Abstract
Vegetation dynamics could lead to changes in the global carbon and hydrology cycle, as well as feedbacks to climate change. This paper reviews the response of forest dynamics to climate change. Based on palaeoecological studies, we summarized the features and modes of vegetation response to climate change and categorized the impacts of climate change on vegetation dynamics as three types: climate stress on vegetation, buffer effects by non-climatic factors, and perturbation of the vegetation distribution by stochastic events. Due to the openness of the vegetation system and the integrated effects of both climatic and non-climatic factors, the vegetation-climate relationship deviates far from its equilibrium. The vegetation distribution shows a non-linear response to climate change, which also makes it difficult to quantify the modern vegetation distribution in terms of specific climatic factors. Past analog, space-for-time-substitution and Dynamic Global Vegetation Models (DGVMs) are three approaches to predicting the future vegetation distribution, but they have all been established on the assumption of vegetation-climate equilibrium. We propose that improving DGVMs is a future task for studies of vegetation dynamics because these are process-based models incorporating both disturbance (e.g. fire) and the variability in Plant Functional Types (PFTs). However, palaeoecological results should be used to test the models, and issues like spatial and temporal scale, complexity of climate change, effects of non-climatic factors, vegetation-climate feedback, and human regulation on vegetation dynamics are suggested as topics for future studies.
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References
Bonan, G B. Forests and climate change: Forcings, feedbacks, and the climate benefits of forests. Science, 2008, 320: 1444–1449
Pan Y, Canadell J G, Ciais P, et al. A large and persistent carbon sink in the world’s forests. Science, 2011, 333: 988–993
Gerten D, Schaphoff S, Haberlandt U, et al. Terrestrial vegetation and water balance-hydrological evaluation of a dynamic global vegetation model. J Hydrol, 2004, 286: 249–270
Claussen M. Late Quaternary vegetation-climate feedbacks. Clim Past, 2009, 5: 203–216
Harris J A, Hobbs R J, Higgs E, et al. Ecological restoration and global climate change. Restor Ecol, 2006, 14: 170–176
Zhang P, Shao G, Zhao G, et al. China’s forest policy for the 21st century. Science, 2000, 288: 2135–2136
Petit R J, Hu F S, Dick C W. Forests of the past: a window to future changes. Science, 2008, 320: 1450–1452
Spellerberg I A, Sawyer J W D. An Introduction to Applied Biogeography. Cambridge: Cambridge University Press, 1999
Whittaker R J, Araújo M B, Jepson P, et al. Conservation biogeography: Assessment and prospect. Divers Distrib, 2005, 11: 3–23
Delcourt H R, Delcourt P A. Quaternary Ecology: A Palaeoecological Perspective. London: Chapman and Hall, 1991
Walker L R, del Moral R. Primary Succession and Ecosystem Rehabilitation. Cambridge: Cambridge University Press, 2003
Bertrand R, Lenoir J, Piedallu C, et al. Changes in plant community composition lag behind climate warming in lowland forests. Nature, 2011, 479: 517–520
Zhu K, Woodall C W, Clark J S. Failure to migrate: Lack of tree range expansion in response to climate change. Glob Chan Biol, 2012, 18: 1042–1052
Zhao X, Zhou D, Fang J. Satellite-based studies on large-scale vegetation changes in China. J Integr Plant Biol, 2012, 54: 713–728
Swetnam T W, Betancourt J L. Mesoscale disturbance and ecological response to decadal climatic variability in the American Southwest. In: Stoffel M, Bollschweiler M, Butler D, et al. eds. Tree Rings and Natural Hazards. Berlin-Heidelberg: Springer, 2010. 329–359
Liu H. Quaternary Ecology and Global Change (in Chnese). Beijing: Science Press, 2002
Marcott S A, Shakun J D, Clark, P U, et al. A reconstruction of regional and global temperature for the past 11300 years. Science, 2013, 339: 1198–1201
Birks H J B. Holocene isochrone maps and patterns of tree-spreading in the British isles. J Biogeog, 1989, 16: 503–540
King G A, Herstrom A A. Holocene tree migration rates objectively determined from fossil pollen data. In: Huntley B, ed. Past and Future Rapid Environmental Change: The Terrestrial and Evolutionary Processes of Terrestrial Biota. Berlin-Heidelberg: Springer Verlag, 1997
Parducci L, Jørgensen T, Tollefsrud M. Glacial survival of boreal trees in northern Scandinavia. Science, 2012, 335: 1083–1086
Hu F S, Hampe A, Petit R J. Paleoecology meets genetics: deciphering past vegetational dynamics. Front Ecol Environ, 2009, 7: 371–379
Stewart J R, Lister A M, Barnes I, et al. Refugia revisited: individualistic responses of species in space and time. Proc R Soc Bio Sci, 2009, 277: 661–671
Qiu Y, Fu C, Comes H P. Plant molecular phylogeography in China and adjacent regions: Tracing the genetic imprints of Quaternary climate and environmental change in the world’s most diverse temperate flora. Molec Phylogen Evol, 2011, 59: 225–244
Iversen J. The bearing of glacial and interglacial epochs on the formation and extinction of plant taxa. Uppsala Univ Arssk, 1958, 6: 210–215
Birks H J B, Birks H H. The rise and fall of forests. Science, 2004, 305: 484–485
Wardle D A, Walker L R, Bardgett, R D. Ecosystem properties and forest decline in contrasting long-term chronosequences. Science, 2004, 305: 509–513
Liu H, Xu L, Cui H. Holocene history of desertification along the woodland-steppe border in northern China. Quat Res, 2002, 57: 259–270
Dykoski C A, Edwards R L, Cheng H, et al. A high-resolution, absolute-dated Holocene and deglacial Asian monsoon record from Dongge Cave, China. Earth Planet Sci Lett, 2005, 233: 71–86
Zhao Y, Yu Z, Chen F, et al. Vegetation response to Holocene climate change in monsoon-influenced region of China. Earth Sci Rev, 2009, 97: 242–256
Zhao Y, Yu Z. Vegetation response to Holocene climate change in East Asian monsoon-margin region. Earth Sci Rev, 2012, 113: 1–10
Carrión J S, Munuera M, Dupré M, et al. Abrupt vegetation changes in the Segura Mountains of Southern Spain throughout the Holocene. J Ecol, 2001, 89: 783–797
Kropelin S, Verschuren D, Lézine A, et al. Climate-driven ecosystem succession in the Sahara: The past 6000 years. Science, 2008, 320: 765–768
Davis M B. Climatic instability, time lags, and community disequilibrium, In: Diamond J, Case T J, eds. Community Ecology. New York: Harper and Row, 1986. 269–284
Williams J W, Shuman B N, Web III T, et al. Late-Quaternary vegetation dynamics in North America: Scaling from taxa to biomes. Ecol Monog, 2004, 74: 309–334
Williams J W, Shuman B N, Webb III T. Dissimilarity analyses of Late-Quaternary vegetation and climate in eastern North America. Ecology, 2001, 82: 3346–3362
Araújo M B, Pearson R G. Equilibrium of species’ distributions with climate. Ecography, 2005, 28: 693–695
Moss R H, Edmonds J A, Hibbard K A, et al. The next generation of scenarios for climate change research and assessment. Nature, 2010, 463: 747–756
Cole K L, Vegetation response to early Holocene warming as an analog for current and future Changes. Conserv Biol, 2009, 24: 29–37
Giesecke T, Hickler T, Kunkel T, et al. Towards an understanding of the Holocene distribution of Fagus sylvatica L. J Biogeog, 2007, 34: 118–131
Miller P, Giesecke T, Hickler T, et al. Exploring climatic and biotic controls on Holocene vegetation change in Fennoscandia. J Ecol, 2008, 96: 247–259
Araújo M B, Nogués-Bravo D, Diniz-Filho J A F, et al. Quaternary climate changes explain diversity among reptiles and amphibians. Ecography, 2008, 31: 8–15
Sandel B, Arge L, Dalsgaard B, et al. The influence of Late Quaternary climate-change velocity on species endemism. Science, 2011, 33: 660–664
Liu H, Cui H, Yu P, et al. The origin of remnant forest stands of Pinus tabulaeformis in southeastern Inner Mongolia, China. Plant Ecol, 2002, 158: 139–151
Ewing H A. The influence of substrate on vegetation history and ecosystem development. Ecology, 2002, 83: 2766–2781
Camill P, Clark J S. Long-term perspectives on lagged ecosystem responses to climate change: Permafrost in boreal peatlands and the grassland/woodland boundary. Ecosystems, 2000, 3: 534–544
He N, Wu L, Wang Y, et al. Changes in carbon and nitrogen in soil particle-size fractions along a grassland restoration chronosequence in northern China. Geoderma, 2009, 150: 302–308
Yin Y, Liu H, He S, et al. Patterns of local and regional grain size distribution and their application to Holocene climate reconstruction in semiarid Inner Mongolia, China. Palaeogeogr Palaeoclimatol Palaeoecol, 2011, 307: 168–176
Gehrig-Fasel J, Guisan A, Zimmermann N E. Tree line shifts in the Swiss Alps: Climate change or land abandonment? J Veget Sci, 2009, 18: 571–582
Sherrer D, Körner Ch. Topographically controlled thermal-habitat differentiation buffers alpine plant diversity against climate warming. J Biogeog, 2011, 38: 406–416
Gill J L, Williams J W, Jackson S T, et al. Pleistocene megafaunal collapse, novel plant communities, and enhanced fire regimes in North America. Science, 2009, 326: 1100–1103
Lang, G. Quatäre Vegetaionsgeschichte Europas. Gustav Fischer Verlag, Jena, 1994
Motz J E, Morgan A V. Holocene paleoclimate and paleoecology determined from fossil Coleoptera at Brampton, Ontario, Canada. Canadian J Earth Sci, 2001, 38: 1451–1462
Girling M A. The bark beetle Scolytus scolytus (Fabricius) and the possible role of elm disease in the early Neolithic. In: Jone M, ed. Archaeology and the Flora of the British Isles. Oxford: Oxford University Committee for Archaeology Monograph, 1988, 14: 34–38
Wilkinson D M. Mycorrizal fungi and Quaternary plant migrations? Glob Ecol Biogeog Lett, 1998, 7: 137–140
Nunez M A, Horton T R, Simberloff D. Lack of belowground mutualisms hinders Pinaceae invasions. Ecology, 2009, 90: 2353–2359
Fabina N S, Abbott K C, Gilman R T. Sensitivity of plant-pollinator-herbivore communities to changes in phenology. Ecol Model, 2010, 221: 453–458
Brown K J, Clark J S, Grimm C, et al. Fire cycles in North American interior grasslands and their relation to prairie drought. Proc Natl Acad Sci USA, 2005, 102: 8865–8870
Walther G R, Post E, Convey P, et al. Ecosystem response to recent climate change. Nature, 2002, 416: 389–395
Liang E, Wang Y, Eckstein D, et al. Little change in the fir tree-line position on the southeastern Tibetan Plateau after 200 years of warming. New Phytol, 2011, 190: 760–769
Wang T, Zhang Q, Ma K. Treeline dynamics in relation to climatic variability in the central Tianshan Mountains, northwestern China. Glob Ecol Biogeog, 2006, 15: 406–415
Van Auken O W. Causes and consequences of woody plant encroachment into western North American grasslands. J Environ Manage, 2009, 90: 2931–2942
Allen C D, Hogg E H, Gonzalez P, et al. A global overview of drought and heat-induced tree mortality reveals emerging climate change risks for forests. Forest Ecol Manage, 2010, 259: 660–684
Williams A P, Allen C D, Macalady A K, et al. Temperature as a potent driver of regional forest-drought stress and tree mortality. Nat Clim Chan, 2013, 3: 292–297
Ciais P, Reichstein M, Viovy N, et al. 2005 Europe-wide reduction in primary productivity caused by the heat and drought in 2003. Nature, 2005, 437: 529–533
Liu G, Liu H, Yin Y. Global patterns of NDVI-indicated vegetation extremes and their sensitivity to climate extremes. Enviorn Res Lett, 2013, 8: 025009
Chiarucci A, Araújo M B, Decocq G, et al. The concept of potential natural vegetation: An epitaph? J Veget Sci, 2010, 21: 1172–1178
Loidi J, Fernández-González F, Palmer M. Potential natural vegetation: Reburying or reboring? J Veget Sci, 2012, 23: 596–604
Fox D. Back to the no-analog future. Nature, 2007, 316: 823–824
Hendersen-Sellers A. Global terrestrial vegetation “prediction”: the use and abuse of climate and application models. Prog Phys Geog, 1994, 18: 209–246
Box E O. Predicting physiognomic vegetation types with climate variables. Vegetatio, 1981, 45: 127–139
Emanuel W R, Shugart H H, Stevenson M P. Climatic change and the broad-scale distribution of terrestrial ecosystem complexes. Clim Chan, 1985, 7: 29–43
Sitch S, Smith B, Prentice I C, et al. Evaluation of ecosystem dynamics, plant geography and terrestrial carbon cycling in the LPJ dynamic global vegetation model. Glob Chan Biol, 2003, 9: 161–185
Prentice I C, Bondeau A, Cramer W, et al. Dynamic global vegetation modeling: quantifying terrestrial ecosystem responses to large-scale environmental change. In: Canadell J G, Pataki D E, Pitelka L T, eds. Terrestrial Ecosystems in a Changing World. Berlin-New York: Springer, 2007. 175–192
Prentice I C, Jolly D, BIOME 6000 Participants. Mid-Holocene and glacial-maximum vegetation geography of the northern continents and Africa. J Biogeog, 2000, 27: 507–519
Lucht W, Schaphoff S, Erbrecht T, et al. Terrestrial vegetation redistribution and carbon balance under climate change. Carb Balan Manag, 2006, 1: doi:10.1186/1750-0680-1-6
DeFries R, Hansen M, Townshend J, et al. A new global 1-km dataset of percentage tree cover derived from remote sensing. Glob Chan Biol, 2001, 6: 247–254
Hansen M, Townshend J, DeFries R, et al. Estimation of tree cover using MODIS data at global. continental and regional/local scales. Int J Rem Sens, 2005, 26: 4359–4380
IPCC. Climate Change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel of Climate Change. Geneva: IPCC, 2007
Fang X, Hou G. Integrated reconstruction of Holocene temperature series in China (in Chinese). Chin Geog Sci, 31: 385–393
Williams J W, Shuman B N, Bartlein P J. Rapid responses of the prairie-forest ecotone to early Holocene aridity in mid-continental North America. Glob Planet Chan, 2009, 66: 195–207
Williams J W, Shuman B N, Webb III T. Dissimilarity analyses of Late-Quaternary vegetation and climate in eastern North America. Ecology, 2001, 82: 3346–3362
Umbanhowar C E Jr, Camill P, Geiss C E, et al. Asymmetric vegetation responses to mid-Holocene aridity at the prairie-forest ecotone in south-central Minnesota. Quat Res, 2006, 66: 53–66
Freilich L E, Reich P B. Will environmental changes reinforce the impact of global warming on the rairie-forest border of central North America? Front Ecol Environ, 2009, 8: 371–378
Volez S D, Williams J W, Blois J L, et al. No-analog climates and shifting realized niches during the late quaternary: implications for 21st century predictions by species distribution models. Glob Chan Biol, 2012, 18: 1698–1713
Holdridge L R. Life Zone Ecology. San Jose: Tropical Science Center, 1967
Yin Y, Liu H, Hao Q, et al. Vegetation responses to mid-Holocene extreme drought events and subsequent long-term drought on the southeastern Inner Mongolia Plateau, China. Agr Forest Meteorol, 2013, 178–179: 3–9
Seneviratne S I, Corti T, Davin E L, et al. Investigating soil moisture-climate interactions in a changing climate: A review, Earth Sci Rev, 2010, 99: 125–161
Liu H, Cui H, Pott R, et al. Vegetation of the woodland-steppe ecotone in southeastern Inner Mongolia, China. J Veget Sci, 2000, 11: 525–532
Liu H, Yin Y, Zhu J, et al. How did forest respond to Holocene climate drying at the forest-steppe ecotone in northern China? Quat Int, 2010, 227: 46–52
Walter H. Ecology of Tropical and Subtropical Vegetation. Edinburgh: Oliver and Boyd, 1971
Scanlon T M, Albertson J D. Inferred controls on tree/grass composition in a savanna ecosystem: Combining 16-year normalized difference vegetation index data with a dynamic soil moisture model. Water Resour Res, 2003, 34: doi:10.1029/2002WR001881
Yin Y. Holocene vegetation evolution and its driving factors in the forest-steppe ecotone in the semi-arid region of China (in Chinese). Dissertation for the Doctoral Degree. Peking University, 2012
Cui H, Liu H, Dai J. Mountain Ecology and Alpine Timberline Research (in Chinese). Beijing: Science Press, 2005
D’Odorico P, He Y, Collins S, et al. Vegetation-microclimate feedbacks in woodland-grassland ecotones, Glob Ecol Biogeog, 2012, doi:10.1111/geb.12000
Holtmeier F-K. Mountain Timberline: Ecology Patchinees and Dynamics. Dordrecht-Boston-London: Kluwer Academic Publishers, 2003
Kirilenko A P, Belotelov N V, Bogaturev B G. Global model of vegetation migration: Incorporation of climatic variability. Ecol Model, 2000, 132: 125–133
Davis M B. Quaternary history and the stability of forest communities. In: West D C, Schugart H H, Botkin D B, eds. Forest Succession: Concepts and Application. New York: Springer, 1981. 132–153
Haxeltine A, Prentice I C. BIOME3: An equilibrium terrestrial biosphere model based on ecophysiological constraints, resource availability, and competition among plant functional types. Glob Biogeochem Cycle, 1996, 10: 693–709
Pearson R G, Dawson T P. Predicting the impacts of climate change on the distribution of species: Are bioclimate envelope models useful? Glob Ecol Biogeog, 2003, 12: 361–371
Fisher R, McDowell N, Purves D, et al. Assessing uncertainties in a second-generation dynamic vegetation model caused by ecological scale limitations. New Phytol, 2010, 187: 666–681
Dallmeyer A, Claussen M. The influence of land cover change in the Asian monsoon region on present-day and mid-Holocene climate. Biogeosciences, 2011, 8: 1499–1519
Lee X, Gu L, Katul G, et al. Observed increase in local cooling effect of deforestation at higher latitudes. Nature, 2011, 479: 384–387
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Liu, H., Yin, Y. Response of forest distribution to past climate change: An insight into future predictions. Chin. Sci. Bull. 58, 4426–4436 (2013). https://doi.org/10.1007/s11434-013-6032-7
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DOI: https://doi.org/10.1007/s11434-013-6032-7