Abstract
Biome models allow the results of experiments with atmospheric general circulation models to be translated into global maps of potential natural vegetation. The use of biome models as a diagnostic tool for palaeoclimate simulations can yield maps that are directly comparable with palaeoecological (pollen and plant macrofossil) records provided these records are “biomized”, i.e. assigned to biomes in a consistent way. This article describes a method for the objective biomization of pollen samples based on fuzzy logic. Pollen types (taxa) are assigned to one or more plant functional types (PFTs), then affinity scores are calculated for each biome in turn based on its list of characteristic PFTs. The pollen sample is assigned to the biome to which it has the highest affinity, subject to a tie-breaking rule. Modern pollen data from surface samples, reflecting present vegetation across Europe, are used to validate the method. Pollen data from dated sediment cores are then used to reconstruct European vegetation patterns for 6 ka. The reconstruction shows systematic differences from present that are consistent with previous interpretations. The method has proved robust with respect to human impacts on vegetation, and provides a rational way to interpret combinations of pollen types that do not have present-day analogs. The method demands minimal prior information and is therefore equally suitable for use in other regions with richer floras, and/or lower densities of available modern and fossil pollen samples, than Europe.
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References
Claussen M, Esch M (1994) Biomes computed from simulated climatologies. Clim Dyn 9:235–243
COHMAP Members (1988) Climatic changes of the last 18000 years: observations and model simulations. Science 241:1043–1052
Cuming MJ, Hawkins BA (1981) TERDAT: FNOC system for terrain data extraction and processing. Technical Report MII Project M-254 (Second edition), Fleet Numerical Oceanography Center. Monterey, CA. Meteorology International Incorporated
Foley JA (1994) Sensitivity of the terrestrial biosphere to climatic change: A simulation of the middle Holocene. Global biogeochemical cycles 8:405–425
Foley JA, Kutzbach JE, Coe MT, Levis S (1994) Feedbacks between climate and boreal forests during the mid-Holocene. Nature 371:52–54
Grimm EC (1988) Data analysis and display. In: Huntley B, Webb T III (eds) Vegetation history. Handbook of Vegetation Science 7, Kluwer, Dordrecht, pp 43–76
Guetter PJ, Kutzbach JE (1990) A modified Köppen classification applied to model simulations of glacial and interglacial climates. Clint Change 16:193–215
Guiot J, Harrison SP, Prentice IC (1993) Reconstruction of Holocene precipitation patterns in Europe using pollen and lake-level data. Quat Res 40:139–149
Harrison SP, Prentice IC, Bartlein PJ (1992). Influence of insolation and glaciation on atmospheric circulation in the North Atlantic sector: implications of general circulation model experiments for the Late Quaternary climatology of Europe. Quat Sci Rev 11:283–300
Haxeltine A, Prentice IC, Cresswell ID (1995) A coupled carbon and water flux model to predict vegetation structure. J Veg Sci (in press)
Huntley B (1990) European vegetation history: palaeovegetation maps from pollen data-13000y BP to present. J Veg Sci 5:103–122
Huntley B (1994) Late Devensian and Holocene palaeoecology and palaeoenvironments of the Morrone Birkwoods, Aberdeenshire, Scotland. J Quat Sci 9:311–336
Huntley B, Birks HJB (1983) An atlas of past and present pollen maps for Europe: 0–13000 years ago. Cambridge University Press, Cambridge, UK, 667 pp
Huntley B, Prentice IC (1988) July temperatures in Europe from pollen data, 6000 years before present. Science 241:687–690
Huntley B, Prentice IC (1993) Holocene vegetation and climates of Europe. In: Wright HE Jr, Kutzbach JE, Webb T III, Ruddiman WA, Street-Perrott FA, Bartlein PJ (eds) Global climates since the Last Glacial Maximum. University of Minnesota, Minneapolis, pp 136–168
Hutchinson MF (1989) A new objective method for spatial interpolation of meteorological variables from irregular networks applied to the estimation of monthly mean solar radiation, temperature, precipitation and windrun. Need for climatic and hydrologic data in agriculture in southeast Asia: vol 89/5, pp 95–104. CSIRO, Canberra, Australia
Iversen J (1944) Viscum, Hedera and Ilex as climatic indicators. Geol Foren Stockholm Förh 66:463–483
Kutzbach JE, Gallimore RG (1988) Sensitivity of a coupled atmosphere/mixed-layer ocean model to changes in orbital forcing at 9000 y ago. J Geophys Res 93:803–821
Kutzbach JE, Guetter PJ (1986) The influence of changing orbital parameters and surface boundary conditions on climate simulations for the past 18000 years. J Atmos Sci 43:1726–1759
Liao X, Street-Perrott A, Mitchell JFB (1994) GCM experiments with different cloud parameterization: comparisons with palaeoclimatic reconstructions for 6000 years BP Paleoclimates 1:99–123
Mitchell JFB, Grahame NS, Needham KJ (1989) Climate simulations for 9000 years before present: seasonal variations and effects of the Laurentide ice sheet. J Geophys Res 93:8283–8303
Neilson RP (1995) A model for predicting continental-scale vegetation distribution and water balance. Ecol Appl 5:362–385
NOAA-EPA Global Ecosystems Database Project (1992) Global Ecosystems Database, Version 1.0. USDOC/NOAA National Geophysical Data Center, Boulder, Colorado
Overpeck JT, Webb T III, Prentice IC (1985) Quantitative interpretation of fossil pollen spectra: dissimilarity coefficients and the method of modern analogs. Quat Res 23:87–108
Peng CH, Guiot J, van Campo E, Cheddadi R (1994) The vegetation carbon storage variation in Europe since 6000 BP: reconstruction from pollen. J Biogeogr 21:19–31
Prentice IC (1986) Multivariate methods for data analysis. In: Berglund BE (ed) Handbook of Holocene palaeoecology and palaeohydrology. Wiley, Chichester, pp 775–797
Prentice IC, Sykes MT (1994) Vegetation geography and carbon storage changes. In: Woodwell GM (ed) Biotic feedbacks in the global climate system: will the warming speed the warming? Oxford University Press, New York, pp 304–312
Prentice IC, Webb T III (1995) Global palaeovegetation data for climate-biosphere model evaluation. GAIM Report in press
Prentice IC, Cramer W, Harrison SP, Leemans R, Monserud RA, Solomon AM (1992) A global biome model based on plant physiology and dominance, soil properties and climate. J Biogeogr 19:117–134
Prentice IC, Sykes MT, Lautenschlager M, Harrison SP, Denissenko O, Bartlein PJ (1993) Modelling global vegetation patterns and terrestrial carbon storage at the last glacial maximum. Global Ecol Biogeogr Lett 3:67–76
Prentice KC (1990) Bioclimatic distribution of vegetation for general circulation model studies. J Geophys Res 95 (D8): 11811–11830
Prentice KC, Fung I-Y (1990) The sensitivity of terrestrial carbon storage to climate change. Nature 346:48–50
Schneider SH (1993) Can palaeoclimatic and palaeoecological analyses validate future climate and ecological change projections? In: Eddy JA, Oeschger H (eds) Global changes in the perspective of the past. Wiley, Chichester, pp 317–342
Smith TM, Leemans R, Shugart HH (1992) Sensitivity of terrestrial carbon storage to CO2-induced climate change: comparison of four scenarios based on general circulation models. Clim Change 21:367–384
VEMAP Participants (1995) Vegetation/ecosystem modeling and analysis project (VEMAP): comparing biogeography and biogeochemistry models in a continental-scale study of terrestrial ecosystem responses to climate change and CO2 doubling. Global Biogeochem Cycles (in press)
Webb T III (1992) Past changes in vegetation and climate: lessons for the future. In: Peters R, Lovejoy T (eds) Consequences of global warming for biological diversity. Yale University Press, New Haven, pp 59–75
Woodward FI (1987) Climate and plant distribution. Cambridge University Press, Cambridge, UK, 174 pp
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Prentice, C., Guiot, J., Huntley, B. et al. Reconstructing biomes from palaeoecological data: a general method and its application to European pollen data at 0 and 6 ka. Climate Dynamics 12, 185–194 (1996). https://doi.org/10.1007/BF00211617
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DOI: https://doi.org/10.1007/BF00211617