 1993: Review and assessment ofmethane emissions from wetlands. Chemosphere, 26, pp. 261–320.Belyea, L.R. and A.J. Baird, 2007: Beyond “the limits to peatbog growth”: Cross-scale feedback in peatland development.Ecological Monographs, 76, pp. 299–322, doi:10.1890/0012-9615(2006)076[0299:BTLTPB]2.0.CO;2.Bergamaschi, P., C. Frankenberg, J.F. Meirink, M. Krol, F.Dentener, T. Wagner, U. Platt, J.O. Kaplan, S. Körner, M.Heimann, E.J. Dlugokencky, and A. Goede, 2007: Satellitechartography of atmospheric methane from SCIAMACHYon board ENVISAT: 2. Evaluation based on inverse modelsimulations. Journal of Geophysical Research, 112, D02304,doi:10.1029/2006JD007268.Berner, R.A., A.C. Lasaga, and R.M. Garrels, 1983: The carbonate-silicategeochemical cycle and its effect on atmosphericcarbon dioxide over the past 100 million years. American Journalof Science, 283, pp. 641–683.Blake, D.R. and F.S. Rowland, 1988: Continuing worldwide increasein tropospheric methane, 1978 to 1987. Science, 239,pp. 1129–1131, doi:10.1126/science.239.4844.1129.Blunier, T. and E.J. Brook, 2001: Timing of millennial-scaleclimate change in Antarctica and Greenland during the lastglacial period. Science, 291, pp. 109–112, doi:10.1126/science.291.5501.109.Boswell, R., 2007: Resource potential of methane hydrate cominginto focus. Journal of Petroleum Science and Engineering, 56,pp. 9–13, doi:10.1016/j.petrol.2006.09.002.Boswell, R., D. Hutchinson, and P. Ray, 2005: Changing perspectiveson the resource potential of methane hydrates. In: Fire inthe Ice, newsletter of the U.S. Department of Energy, Office ofFossil Energy, National Energy Technology Laboratory, summer2005. http://www.netl.doe.gov/technologies/oil-gas/publications/Hydrates/Newsletter/HMNewsSummer05.pdf.Boudreau, B.P., C. Algar, B.D. Johnson, I. Croudace, A. Reed, Y.Furukawa, K.M. Dorgan, P.A. Jumars, A.S. Grader, and B.S.Gardiner, 2005: Bubble growth and rise in soft sediments. Geology,33(6), pp. 517–520, doi:10.1130/G21259.1.Bousquet, P., P. Ciais, J.B. Miller, E.J. Dlugokencky, D.A. Hauglustaine,C. Prigent, G.R. Van der Werf, P. Peylin, E.-G.Brunke, C. Carouge, R.L. Langenfelds, J. Lathière, F. Papa,M. Ramonet, M. Schmidt, L.P. Steele, S.C. Tyler, and J. White,2006: Contribution of anthropogenic and natural sources toatmospheric methane variability. Nature, 443, pp. 439–443,doi:10.1038/nature05132.Bowen, G.J., D.J. Beerling, P.L. Koch, J.C. Zachos, and T. Quattlebaum,2004: A humid climate state during the Palaeocene/Eocene thermal maximum. Nature, 432(7016), pp. 495–499,doi:10.1038/nature03115.Bralower, T.J., D.J. Thomas, J.C. Zachos, M.M. Hirschmann,U. Rohl, H. Sigurdsson, E. Thomas, and D.L. Whitney, 1997:High-resolution records of the late Paleocene thermal maximumand circum-Caribbean volcanism: Is there a causal link?Geology, 25(11), pp. 963–966.Brewer, P.G., C. Paull, E.T. Peltzer, W. Ussler, G. Rehder, andG. Friederich, 2002: Measurements of the fate of gas hydratesduring transit through the ocean water column. GeophysicalResearch Letters, 29(22), 2081, doi:10.1029/2002GL014727.Brook, E. and L. Mitchell, 2007: Timing and trends in Northernand Southern Hemisphere atmospheric methane during the Holocene:New results from Antarctic and Greenlandic ice cores.Eos, Transactions, American Geophysical Union, 88(52), FallMeeting Supplement, Abstract U21F-06.Brook, E., J.W.C. White, A.S.M. Schilla, M.L. Bender, B. Barnett,J.P. Serveringhaus, K.C. Taylor, R.B. Alley, and E.J.Steig, 2005: Timing of millennial-scale climate change at SipleDome, West Antarctica, during the last glacial period. QuaternaryScience Reviews, 24, pp. 1333–1343, doi:10.1016/j.quascirev.2005.02.002.Brook, E. and E. Wolff, 2005: The future of ice core science.Eos, Transactions, American Geophysical Union, 87,doi:10.1029/2006EO040004.Brook, E.J., S. Harder, J.P. Severinghaus, E.J. Steig, and C.M.Sucher, 2000: On the origin and timing of rapid changes inatmospheric methane during the last glacial period. GlobalBiogeochemical Cycles, 14, pp. 559–572.Brook, E.J., T. Sowers, and J. Orchardo, 1996: Rapid variationsin atmospheric methane concentration during the past 110,000years. Science, 273, doi:10.1126/science.273.5278.1087.230
Abrupt Climate ChangeBrooks, J.M., W.R. Bryant, B.B. Bernard, and N.R. Cameron,2000: The nature of gas hydrates on the Nigerian continentalslope. In: Gas Hydrates: Challenges for the Future [Holder,G.D. and P.R. Bishnoi (eds.)]. Annals of the New York Academyof Sciences, 912, pp. 76–93.Bryn, P., K. Berg, C.F. Forsberg, A. Solheim, and T.J. Kvalstad,2005: Explaining the Storegga slide. Marine and PetroleumGeology, 22(1–2), pp. 11–19, doi:10.1016/j.marpetgeo.2004.12.003.Bubier, J.L., T.R. Moore, L. Bellisario, N.T. Comer, and P.M.Crill, 1995: Ecological controls on methane emissions from anorthern peatland vomplex in the zone of discontinuous permafrost,Manitoba, Canada. Global Biogeochemical Cycles, 9,pp. 455–470.Bubier, J.L., T. Moore, K. Savage, and P. Crill, 2005: A comparisonof methane flux in a boreal landscape between a dryand a wet year. Global Biogeochemical Cycles, 19, GB1023,doi:10.1029/2004GB002351.Buffett, B. and D. Archer, 2004: Global inventory of methaneclathrate: Sensitivity to changes in the deep ocean. Earth andPlanetary Science Letters, 227, pp. 185–199.Bunz, S. and J. Mienert, 2004: Acoustic imaging of gas hydrateand free gas at the Storegga slide. Journal of Geophysical Research,109, B04102, doi:10.1029/2003JB002863.Buteau, S., R. Fortier, G. Delisle, and M. Allard, 2004: Numericalsimulation of the impacts of climate warming on a permafrostmound. Permafrost and Periglacial Processes, 15, pp. 41–57.Camill, P., 2005: Permafrost thaw accelerates in boreal peatlandsduring late-20th century climate warming. Climatic Change,68, pp. 135–152.Cannariato, K.G. and L.D. Stott, 2004: Evidence against clathrate-derivedmethane release to Santa Barbara Basin surfacewaters? Geochemistry, Geophysics, Geosystems, 5, Q05007,doi:10.1029/2003GC000600.Chapin, F.S., III, M. Sturm, M.C. Serreze, J.P. McFadden, J.R.Key, A.H. Lloyd, A.D. McGuire, T.S. Rupp, A.H. Lynch, J.P.Schimel, J. Beringer, W.L. Chapman, H.E. Epstein, E.S. Euskirchen,L.D. Hinzman, G. Jia, C.-L. Ping, K.D. Tape, C.D.C.Thompson, D.A. Walker, and J.M. Welker, 2005: Role ofland-surface changes in arctic summer warming. Science, 310,doi:10.1126/science.1117368.Chapman, W.L. and J.E. Walsh, 2007: Simulations of Arctic temperatureand pressure by global coupled models. Journal ofClimate, 20, pp. 609–632.Chappellaz, J., J.M. Barnola, D. Raynaud, Y.S. Korotkevich, andC. Lorius, 1990: Ice-core record of atmospheric methane overthe past 160,000 years. Nature, 345, doi:10.1038/345127a0.Chappellaz, J., T. Blunier, S. Kints, A. Dällenbach, J.-M. Barnola,J. Schwander, D. Raynaud, and B. Stauffer, 1997: Changes inthe atmospheric CH 4 gradient between Greenland and Antarcticaduring the Holocene. Journal of Geophysical Research,102, pp. 15,987–15,997.Chappellaz, J., T. Blunier, D. Raynaud, J.M. Barnola, J.Schwander, and B. Stauffer, 1993a: Synchronous changes inatmospheric CH 4 and Greenland climate between 40 and 8 kyrBP. Nature, 366, doi:10.1038/366443a0.Chappellaz, J.A., I.Y. Fung, and A.M. Thompson, 1993b: Theatmospheric CH 4 increase since the Last Glacial Maximum.1, Source estimates. Tellus, 45B(3), pp. 228–241.Christensen, T.R., A. Ekberg, L. Ström, M. Mastepanov, N. Panikov,M. Öquist, B.H. Svensson, H. Nykänen, P.J. Martikainen,and H. Oskarsson, 2003: Factors controlling large scale variationsin methane emissions from wetlands. Geophysical ResearchLetters, 30(7), 1414, doi:10.1029/2002GL016848.Christensen, T.R., T. Johansson, H.J. Åkerman, M. Mastepanov,N. Malmer, T. Friborg, P. Crill, and B.H. Svensson, 2004:Thawing sub-arctic permafrost: Effects on vegetation andmethane emissions. Geophysical Research Letters, 31, L04501,doi:10.1029/2003GL018680.Christensen, T.R., I.C. Prentice, J. Kaplan, A. Haxeltine, and S.Sitch, 1996: Methane flux from northern wetlands and tundra:An ecosystem modelling approach. Tellus, 48B, pp. 652–661.Collett, T.S. and G.D. Ginsburg, 1998: Gas hydrates in the MessoyakhaGas Field of the West Siberian Basin—A re-examinationof the geologic evidence. In: The Proceedings of theSeventh (1997) International Offshore and Polar EngineeringConference, Honolulu, HI, May 25–30, 1997, volume 1.Collett, T.S. and V.A. Kuuskraa, 1998: Hydrates contain vast storeof world gas resources. Oil and Gas Journal, 96, pp. 90–95.Dällenbach, A., T. Blunier, J. Flückiger, B. Stauffer, J. Chappellaz,and D. Raynoud, 2000: Changes in the atmospheric CH 4gradient between Greenland and Antarctica during the LastGlacial and the transition to the Holocene. Geophysical ResearchLetters, 27, pp. 1005–1008.Dansgaard, W., J.W.C. White, and S.J. Johnsen,1989: The abrupttermination of the Younger Dryas climate event. Nature, 339,doi:10.1038/339532a0.Davidson, E.A. and I.A. Janssens, 2006: Temperature sensitivityof soil carbon decomposition and feedbacks to climate change.Nature, 440, doi:10.1038/nature04514.De Batist, M., J. Klerkx, P. Van Rensbergen, M. Vanneste, J.Poort, A.Y. Golmshtok, A.A. Kremlev, O.M. Khlystov, and P.Krinitsky, 2002: Active hydrate destabilization in Lake Baikal,Siberia? Terra Nova, 14(6), pp. 436–442.Delmotte, M., J. Chappellaz, E. Brook, P. Yiou, J.M. Barnola,C. Goujon, D. Raynaud, and V.I. Lipenkov, 2004: Atmosphericmethane during the last four glacial-interglacialcycles: Rapid changes and their link with Antarctic temperature.Journal of Geophysical Research, 109, D12104,doi:10.1029/2003JD004417.Denman, K.L., G. Brasseur, A. Chidthaisong, P. Ciais, P.M. Cox,R.E. Dickinson, D. Hauglustaine, C. Heinze, E. Holland, D.Jacob, U. Lohmann, S. Ramachandran, P.L. da Silva Dias, S.C.Wofsy, and X. Zhang, 2007: Couplings between changes inthe climate system and biogeochemistry. In: Climate Change2007: The Physical Science Basis. Contribution of WorkingGroup I to the Fourth Assessment Report of the IntergovernmentalPanel on Climate Change [Solomon, S., D. Qin, M.Manning, Z. Chen, M. Marquis, K.B. Averyt, M.Tignor, andH.L. Miller (eds.)]. Cambridge University Press, Cambridge,United Kingdom, and New York, NY, USA, pp. 500–587.231
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TABLE OF CONTENTSAuthor Team for th
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The U.S. Climate Change Science Pro
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PREFACEReport Motivation and Guidan
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1CHAPTERAbrupt Climate ChangeIntrod
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Abrupt Climate Change-35Arctic temp
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Abrupt Climate ChangeFigure 1.2. Po
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Abrupt Climate Changewell below sea
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Abrupt Climate Changeheterogeneous
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Abrupt Climate Changeapart from dro
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Abrupt Climate Change6. Abrupt Chan
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Abrupt Climate Changeintermediate c
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Abrupt Climate Changeper square met
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Abrupt Climate Changeis the norther
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Abrupt Climate ChangeRegardless how
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Abrupt Climate Changecentrations, a
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Abrupt Climate ChangeBox 2.1. Glaci
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Abrupt Climate Changetime. Degree-d
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Abrupt Climate Changetion, and accu
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Abrupt Climate ChangeBox 2.2. Mass
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Abrupt Climate Changeof the glacier
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Abrupt Climate ChangeFigure 2.6. Ra
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Abrupt Climate Changewater) or, mor
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Abrupt Climate ChangeFigure 2.7. Re
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Abrupt Climate Changeresults in a l
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Abrupt Climate Changeis not providi
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Abrupt Climate Changemeasurements c
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Abrupt Climate Changemore than 10,0
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Abrupt Climate Changeocean models h
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Abrupt Climate Changeto atmosphere-
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3CHAPTERHydrological Variability an
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Abrupt Climate Change• The integr
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Abrupt Climate Changethe soil (King
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Abrupt Climate Changeon (Kaplan et
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Abrupt Climate Changeorbital-time-s
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Abrupt Climate ChangeFigure 3.4. (t
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Abrupt Climate Changemodels forced
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Abrupt Climate ChangeBox 3.2. Waves
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Abrupt Climate ChangeHarrison et al
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Abrupt Climate Changeentire period
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Abrupt Climate Changelong-lived gre
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Abrupt Climate Changeplanetary-scal
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Abrupt Climate ChangeBox 3.3. Paleo
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Abrupt Climate Changeinto the North
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Abrupt Climate ChangeThe summertime
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Abrupt Climate Change(Anderson et a
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Abrupt Climate ChangeHere the model
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Abrupt Climate Changetropical tropo
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Abrupt Climate Changefunctions; Koc
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Abrupt Climate Changechanges than t
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