Who is Who in Carbon Balance and Management 2006

This editorial provides a subject index from published articles, active researchers, and published papers in the field of carbon balance and management. Background Developing a policy relevant understanding of the global carbon cycle requires a high degree of interdisciplinarity. Therefore, research published in Carbon Balance and Management involves cutting across disciplines and consulting with specialists in various fields. This editorial is to support an interdisciplinary effort with relevant bibliographic information [see Additional file 1] including a source of names to consult with and a list of subjects that may appear in the papers. Terms may differ depending on context. Subject index This list of words and wordings [see Additional file 2], selected from the articles published in the first volume of the journal, represents the phraseology of carbon cycle science. It was compiled to provide help in searching relevant web resources. This list is also presented below together with links to the articles where a given subject is treated or mentioned. ability to retain organic carbon [14] acceptable climate change [6] acid neutralizing capacity of seawater [4] acid-base balance [2] acid-base imbalances in marine organisms [2] activity data [9] actual country-specific information [9] adverse conditions [6] afforestation [15,134] agriculture sector [9] alkalinity [2] allocation of carbon [6] anomalies in atmospheric CO2 increase [7] anomalous CO2 flux [7] anomalously extreme climate [6] Anthropocene [3,4] anthropogenic emissions [7] Asia region [9] Published: 22 January 2007 Carbon Balance and Management 2007, 2:1 doi:10.1186/1750-0680-2-1 Received: 10 January 2007 Accepted: 22 January 2007 This article is available from: http://www.cbmjournal.com/content/2/1/1 © 2007 Alexandrov; licensee BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Page 1 of 18 (page number not for citation purposes) Carbon Balance and Management 2007, 2:1 http://www.cbmjournal.com/content/2/1/1 atmosphere-ice-ocean carbon cycle model [2] atmospheric CO2 concentrations [2,5,88] average surface temperature [2] baseline energy consumption from air-conditioning [12] baseline value for SOC [14] biologically mediated pH changes [2] biosphere simulation model [6] burnt biomass [7] calcareous shells [2] capacity to absorb anthropogenic CO2 [5] capacity to act as sinks [3] carbon budgets [7,11,85,133] carbon conserving practices [4] carbon cycle feedbacks [3,42,44,49,50,81] carbon emissions [8,11] carbon fertilisation [6,53,55] carbon flows [8] carbon flux anomalies [7] carbon fluxes [3,7,8,17,46,55,65] Carbon Management Education [13] carbon price incentive schemes [15] carbon sequestration [4,15,107,134,135] carbon sink [5,45,73] carbon stocks in forest biomass [15] carbon tax [15] carbon uptake [5-7,15,36,49] carelessness feedback [4] cation exchange capacity [14] change of vegetation type [6] changes in the moisture regime [3] changes in weather patterns [6] Cities for Climate Change Program [11] climate change [2,6,14,18,40,43,44,46,49,58,60,81,108,134,136] climate change feedbacks on the carbon chemistry [2] climate policy [5] climate scenario [6] CO2 biological pump [2] CO2 emissions in the commercial sector [12] CO2 uptake by the ocean [2,34] collapse of the Amazonian rain forest [6] compensating effects [2,3] compensatory mechanisms [6] consumption activities [9] conversion of natural lands [8] country-specific emission factors [9] coupled atmosphere-ocean mode [2] cover fraction of major vegetation types [6] current forest cover [15] data set [7,8,34,63,133] dead organic matter [8] decline in boreal forest area [6] decline in forest area [6] decrease in pH due to ocean warming [2] decrease of biomass [6] decreases in transpiration [6] Page 2 of 18 (page number not for citation purposes) Carbon Balance and Management 2007, 2:1 http://www.cbmjournal.com/content/2/1/1 decreasing rainfall [6] default activity data [9] default emission factors [9] deforestation [6,15,134] deforestation emissions [15] deforestation tax [15] desertification [14] DIC concentrations [2] direct anthropogenic emission of CO2 [8] direct effects of ocean warming [2] direct human influence [5] direct injection of carbon into the deep ocean [4] dissolution of exoskeletal components [2] disturbance in terrestrial ecosystems [3] disturbances of the global carbon cycle [7] drought-induced tree line [6] Dynamic Global Vegetation Models [6,43,48,61,70] dynamics of terrestrial ecosystems [3] ecological modernization [11] ecosystem physiology [3] eddy covariance measurements [7] EEZ [5] EEZ carbon sink [5] effect of income [11] effects of temperature and precipitation [7] embedded carbon [11] emission factors [9,12] emission reduction targets [12] emission sources [9,105,106] emissions reduction target [11] emitting mechanisms from sources [9] energy consumption in typical offices [12] energy savings potential [12] energy usage within buildings [12] energy use [11] enhanced litter production [6] enhanced plant growth [3] environmental regulations [11] environmental stress [6] estimation methods [9] exceptionally dry years [6] Exclusive Economic Zone [5] expanding land use [6] extended dry seasons [7] extent of ocean acidification [2] feedbacks and non-linearities [8] feedbacks and nonlinearities [3] feedbacks between climate and vegetation [6] financial mechanisms [15] fire control in forests [4] forest [3,6,14,15,17,51,54,55,57,75,79,119,133] forest degradation [15] forest expansion [15] fossil fuel consumption [4] fuelwood production [15] full carbon budgets for cities [11] Page 3 of 18 (page number not for citation purposes) Carbon Balance and Management 2007, 2:1 http://www.cbmjournal.com/content/2/1/1 functional strategies [6] geoengineering strategies [4] geographical pattern of vegetation [6] geologic sequestration [4] GHG inventories [9] global carbon trading [5] global decline in SOC [14] greenhouse gas emission scenario [6] greenhouse gas emissions [11] greenhouse gas inventories [9,12] guidelines of the Intergovernmental Panel on Climate Change [9] heat stress on boreal trees [6] heating, ventilating, and air conditioning [12] heterotrophic respiration [7] holistic view of the carbon cycle [3] human emissions-atmospheric CO2 equation [3] human well-being [6] HVAC [12] impact of climate change [6,14] incentives for keeping the forest carbon stock intact [15] increase in fire frequency [6] increase in oceanic [2] increased deciduousness [6] increased water demand [6] increased water use efficiency [6] increases in growing stock [15] increasing concentration of carbonic acid [3] increasing greenhouse gas concentrations [6] industrial carbon dioxide emissions [11] industrialization [11] information exchange activities [9] injected carbon [4] insensitivity of pH to climate change [2] institutional drivers [11] institutional impacts [11] intergenerational equity [4] invariant allocation of carbon gains [6] IPAT [11,104] IPCC guidelines [9] Kuznets curve [11] Kyoto Protocol [4,5,134] land ecosystems [6] land use change [7] land use model [15] Land Use, Land-Use Change and Forestry [9] land-use change [11] large-scale climate anomalies [7] leaf nitrogen contents [6] living biomass [8] locally appropriate levers for carbon management [13] locally derived regulatory oversight [11] long term means to store CO2 [4] lower wet season precipitation [7] magnitude of carbon fertilisation effects [6] marine carbon cycle [3] Page 4 of 18 (page number not for citation purposes) Carbon Balance and Management 2007, 2:1 http://www.cbmjournal.com/content/2/1/1 marine organisms [2] meridional change in pH [2] Miami model [14] mitigating the heat load of buildings [12] mitigation and adaptation policies [6] mobilisation of nitrogen [3] modernization effect [11] Montreal Protocol [9] national carbon accounts [5] national communications [9] national greenhouse gas inventories [11] NEE anomalies [7] net carbon exchange [6] net carbon loss [6] net climate change feedback [2] net ecosystem production [15,133] net loss of carbon [3] net primary production [7,14,71,72] net primary productivity [71,116] net sink of carbon [6] neutralizing capacity of calcium carbonate [4] non-woody vegetation [6] northward expansion of the boreal forest [6] NPP [7,8,14] nutrient and water constraints [6] nutrient limitations of vegetation growth [6] ocean acidification [2,19] ocean pH [2,20] ocean warming [2] ocean warming feedback [2] oceanic anthropogenic CO2 sink [5] oceanic CO2 uptake [2,18,67] oceanic uptake of anthropogenic CO2 [2] past changes in climate [6] permafrost soils [3] permafrost thawing depth [6] pest outbreaks [3] pH of seawater [2] phosphorus availability [14] pools of carbon [3] population growth [11,92] purposeful carbon sequestration [4] purposeful sequestration [4] quantifiable mitigation strategies [14] rate of acidification [2] rates of leakage [4] recession of the boreal forest [6] reduce energy consumption in the HVAC [12] reduced precipitation [6] reduced soil respiration [7] reducing deforestation [15] reduction in DIC growth [2] regional carbon budget [11] regional changes in vegetation structure [6] reporting country inventory practices [9] reporting requirements [9] Page 5 of 18 (page number not for citation purposes) Carbon Balance and Management 2007, 2:1 http://www.cbmjournal.com/content/2/1/1 reservoir to purposefully sequester carbon [4] response of marine organisms to pH changes [2] response of vegetation [7] responses of plant functional types to climate [6] responses to a warming climate [3] retention of forests [15] rising acidity of the ocean [3] robust assessment [6] salinity [2] saturation state of calcium carbonate [3] sea-ice extent [2] sectoral groups of energy [9] sensitivity of future oceanic acidification [2] sensitivity of heterotrophic respiration to soil moisture [7] sensitivity to natural disturbances [6] sequestration efficiency [4] shifts in spatial rainfall distribution [7] short-lived plant parts [6] slow down climate change [6] SOC [14] socioeconomic drivers [6] soil crusting and compaction [14] soil microbial activity [7] soil organic carbon [14,108,109,112,115,130] soil organic matter [7,14,112,114] soil processes [7] soil respiration [3,6,7,16,84] soil survey [14] solubility induced changes [2] spatial distribution of vegetation [6] speciation of carbon within the ocean [2] species composition [6] steady state analysis [14] technological efficiency [11] temporal development of vegetation [6] temporal variability of heterotrophic respiration [7] terrestrial balances of carbon [6] terrestrial carbon balance [6] terrestrial carbon cycling [14] terrestrial carbon sink [6] terrestrial feedback on climate [6] terrestrial modulation of atmospheric carbon anomalies [7] terrestrial vegetation [6,52] the impact on soil respiration [3] the lack of actual country-specific information [9] the value of forest land [15] thermodynamic equilibration [2] transfer of CO2 from the atmosphere to the oceans [4] transition from temperate savannah to subtropical woodland [6] trophic structure of marine ecosystems [3] uncertainty of estimated emissions [9] UNFCCC [9] UNFCCC requirements [9] Urban and Regional Carbon Management [13] urban areas [11] Page 6 of 18 (page number not for citation purposes) Carbon Balance and Management 2007, 2:1 http://www.cbmjournal.com/content/2/1/1 urban territories [8,102] urban vegetation [8] urbanised ecosystem [8] urbanized areas [11] value of the regional network [9] variations in the CO2 growth rate [7] voluntary environmental management standard [11] vulnerable to rising temperatures [3] water-limitation of NPP [7] weakening oceanic sink [3] WGIA [9] wildfires [3] woody encroachment [6] world-wide cooling [7] Author index The list of names cited in the first volume of the journal provides some information about the research community involved in the study of the global carbon cycle either directly or indirectly. This information is intended for those who are considering Carbon Balance and Management as a medium for conveying their findings and evaluating whether they would be of sufficiently immediate interest to researchers in the broad range of disciplines associated with the studies of the global carbon cycle. Acock, B. [128] Adams, A.F.R. [112] Adams, D.E. [131] Aerts, K. [25] Alcamo, J. [41] Alder, J. [41] Alexandrov, G. [135] Alexandrov, G.A. [133,10] Amato, M. [123,132] Anderson, B. [80] Andren, O. [122] Angert, A. [74] Apps, M.J. [17] Arellano, A. [66] Arneth, A. [70] Asner, G.P. [71] Asshoff, R. [55] Aumont, O. [19] Aumont, O.L. [67] Bala, G. [50] Baldocchi, D.D. [75] Banks, H.T. [64] Barrett, D.J. [116] Barry, J.P. [24] Bazilevich, N.I. [89] Beaufort, L. [25] Benitez, P.C. [134,135] Benthien, A. [25] Berry, J.A. [83,82] Berthelot, M. [46] Betts, R. [50] Betts, R.A. [57,42,51,43] Bignucolo, O. [55] Biraud, S. [74] Birdsey, R. [71] Boden, T.A. [75] Page 7 of 18 (page number not for citation purposes) Carbon Balance and Management 2007, 2:1 http://www.cbmjournal.com/content/2/1/1 Bondeau, A. [43,70] Bonfils, C. [74] Bopp, L. [50,67,19] Bousquet, P. [67,76,65] Boutin, J. [36] Brewer, P.G. [24] Brovkin, V. [43,50] Buck, K.R. [24] Buermann, W. [74,80,76] Bullister, J.L. [34] Cadule, P. [50] Caldeira, K. [20] Campbell, J. [16] Canadell, J. [129] Canan, P. [13] Catton, W.R. [91] Chou, L. [25] Ciais, P. [46,67,65] Coleman, K. [120] Collatz, G. [66] Collatz, G.J. [83,77] Collins, M. [51] Colunga-Garcia, M. [108] Cooper, C. [64] Cornelissen, J.H.C. [16] Cox, P. [50] Cox, P.M. [57,42,51,43,44] Cramer, J.C. [92] Cramer, W. [41,43,56,76,6,47,70] Crill, P. [79] Cure, J.D. [128] da Rocha, H.R. [79] Dala, O.E. [129] Dale, V.H. [110] Daube, B.C. [79] Davidson, E.A. [81] Davis, M. [78] de Camargo, P.B. [79] de Freitas, H.C. [79] DeAngelis, D.L. [110] DeFries, R. [86] DeFries, R.S. [77] Delille, B. [25] Diamond, L. [94] Dickinson, R.E. [80,1] Dickson, A.G. [39] Dietz, T. [95,104] Dix, M.R. [31] Doney, S. [50] Doney, S.C. [19] Drapek, R.J. [59] Dufresne, J.L. [46,44] Duncan, O.D. [96] Dunlap, R.E. [91] Eby, M. [50] Ehrlich, P. [98] Page 8 of 18 (page number not for citation purposes) Carbon Balance and Management 2007, 2:1 http://www.cbmjournal.com/content/2/1/1 Eichhout, B. [60] Ellsworth, D.S. [54] Emanuel, W.R. [110] Engel, A. [25] Erbrecht, T. [7,6] Erlinger, J.R. [129] Ewert, F. [118] Fabry, V.J. [19] Farquhar, G.D. [82,88] Fasham, M.J.R. [88] Feely, R.A. [19] Field, C. [71] Fisher, V. [43] Foley, J.A. [43,85,136] Francey, R. [67] Friedlingstein, P. [46,44,50,76,65] Friend, A.D. [43] Fung, I. [74,50] Gage, S.H. [109,108] Garcia, H.E. [35] Gattuso, J.P. [25] GCTE, N.E.W.S. [16] Genovese, V. [73] Gerber, S. [61,49] Gerten, D. [52,56,47,87] Gifford, R.M. [117] Giglio, L. [77,66] Gnanadesikan, A. [19] Gordon, C. [64] Gordon, H.B. [30] Goulden, M.L. [88,79] Grace, P.R. [109,14,108,132] Grant, R.F. [125] Gregory, J.M. [64] Gruber, N. [36,19,65] Gu, L. [75] Gurevitch, J. [16] Haberlandt, U. [52] Hanaoka, T. [106] Hansen, J. [68] Hansen, M. [86] Hansen, P.J. [27,28] Harlay, J. [25] Harris, P.P. [57,51] Hart, J.L. [93] Hartley, A.E. [16] Hashimoto, H. [72] Hasselmann, K. [49] Hattenschwiler, S. [55] Haugen-Korzyra, K.L. [125] Hausman, J.A. [97] Heemann, C. [25] Heimann, M. [45,67,88] Hennessy, K. [14] Heyder, U. [6] Hicke, J.A. [71] Page 9 of 18 (page number not for citation purposes) Carbon Balance and Management 2007, 2:1 http://www.cbmjournal.com/content/2/1/1 Hickler, T. [56,78] Hiederer, R. [118,119] Hiley, J.C. [125] Hirst, A.C. [30,18] Hoffmann, L. [25] Hogg, E.H. [58] Holdren, J.P. [98] Holland, E. [71] Hooss, G. [49] Houghton, R.A. [45] House, J.I. [45] Hulme, M. [63] Huntingford, C. [57,51] Hutyra, L. [79] Ikaga, T. [105] Isbell, R.F. [114] Ishida, A. [19] Ishimatsu, A. [26] Izaurralde, R.C. [125] Jackson, R.B. [129] Jacquet, S. [25] Jans, D.C. [125] Janssens, I.A. [81] Jaramillo, V.J. [88] Jenkins, J.C. [71] Jenkinson, D.S. [120,130,131] John, J. [50] Johns, T.C. [64] Jolly, W.M. [72] Jones, C. [50] Jones, C.D. [57,42,51] Jones, P.D. [63] Jones, R. [119] Jones, R.J.A. [118] Joos, F. [50,61,49,19] Kainuma, M. [106] Kankaanpaa, S. [119] Kaplan, J.O. [70] Karl, T.R. [40] Kasibhatla, P. [77,66] Kasischke, E. [66] Kasischke, E.S. [77] Kato, S. [105] Kato, T. [50] Katterer, T. [122] Kawamiya, M. [50] Keel, S.G. [55] Keeling, C.D. [67,72] Keeling, R.F. [35,67] Keller, M. [79] Kern, J.S. [115] Key, R.M. [34,36,19] Kheshgi, H. [67] Kheshgi, H.S. [88] Kikkawa, T. [26] Kindermann, G. [15] Page 10 of 18 (page number not for citation purposes) Carbon Balance and Management 2007, 2:1 http://www.cbmjournal.com/content/2/1/1 King, A.W. [124,110] Kirchhoff, V. [79] Kita, J. [26] Klooster, S. [73] Knorr, W. [50] Koch, G.W. [54] Kolp, P. [106] Korner, C. [55] Kraxner, F. [135] Kubiske, M.E. [54] Kucharik, C. [43] Kuhnz, L. [24] Kumar, V. [73] Kurz, W.A. [17] Ladd, J.N. [123,109,132] Langenbuch, M. [29] Le Quere, C. [67,36,88] Lebel, L. [99] Leemans, R. [60] Levis, S. [70] Lieth, H. [126] Lindner, M. [119] Lindsay, A.M. [111] Lindsay, K. [50,19] Lloyd, J. [84] Lomas, M.R. [43,48] London, B. [100] Los, S. [71] Lovera, C.F. [24] Lucht, W. [80,7,52,56,76,6,47,70,87] Luo, Y.Q. [53] Maier-Reimer, E. [36,19] Marchetti, C. [32] Marion, G.M. [16] Masui, T. [41] Matear, R. [2,19] Matear, R.J. [18,34] Matross, D.M. [79] Matsumoto, K. [4] Matthews, H.D. [50] McCallum, I. [15,135] McGill, W.B. [125] McKinley, G. [65] McNeil, B.I. [34,2,5] McPhaden, J. [69] McSweeney, K. [136] Menton, M. [79] Meyer, J. [119] Meyer, R. [49] Michalsky, J.J. [75] Mikolajewicz, U. [36] Miller, J.B. [77] Miller, S.D. [79] Millero, F.J. [39] Milligan, C.L. [21] Mitchell, J.F.B. [64] Page 11 of 18 (page number not for citation purposes) Carbon Balance and Management 2007, 2:1 http://www.cbmjournal.com/content/2/1/1 Mitchell, M.J. [16] Monfray, P. [46,36,19] Montanarella, L. [118,119] Mooney, H.A. [129] Moorcroft, P.R. [62] Mouchet, A. [19] Munger, J.W. [75,79] Murakami, S. [105] Myneni, R.B. [80,76,72,73] Najjar, R.G. [19] Nakicenovic, N. [106] Naumburg, E.S. [54] Neilson, R.P. [59] Nejstgaard, J. [25] Nemani, R.R. [72] New, M.G. [63] Nix, H.A. [113] Norby, R.J. [53,16] Norman, J. [136] Obersteiner, M. [134,15,135] Ofarrell, S.P. [30,31] Oikawa, T. [133] Olsen, S. [66] Orr, J.C. [36,19] Pacala, S. [33] Palmer, J. [36] Parton, W.J. [121] Pathe, C. [87] Pedersen, M.F. [27,28] Pelez-Riedl, S. [55] Peltzer, E.T. [24] Peng, T.H. [110] Pepin, S. [55] Peylin, P. [67,65] Piper, S.C. [67,72] Pittock, A.B. [113] Pizay, M.D. [25] Plattner, G.K. [49,19] Polglase, P.J. [127] Pomaz, V.L. [102] Portner, H.O. [29] Post, W.M. [14,124,110] Potter, C.S. [80,73] Prentice, I.C. [43,61,45,49,67,76,88,47,70] Probert, M.E. [114] Pyle, E.H. [79] Quere, C.L. [65] Raddatz, T. [50] Ramankutty, N. [43,45,136] Rametsteiner, E. [15] Randerson, J. [66] Randerson, J.T. [71,77] Rasmussen, P.E. [121] Rayner, P. [44,50,65] Rayner, P.J. [67] Reginster, I. [118,119] Page 12 of 18 (page number not for citation purposes) Carbon Balance and Management 2007, 2:1 http://www.cbmjournal.com/content/2/1/1 Reich, P.B. [54] Reick, C. [50] Reipschlager, A. [29] Reynolds, R. [68] Riahi, K. [106,135] Ribas-Carbo, M. [83] Rice, A.H. [79] Riebesell, U. [25] Ringler, D.C. [41] Robertson, G.P. [109,108] Rochelle-Newall, E. [25] Rodgers, K.B. [19] Roeckner, E. [50] Rokityanskiy, D. [135] Rosa, E. [95,104] Rounsevell, M. [119] Rounsevell, M.D.A. [118] Rudolf, B. [87] Ruedy, R. [68] Running, S.R. [72] Rustad, L.E. [16] Sabine, C.L. [36,19] Safir, G.R. [108] Salameh, P.K. [37] Saleska, S.R. [79] Sarmiento, J.L. [34,36,19] Sato, M. [68] Schaphoff, S. [52,56,6,47] Schellnhuber, H.J. [102,8] Schienke, E. [13] Schlesinger, W.H. [107] Schlitzer, R. [19] Schneider, U. [25] Schnur, R. [50] Scholes, R.J. [88] Scholz, S. [11] Schulze, E.D. [129] Schulze, K. [41] Schwarz, A.G. [58] Scipal, K. [87] Seibel, B.A. [22,23] Senior, C.A. [64] Shandra, J.M. [100] Shiraishi, Y. [105] Siegwolf, R.T.W. [55] Silva, H. [79] Sitch, S. [43,52,49,76,65,47,70] Slater, R.D. [19] Smith, B. [43,78,76,70] Smith, J.U. [118,119] Smith, P. [118,119] Smith, S.D. [54] Snitzler, K.G. [50] Socolow, R. [33] Sohlberg, R. [86] Sonnerup, R.E. [38] Page 13 of 18 (page number not for citation purposes) Carbon Balance and Management 2007, 2:1 http://www.cbmjournal.com/content/2/1/1 Soule, P. [93] Spain, A.V. [114] Spall, S.A. [42] Steffen, W. [3] Still, C.J. [77] Strassmann, K. [50] Strengers, Y. [101] Sugita, S. [78] Svirejeva-Hopkins, A. [102,8] Svirezhev Yu, M. [90] Sykes, M.T. [78,70] Tan, P. [73] Taylor, J.A. [84] Taylor, N.K. [36] Terbrueggen, A. [25] Thonicke, K. [70] Toggweiler, J.R. [36] Totterdell, I.J. [42,19] Townshend, J.R.G. [86] Trenbreth, K.E. [40] Tucker, C. [71] Tucker, C.J. [80,72] Umemiya, C. [9] Urbanski, S.P. [75] Van der Werf, G. [66] Van der Werf, G.R. [77] van Veen, J.A. [132] van Vuuren, D. [41] Venevsky, S. [70] von Bloh, W. [50] von Caemmerer, S. [82] Wagner, W. [56,87] Waley, P. [103] Walker, K. [78] Walker, S.J. [37] Walker, T.W. [112] Wallace, D.W.R. [88] Walsh, P.J. [22,23,21] Walz, P. [24] Wang, Y.P. [127] Wattenbach, M. [118,119] Watterson, I.G. [31] Weaver, A.J. [50] Weirig, M.F. [19] Weiss, R.F. [37] Whaling, P.J. [24] White, A. [43] White, J.W.C. [77] Whooley, O. [100] Wickett, M.E. [20] Wild, A. [131] Williamson, J. [100] Wofsy, S.C. [75,79] Wood, R.A. [64] Woodward, F.I. [43,48] Wullschleger, S.D. [124] Page 14 of 18 (page number not for citation purposes) Carbon Balance and Management 2007, 2:1 http://www.cbmjournal.com/content/2/1/1 Yamagata, Y. [133,135]Yamanaka, Y. [19]Yool, A. [19]York, R. [104]Yoshida, Y. [12]Yoshikawa, C. [50]Young-Molling, C. [43]Zaehle, S. [118,119]Zeng, N. [50]Zondervan, I. [25]Zotz, G. [55]Additional material References1. Dickinson RE: Welcome to Carbon Balance and Management.Carbon Balance and Management 2006, 1:1.2. McNeil BI, Matear R: Projected climate change impact on oce-anic acidification. Carbon Balance and Management 2006, 1:2.3. Steffen W: The Anthropocene, global change and sleepinggiants: where on Earth are we going? Carbon Balance and Man-agement 2006, 1:3.4. Matsumoto K: A psychological effect of having a potentiallyviable sequestration strategy. Carbon Balance and Management2006, 1:4.5. McNeil BI: Significance of the oceanic CO2 sink for nationalcarbon accounts. Carbon Balance and Management 2006, 1:5.6. Lucht W, Schaphoff S, Erbrecht T, Heyder U, Cramer W: Terres-trial vegetation redistribution and carbon balance under cli-mate change. Carbon Balance and Management 2006, 1:6.7. Erbrecht T, Lucht W: Impacts of large-scale climatic distur-bances on the terrestrial carbon cycle. Carbon Balance and Man-agement 2006, 1:7.8. Svirejeva-Hopkins A, Schellnhuber HJ: Modelling carbon dynam-ics from urban land conversion: fundamental model of city inrelation to a local carbon cycle. Carbon Balance and Management2006, 1:8.9. Umemiya C: Improving GHG inventories by regional informa-tion exchange: a report from Asia. Carbon Balance and Manage-ment 2006, 1:9.10. Alexandrov GA: The purpose of peer review in the case of anopen-access publication. Carbon Balance and Management 2006,1:10.11. Scholz S: The POETICs of industrial carbon dioxide emissionsin Japan: an urban and institutional extension of the IPATidentity. Carbon Balance and Management 2006, 1:11.12. Yoshida Y: Development of air conditioning technologies toreduce CO2 emissions in the commercial sector. Carbon Bal-ance and Management 2006, 1:12.13. Canan P, Schienke E: Responsibility, opportunity, and vision forhigher education in urban and regional carbon management.Carbon Balance and Management 2006, 1:13.14. Grace PR, Post WM, Hennessy K: The potential impact of cli-mate change on Australia's soil organic carbon resources.Carbon Balance and Management 2006, 1:14.15. Kindermann G, Obersteiner M, Rametsteiner E, McCallum I: Pre-dicting the deforestation-trend under different carbon-prices. Carbon Balance and Management 2006, 1:15.16. Rustad LE, Campbell J, Marion GM, Norby RJ, Mitchell MJ, Hartley AE,Cornelissen JHC, Gurevitch J, GCTE NEWS: A meta-analyses ofthe response of soil respiration, net N mineralization, andaboveground plant growth to experimental ecosystemwarming. Oecologia 2000, 126:543-562.17. Kurz WA, Apps MJ: A 70-year retrospective analysis of carbonfluxes in the Canadian forest sector. Ecological Applications 1999,9:526-547.18. Matear RJ, Hirst AC: Climate change feedback on the futureoceanic CO2 uptake. Tellus Ser B-Chem Phys Meteorol 1999,51:722-733.19. Orr JC, Fabry VJ, Aumont O, Bopp L, Doney SC, Feely RA, Gnan-adesikan A, Gruber N, Ishida A, Joos F, Key RM, Lindsay K, Maier-Reimer E, Matear R, Monfray P, Mouchet A, Najjar RG, Plattner GK,Rodgers KB, Sabine CL, Sarmiento JL, Schlitzer R, Slater RD, Totter-dell IJ, Weirig MF, Yamanaka Y, Yool A: Anthropogenic oceanacidification over the twenty-first century and its impact oncalcifying organisms. Nature 2005, 437:681-686.20. Caldeira K, Wickett ME: Anthropogenic carbon and ocean pH.Nature 2003, 425:365.21. Walsh PJ, Milligan CL: Coordination of Metabolism and Intrac-ellular Acid-Base Status – Ionic Regulation and MetabolicConsequences. Canadian Journal of Zoology-Revue Canadienne DeZoologie 1989, 67:2994-3004.22. Seibel BA, Walsh PJ: Carbon cycle – Potential, impacts of CO2injection on deep-sea biota. Science 2001, 294:319-320.23. Seibel BA, Walsh PJ: Biological impacts of deep-sea carbondioxide injection inferred from indices of physiological per-formance. Journal of Experimental Biology 2003, 206:641-650.24. Barry JP, Buck KR, Lovera CF, Kuhnz L, Whaling PJ, Peltzer ET, WalzP, Brewer PG: Effects of direct ocean CO2 injection on deep-sea meiofauna. Journal of Oceanography 2004, 60:759-766.25. Engel A, Zondervan I, Aerts K, Beaufort L, Benthien A, Chou L, DelilleB, Gattuso JP, Harlay J, Heemann C, Hoffmann L, Jacquet S, Nejst-gaard J, Pizay MD, Rochelle-Newall E, Schneider U, Terbrueggen A,Riebesell U: Testing the direct effect of CO2 concentration ona bloom of the coccolithophorid Emiliania huxleyi in meso-cosm experiments. Limnology and Oceanography 2005, 50:493-507.26. Kikkawa T, Ishimatsu A, Kita J: Acute CO2 tolerance during theearly developmental stages of four marine teleosts. Environ-mental Toxicology 2003, 18:375-382.27. Pedersen MF, Hansen PJ: Effects of high pH on a natural marineplanktonic community. Marine Ecology-Progress Series 2003,260:19-31.28. Pedersen MF, Hansen PJ: Effects of high pH on the growth andsurvival of six marine heterotrophic protists. Marine Ecology-Progress Series 2003, 260:33-41.29. Portner HO, Langenbuch M, Reipschlager A: Biological impact ofelevated ocean CO2 concentrations: Lessons from animalphysiology and earth history. Journal of Oceanography 2004,60:705-718.Additional File 1References to the journal articles cited in the first volume of the journal.This file is formatted for importing references into a reference database.Click here for file[http://www.biomedcentral.com/content/supplementary/1750-0680-2-1-S1.xml] Additional File 2The list of words and wordings selected from the articles published in thefirst volume of the journal.Click here for file[http://www.biomedcentral.com/content/supplementary/1750-0680-2-1-S2.txt] Page 15 of 18(page number not for citation purposes) Carbon Balance and Management 2007, 2:1http://www.cbmjournal.com/content/2/1/1 30. Hirst AC, Gordon HB, Ofarrell SP: Global warming in a coupledclimate model including oceanic eddy-induced advection.Geophysical Research Letters 1996, 23:3361-3364.31. Watterson IG, Ofarrell SP, Dix MR: Energy and water transportin climates simulated by a general circulation model thatincludes dynamic sea ice. Journal of Geophysical Research-Atmos-pheres 1997, 102(D10):11027-11037.32. Marchetti C: On geoengineering and the CO2 problem. ClimaticChange 1977, 1:59-68.33. Pacala S, Socolow R: Stabilization wedges: Solving the climateproblem for the next 50 years with current technologies. Sci-ence 2004, 305:968-972.34. McNeil BI, Matear RJ, Key RM, Bullister JL, Sarmiento JL: Anthropo-genic CO2 uptake by the ocean based on the global chlo-rofluorocarbon data set. Science 2003, 299:235-239.35. Keeling RF, Garcia HE: The change in oceanic O2 inventoryassociated with recent global warming. Proc Natl Acad Sci USA2002, 99:7848-7853.36. Orr JC, Maier-Reimer E, Mikolajewicz U, Monfray P, Sarmiento JL,Toggweiler JR, Taylor NK, Palmer J, Gruber N, Sabine CL, Le QuereC, Key RM, Boutin J: Estimates of anthropogenic carbon uptakefrom four three-dimensional global ocean models. Glob Bioge-ochem Cycle 2001, 15:43-60.37. Walker SJ, Weiss RF, Salameh PK: Reconstructed histories of theannual mean atmospheric mole fractions for the halocar-bons CFC-11, CFC-12, CFC-113 and carbon tetrachloride.Journal of Geophysical Research 2000, 105:14, 285-14, 296.38. Sonnerup RE: On the relations among CFC derived watermass ages. Geophys Res Lett 2001, 28:1739-1742.39. Dickson AG, Millero FJ: A Comparison of the Equilibrium-Con-stants for the Dissociation of Carbonic-Acid in SeawaterMedia. Deep-Sea Research Part a-Oceanographic Research Papers 1987,34:1733-1743.40. Karl TR, Trenbreth KE: Modern global climate change. Science2003, 302:1719-1723.41. Alcamo J, van Vuuren D, Ringler DC, Cramer W, Masui T, Alder J,Schulze K: Changes in nature's balance sheet: model-basedestimates of future worldwide ecosystem services. Ecologyand Society 2005, 10:19.42. Cox PM, Betts RA, Jones CD, Spall SA, Totterdell IJ: Accelerationof global warming due to carbon-cycle feedbacks in a cou-pled climate model. Nature 2000, 408:184-187.43. Cramer W, Bondeau A, Woodward FI, Prentice IC, Betts RA, BrovkinV, Cox PM, Fisher V, Foley JA, Friend AD, Kucharik C, Lomas MR,Ramankutty N, Sitch S, Smith B, White A, Young-Molling C: Globalresponse of terrestrial ecosystem structure and function toCO2 and climate change: Results from six dynamic globalvegetation models. Global Change Biology 2001:357-373.44. Friedlingstein P, Dufresne JL, Cox PM, Rayner P: How positive isthe feedback between climate change and the carbon cycle?Tellus 2003, 55B:692-700.45. House JI, Prentice IC, Ramankutty N, Houghton RA, Heimann M:Reconciling apparent inconsistencies in estimates of terres-trial CO2 sources and sinks. Tellus 2003, 55B:345-363.46. Berthelot M, Friedlingstein P, Ciais P, Dufresne JL, Monfray P: Howuncertainties in future climate change predictions translateinto future terrestrial carbon fluxes. Glob Change Biol 2005,1:959-970.47. Schaphoff S, Lucht W, Gerten D, Sitch S, Cramer W, Prentice IC:Terrestrial biosphere carbon storage under alternative cli-mate projections. Climatic Change 2006.48. Woodward FI, Lomas MR: Vegetation dynamics – simulatingresponses to climatic change. Biol Rev 2004, 79:643-670.49. Joos F, Prentice IC, Sitch S, Meyer R, Hooss G, Plattner GK, GerberS, Hasselmann K: Global warming feedbacks on terrestrial car-bon uptake under the Intergovernmental Panel on ClimateChange (IPCC) emission scenarios. Global Biogeochemical Cycles2001, 15:891-907.50. Friedlingstein P, Cox P, Betts R, Bopp L, von Bloh W, Brovkin V, Cad-ule P, Doney S, Eby M, Fung I, Bala G, John J, Jones C, Joos F, Kato T,Kawamiya M, Knorr W, Lindsay K, Matthews HD, Raddatz T, RaynerP, Reick C, Roeckner E, Snitzler KG, Schnur R, Strassmann K, WeaverAJ, Yoshikawa C, Zeng N: Climate-carbon cycle feedback anal-ysis: Results from the C4MIP model intercomparison. J Clim2006, 19:3337-3353.51. Cox PM, Betts RA, Collins M, Harris PP, Huntingford C, Jones CD:Amazonian forest dieback under climate-carbon cycle pro-jections for the 21st century. Theoretical and Applied Climatology2004, 78:137-156.52. Gerten D, Schaphoff S, Haberlandt U, Lucht W, Sitch S: Terrestrialvegetation and water balance: Hydrological evaluation of adynamic global vegetation model. Journal of Hydrology 2004,286:249-270.53. Norby RJ, Luo YQ: Evaluating ecosystem responses to risingatmospheric CO2 and global warming in a multi-factorworld. New Phytologist 2004, 162:281-293.54. Ellsworth DS, Reich PB, Naumburg ES, Koch GW, Kubiske ME, SmithSD: Photosynthesis, carboxylation and leaf nitrogenresponses of 16 species to elevated pCO2 across four free-airCO2 enrichment experiments in forest, grassland and desert.Global Change Biology 2004, 10:2121-2138.55. Korner C, Asshoff R, Bignucolo O, Hattenschwiler S, Keel SG, Pelez-Riedl S, Pepin S, Siegwolf RTW, Zotz G: Carbon flux and growthin mature deciduous forest trees exposed to elevatedCO2.Science 2005, 309:1360-1362.56. Gerten D, Lucht W, Schaphoff S, Cramer W, Hickler T, Wagner W:Hydrologic resilience of the terrestrial biosphere. Geophys ResLett 2005, 32:.57. Betts RA, Cox PM, Harris PP, Huntingford C, Jones CD: The role ofecosystem-atmosphere interactions in simulated Amazonforest dieback under global climate warming. Theoretical andApplied Climatology 2004, 78:157-175.58. Hogg EH, Schwarz AG: Regeneration of planted conifers acrossclimatic moisture gradients on the Canadian prairies: impli-cations for distribution and climate change. Journal of Biogeog-raphy 1997, 24:527-534.59. Neilson RP, Drapek RJ: Potentially complex biosphereresponses to transient global warming. Global Change Biology1998, 4:505-521.60. Leemans R, Eichhout B: Another reason for concern: regionaland global impacts on ecosystems for different levels of cli-mate change. Global Environmental Change 2004, 14:219-228.61. Gerber S, Joos F, Prentice IC: Sensitivity of a dynamic global veg-etation model to climate and atmosphericCO2. Global ChangeBiology 2004, 10:1223-1239.62. Moorcroft PR: How close are we to a predictive science of thebiosphere? Trends in Ecology and Evolution 2006, 21:400-407.63. New MG, Hulme M, Jones PD: Representing twentieth-centuryspace-time climate variability, Part II, Development of 1901–1996 monthly grids of terrestrial surface climate. Journal of Cli-mate 2000, 13:2217-2238.64. Gordon C, Cooper C, Senior CA, Banks HT, Gregory JM, Johns TC,Mitchell JFB, Wood RA: The simulation of SST, sea ice extentsand ocean heat transports in a version of the Hadley Centrecoupled model without flux adjustments. Climate Dynamics2000, 16:147-168.65. Peylin P, Bousquet P, Quere CL, Sitch S, Friedlingstein P, McKinley G,Gruber N, Rayner P, Ciais P: Multiple constraints on regionalCO2 flux variations over land and oceans. Global BiogeochemicalCycles 2005:19.66. Van der Werf G, Randerson J, Collatz G, Giglio L, Kasibhatla P, Arel-lano A, Olsen S, Kasischke E: Continental-Scale Partitioning ofFire Emissions During the 1997 to 2001 El Nino/La NinaPeriod. Science 2004, 303:73-76.67. Le Quere C, Aumont OL, Bopp L, Bousquet P, Ciais P, Francey R,Heimann M, Keeling CD, Keeling RF, Kheshgi H, Peylin P, Piper SC,Prentice IC, Rayner PJ: Two decades of ocean CO2 sink and var-iability. Tellus 2003, 55B:649-656.68. Hansen J, Ruedy R, Sato M, Reynolds R: Global surface air tem-perature in 1995: Return to pre-Pinatubo level. GeophysicalResearch Letters 1996, 23:1665-1668.69. McPhaden J: Genesis and Evolution of the 1997–98 El Nino. Sci-ence 1999, 283:950-954.70. Sitch S, Smith B, Prentice IC, Arneth A, Bondeau A, Cramer W, Kap-lan JO, Levis S, Lucht W, Sykes MT, Thonicke K, Venevsky S: Evalu-ation of ecosystem dynamics, plant geography and terrestialcarbon cycling in the LPJ dynamic global vegetation model.Global Change Biology 2003, 9:161-185.71. Hicke JA, Asner GP, Randerson JT, Tucker C, Los S, Birdsey R, JenkinsJC, Field C, Holland E: Satellite-derived increases in net primary Page 16 of 18(page number not for citation purposes) Carbon Balance and Management 2007, 2:1http://www.cbmjournal.com/content/2/1/1 productivity across North America, 1982–1998. GeophysicalResearch Letters 2002, 29:69-73.72. Nemani RR, Keeling CD, Hashimoto H, Jolly WM, Piper SC, TuckerCJ, Myneni RB, Running SR: Climate-Driven Increases in GlobalTerrestial Net Primary Production from 1982 to 1999. Sci-ence 2003, 300:1560-1563.73. Potter CS, Klooster S, Myneni RB, Genovese V, Tan P, Kumar V:Continental-scale comparisons of terrestial carbon sinksestimated from satellite data and ecosystem modeling 1982–1998. Global and Planetary Change 2003, 39:201-213.74. Angert A, Biraud S, Bonfils C, Buermann W, Fung I:CO2 seasonalityindicates origins of post-Pinatubo sink. Geophysical Research Let-ters 2004:31.75. Gu L, Baldocchi DD, Wofsy SC, Munger JW, Michalsky JJ, Urbanski SP,Boden TA: Response of a Deciduous Forest to the MountPinatubo Eruption: Enhanced Photosynthesis. Science 2003,299:2035-2038.76. Lucht W, Prentice IC, Myneni RB, Sitch S, Friedlingstein P, Cramer W,Bousquet P, Buermann W, Smith B: Climate Control of the High-Latitude Vegetation Greening Trend and Pinatubo Effect.Science 2002, 296:1687-1689.77. Randerson JT, Van der Werf GR, Collatz GJ, Giglio L, Still CJ, Kasib-hatla P, Miller JB, White JWC, DeFries RS, Kasischke ES: Fire emis-sions from C3 and C4 vegetation and their influence oninterannual variability of atmospheric CO2 and delta13 CO2.Global Biogeochemical Cycles 2005:19.78. Hickler T, Smith B, Sykes MT, Davis M, Sugita S, Walker K: Using ageneralized vegetation model to simulate vegetationdynamics in northeastern USA. Ecology 2004, 85:519-530.79. Saleska SR, Miller SD, Matross DM, Goulden ML, Wofsy SC, da RochaHR, de Camargo PB, Crill P, Daube BC, de Freitas HC, Hutyra L, Kel-ler M, Kirchhoff V, Menton M, Munger JW, Pyle EH, Rice AH, Silva H:Carbon in Amazon Forests: Unexpected Seasonal Fluxesand Disturbance-Induced Losses. Science 2003, 302:1554-1557.80. Buermann W, Anderson B, Tucker CJ, Dickinson RE, Lucht W, PotterCS, Myneni RB: Interannual covariability in Northern Hemi-sphere air temperetures and greenness associated with ElNino-Southern Oscillation and the Arctic Oscillation. Journalof Geophysical Research 2003, 108:4396-4441.81. Davidson EA, Janssens IA: Temperature sensitivity of soil car-bon decomposition and feedbacks to climate change. Nature2006, 440:165-173.82. Farquhar GD, von Caemmerer S, Berry JA: A biochemical modelof photosynthetic CO2 assimilation in leaves of C3 species.Planta 1980, 149:78-90.83. Collatz GJ, Ribas-Carbo M, Berry JA: Coupled photosynthesis-stomatal conductancemodel for leaves of C4 plants. AustralianJournal of Plant Physiology 1992, 19:519-538.84. Lloyd J, Taylor JA: On the temperature dependence of soil res-piration. Functional Ecology 1994, 8:315-323.85. Foley JA: An equilibrium model of the terrestrial carbonbudget. Tellus 2005, 47B:310-319.86. Hansen M, DeFries R, Townshend JRG, Sohlberg R: Global landcover classification at 1 km spatial resolution using a classifi-cation tree approach. International Journal of Remote Sensing 2000,21:1331-1364.87. Wagner W, Scipal K, Pathe C, Gerten D, Lucht W, Rudolf B: Evalu-ation of the agreement between the first global remotelysensed soil moisture data with model and precipitation data.Journal of Geophysical Research 2003, 108:1-10.88. Prentice IC, Farquhar GD, Fasham MJR, Goulden ML, Heimann M, Jar-amillo VJ, Kheshgi HS, Le Quere C, Scholes RJ, Wallace DWR: Thecarbon cycle and atmospheric carbon dioxide. Climate Change2001: The Scientific Basis Contribution of Working Group I to the ThirdAssessment Report of the Intergovernmental Panel on Climate Change2001, 1:185-225.89. Bazilevich NI: Biogeochemisty of the Earth and functionalmodels of exchange processes in natural ecosystems. ModernConcepts and Problem of Biogeochemistry (Proceedings of the Biogeochem-ical Laboratory), Nauka Moscow 1979, 17:56-73.90. Svirezhev Yu M: Simple spatially distributed model of the glo-bal carbon cycle and its dynamic properties. Ecol Modelling2002, 155:53-69.91. Catton WR, Dunlap RE: Environmental Sociology: A New Par-adigm. American Sociologist 1978, 13:41-49.92. Cramer JC: Population Growth and Air Quality in California.Demography 1998, 35:45-56.93. Hart JL, Soule P: Does I = PAT Work in Local Places? ProfessionalGeographer 2000, 52:1-10.94. Diamond L: Rethinking Civil Society. Journal of Democracy 1994,5:5-17.95. Dietz T, Rosa E: Rethinking the Environmental Impacts of Pop-ulation, Affluence and Technology. Human Ecology Review 1994,1.2:277-300.96. Duncan OD: From Social System to Ecosystem. SociologicalInquiry 1961, 31:140-149.97. Hausman JA: Specification Tests in Econometrics. Econometrica1978, 46:1251-1271.98. Holdren JP, Ehrlich P: Human Population and the Global Envi-ronment. American Scientist 1974, 62:282-292.99. Lebel L: Social Change and CO2 Stabilization: Moving Awayfrom Carbon Cultures. SCOPE: The Global Carbon Cycle 2004,62:371-383.100. Shandra JM, London B, Whooley O, Williamson J: InternationalNongovernmental Organizations and CarbonDioxide Emis-sions in the Developing World: A Quantitative, Cross-National Analysis. Sociological Inquiry 2004, 74:520-545.101. Strengers Y: Environmental Culture Change in LocalGovern-ment: A Practised Perspective from the International Coun-cil for Local Environmental Initiatives – Australia/NewZealand. Local Environment 2004, 9:621-628.102. Svirejeva-Hopkins A, Schellnhuber HJ, Pomaz VL: Urbanised Terri-tories as a Specific Component of the Global Carbon Cycle.Ecological Modelling 2004, 173:295-312.103. Waley P: Ruining and Restoring Rivers: The State and CivilSociety in Japan. Pacific Affairs 2005, 78:.104. York R, Rosa E, Dietz T: STIRPAT, IPAT and ImPACT: Ana-lytic Tools for Unpacking the Driving Force of Environmen-tal Impacts. Ecological Economics 2003, 46:351-365.105. Ikaga T, Murakami S, Kato S, Shiraishi Y: Estimation of CO2 Emis-sion Associated with Building Construction and Operationtill 2050 in Japan: Study on Social Life Cycle Assessment ofBuildings and Cities. J Archt Plann Environ Eng 2000, 535:53-58.106. Nakicenovic N, Kolp P, Riahi K, Kainuma M, Hanaoka T: Assess-ment of Emissions Scenarios Revisited. Environmental Economicsand Policy Studies 2006, 7:137-173.107. Schlesinger WH: Carbon sequestration in soils. Science 1999,284:2095.108. Grace PR, Colunga-Garcia M, Gage SH, Robertson GP, Safir GR: Thepotential impact of agricultural management and climatechange on soil organic carbon resources in terrestrial eco-systems of the North Central Region of the United States.Ecosystems 2006, 9:816-827.109. Grace PR, Ladd JN, Robertson GP, Gage SH: SOCRATES – a sim-ple model for predicting long-term changes in soil organiccarbon in terrestrial ecosystems. Soil Biol Biochem 2005,38:1172-1176.110. Post WM, Peng TH, Emanuel WR, King AW, Dale VH, DeAngelis DL:The global carbon cycle. Amer Scient 1990, 78:310-326.111. Lindsay AM: Are Australian soils different? Proc Ecol Soc Aust1985, 14:83-97.112. Walker TW, Adams AFR: Studies on soil organic matter: I.Influence of phosphorus content of parent material on accu-mulation of carbon, nitrogen, sulphur and organic phospho-rus in grassland soils. Soil Sci 1958, 85:307-318.113. Pittock AB, Nix HA: The effect of changing climate on Austral-ian biomass production – a preliminary study. Clim Change1986, 8:243-255.114. Spain AV, Isbell RF, Probert ME: Soil organic matter. Soils: An Aus-tralian Viewpoint 1983:551-563.115. Kern JS: Spatial patterns of soil organic carbon in the contig-uous United States. Soil Sci Soc Am J 1994, 58:439-455.116. Barrett DJ: Steady state net primary productivity, carbonstocks and mean residence time of carbon in the Australianterrestrial biosphere. Global Biogeochem Cycles 2002, 116:1108.117. Gifford RM: Implications of the globally increasing atmos-pheric CO2 concentration and temperature for the Austral-ian terrestrial carbon budget: integration using a simplemodel. Aust J Bot 1992, 40:527-543.118. Smith JU, Smith P, Wattenbach M, Zaehle S, Hiederer R, Jones RJA,Montanarella L, Rounsevell MDA, Reginster I, Ewert F: Projected Page 17 of 18(page number not for citation purposes) Carbon Balance and Management 2007, 2:1http://www.cbmjournal.com/content/2/1/1 Publish with BioMed Central and everyscientist can read your work free of charge"BioMed Central will be the most significant development fordisseminating the results of biomedical research in our lifetime."Sir Paul Nurse, Cancer Research UKYour research papers will be:available free of charge to the entire biomedical communitypeer reviewed and published immediately upon acceptancecited in PubMed and archived on PubMed Centralyours — you keep the copyrightSubmit your manuscript here:http://www.biomedcentral.com/info/publishing_adv.aspBioMedcentralchanges in mineral soil carbon of European croplands andgrasslands, 1990–2080. Global Change Biol 2005, 11:2141-2152.119. Smith P, Smith JU, Wattenbach M, Meyer J, Lindner M, Zaehle S, Hie-derer R, Jones R, Montanarella L, Rounsevell M, Reginster I, Kankaan-paa S: Projected changes in mineral soil carbon of Europeanforests, 1990–2100. Canadian J Soil Sci 2006, 86:159-169.120. Coleman K, Jenkinson DS: RothC 26.3-A model for the turnoverof carbon in soil. Evaluation of Soil Organic Matter Models Using Long-Term Datasets (NATO ASI Series I Vol 38) 1990:237-246.121. Parton WJ, Rasmussen PE: Long term effects in crop manage-ment-fallow: II. Century model formulation. Soil Sci Soc Am J1994, 58:530-536.122. Katterer T, Andren O: The ICBM family of analytically solvedmodels of soil carbon, nitrogen and microbial biomassdynamics – descriptions and application examples. Ecol Mod2001, 136:191-207.123. Amato M, Ladd JN: Decomposition of 14C-labelled glucose andlegume materials in soils: Properties influencing the accu-mulation of organic residue C and microbial biomass C. SoilBiol Biochem 1992, 27:455-464.124. King AW, Post WM, Wullschleger SD: The potential response ofterrestrial carbon storage to changes in climate and atmos-phericCO2. Climatic Change 1997, 35:199-227.125. Izaurralde RC, Haugen-Korzyra KL, Jans DC, McGill WB, Grant RF,Hiley JC: Soil C dynamics: Measurement, simulation and site-to-region scale-up. Assessment Methods of Soil Carbon2001:553-575.126. Lieth H: Modeling the primary productivity of the world. Pri-mary Productivity of the Biosphere 1975:237-263.127. Polglase PJ, Wang YP: PotentialCO2-enhanced carbon storageby the terrestrial biosphere. Aust J Bot 1992, 40:641-656.128. Cure JD, Acock B: Crop responses to carbon dioxide doubling:a literature survey. Agric For Meteor 1986, 38:127-145.129. Jackson RB, Canadell J, Erlinger JR, Mooney HA, Dala OE, Schulze ED:A global analysis of root distributions for terrestrial biomes.Oecolog 1996, 108:389-411.130. Jenkinson DS: The turnover of organic carbon and nitrogen insoil. Phil Trans Roy Soc London [B] 1990, 329:361-368.131. Jenkinson DS, Adams DE, Wild A: Model estimates of CO2 emis-sions from soil in response to global warming. Nature 1991,351:304-306.132. Ladd JN, Amato M, Grace PR, van Veen JA: Simulation of 14Cturnover through the microbial biomass in soils incubatedwith 14C-labelled plant residues. Soil Biol Biochem 1995,27:777-783.133. Alexandrov GA, Yamagata Y, Oikawa T: Towards a model for pro-jecting Net Ecosystem Production of the world forests. Eco-logical Modelling 1999, 123:183-191.134. Benitez PC, Obersteiner M: Site identification for carbonsequestration in Latin America: A grid-based economicapproach. Forest Policy and Economics 2006, 8:636-651.135. Obersteiner M, Alexandrov G, Benitez PC, McCallum I, Kraxner F,Riahi K, Rokityanskiy D, Yamagata Y: Global Supply of Biomassfor Energy and Carbon Sequestration from Afforestation/Reforestation Activities. Mitigation and Adaptation Strategies forGlobal Change 2006:1381-2386.136. Ramankutty N, Foley JA, Norman J, McSweeney K: The global dis-tribution of cultivable lands: current patterns and sensitivityto possible climate change. Global Ecology & Biogeography 2002,11:377-392. Page 18 of 18(page number not for citation purposes)