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1.
Brian Huntley 《Climate Dynamics》1992,6(3-4):185-191
Rates of change of pollen spectra throughout Europe during the last 13 000 years have been calculated. The overall mean rate of change curve shows peaks corresponding to known times of rapid palaeoenvironmental change between 13 000 and 12000y BP, and between 10 000 and 9000 y BP. These peaks are strongest in the north and west of Europe. As in eastern North America (Jacobson et al. 1987), highest rates of change are recorded during the last millennium. At this time the changes of greatest magnitude are in areas of Europe with winter climate conditions strongly influenced by the North Atlantic. It is hypothesized that the overall pattern of Holocene climate change in Europe, and especially the changes of the last millennium, result from changes in the North Atlantic that have most strongly influenced winter conditions in western Europe.Contribution to Clima Locarno — Past and Present Climate Dynamics; Conference September 1990, Swiss Academy of Sciences — National Climate Program 相似文献
2.
A quantitative measure of the rate at which fossil-pollen abundances changed over the last 18 000 years at 18 sites spread across eastern North America distinguishes local from regionally synchronous changes. Abrupt regional changes occurred at most sites in late-glacial time (at 13700, 12 300, and 10000 radiocarbon yr BP) and during the last 1000 years. The record of abrupt late-glacial vegetation changes in eastern North America correlates well with abrupt global changes in ice-sheet volume, mountain snow-lines, North Atlantic deep-water production, atmospheric CO2, and atmospheric dust, although the palynological signal varies from site to site. Changes in vegetation during most of the Holocene, although locally significant, were not regionally synchronous. The analysis reveals non-alpine evidence for Neoglacial/Little Ice Age climate change during the last 1000 years, which was the only time during the Holocene when climate change was of sufficient magnitude to cause a synchronous vegetational response throughout the subcontinent. During the two millennia preceding this widespread synchronous change, the rate of change at all sites was low and the average rate of change was the lowest of the Holocene.Contribution to Clima Locarno Past and Present Climate Dynamics; Conference September 1990, Swiss Academy of Sciences — National Climate Program 相似文献
3.
Fully coupled climate/dynamical vegetation model simulations over Northern Africa during the mid-Holocene 总被引:6,自引:1,他引:5
The climate and vegetation patterns of the middle Holocene (6000 years ago; 6 ka) over Northern Africa are simulated using
a fully-synchronous climate and dynamical vegetation model. The coupled model predicts a northward shift in tropical rainforest
and tropical deciduous forest vegetation by about 5 degrees of latitude, and an increase in grassland at the present-day simulated
Saharan boundaries. The northward expansion of vegetation over North Africa at 6 ka is initiated by an orbitally-induced amplification
of the summer monsoon, and enhanced by feedback effects induced by the vegetation. These combined processes lead to a major
reduction in Saharan desert area at 6 ka relative to present-day of about 50%. However, as shown in previous asynchronous
modelling studies, the coupled climate/vegetation model does not fully reproduce the vegetation patterns inferred from palaeoenvironmental
records, which suggest that steppe vegetation may have existed across most of Northern Africa. Orbital changes produce an
intensification of monsoonal precipitation during the peak rainy season (July to September), whilst vegetation feedbacks,
in addition to producing further increases in the peak intensity, play an important role in extending the rainy season from
May/June through to November. The orbitally induced increases in precipitation are relatively uniform from west to east, in
contrast to vegetation feedback-induced increases in precipitation which are concentrated in western North Africa. Annual-average
precipitation increases caused by vegetation feedbacks are simulated to be of similar importance to orbital effects in the
west, whilst they are relatively unimportant farther to the east. The orbital, vegetation and combined orbital and vegetation-induced
changes in climate, from the simulations presented in this study, have been compared with results from previous modelling
studies over the appropriate North African domain. Consequently, the important role of vegetation parametrizations in determining
the magnitude of vegetation feedbacks has been illustrated. Further modelling studies which include the effects of changes
in ocean temperature and changes in soil properties may be needed, along with additional observations, to resolve the discrepancy
between model predictions of vegetation and palaeorecords for North Africa.
Received: 15 June 1999 / Accepted: 14 December 1999 相似文献
4.
It has long been recognized that albedo related vegetation feedbacks amplify climate variability in North Africa. Recent studies
have revealed that areas of very high albedo associated with certain desert soil types contribute to the current dry climate
of the region. We construct three scenarios of North African albedo, one based on satellite measurements, one where the highest
albedo resembles that of soils in the desert transition zones, and one based on a vegetation map for the “green Sahara” state
of the middle Holocene, ca. 6,000 years ago. Using a series of climate model simulations, we find that the additional amplitude
of albedo change from the middle Holocene to the present caused by the very bright desert soils enhances the magnitude of
the June-to-August precipitation change in the region of the present Sahara from 0.6 to 1.0 mm/day on average. We also find
that albedo change has a larger effect on regional precipitation than changes in either the Earth’s orbit or sea surface temperatures
between 6,000 years ago and today. Simulated precipitation agrees rather well with present observations and mid Holocene reconstructions.
Our results suggest that there may exist an important climate feedback from soil formation processes that has so far not been
recognized. 相似文献
5.
Vincent Garreta Paul A. Miller Joël Guiot Christelle Hély Simon Brewer Martin T. Sykes Thomas Litt 《Climate Dynamics》2010,35(2-3):371-389
Climate reconstructions from data sensitive to past climates provide estimates of what these climates were like. Comparing these reconstructions with simulations from climate models allows to validate the models used for future climate prediction. It has been shown that for fossil pollen data, gaining estimates by inverting a vegetation model allows inclusion of past changes in carbon dioxide values. As a new generation of dynamic vegetation model is available we have developed an inversion method for one model, LPJ-GUESS. When this novel method is used with high-resolution sediment it allows us to bypass the classic assumptions of (1) climate and pollen independence between samples and (2) equilibrium between the vegetation, represented as pollen, and climate. Our dynamic inversion method is based on a statistical model to describe the links among climate, simulated vegetation and pollen samples. The inversion is realised thanks to a particle filter algorithm. We perform a validation on 30 modern European sites and then apply the method to the sediment core of Meerfelder Maar (Germany), which covers the Holocene at a temporal resolution of approximately one sample per 30 years. We demonstrate that reconstructed temperatures are constrained. The reconstructed precipitation is less well constrained, due to the dimension considered (one precipitation by season), and the low sensitivity of LPJ-GUESS to precipitation changes. 相似文献
6.
《Climate Dynamics》2008,30(7-8):887-907
Fire activity has varied globally and continuously since the last glacial maximum (LGM) in response to long-term changes in
global climate and shorter-term regional changes in climate, vegetation, and human land use. We have synthesized sedimentary
charcoal records of biomass burning since the LGM and present global maps showing changes in fire activity for time slices
during the past 21,000 years (as differences in charcoal accumulation values compared to pre-industrial). There is strong
broad-scale coherence in fire activity after the LGM, but spatial heterogeneity in the signals increases thereafter. In North
America, Europe and southern South America, charcoal records indicate less-than-present fire activity during the deglacial
period, from 21,000 to ∼11,000 cal yr BP. In contrast, the tropical latitudes of South America and Africa show greater-than-present
fire activity from ∼19,000 to ∼17,000 cal yr BP and most sites from Indochina and Australia show greater-than-present fire
activity from 16,000 to ∼13,000 cal yr BP. Many sites indicate greater-than-present or near-present activity during the Holocene
with the exception of eastern North America and eastern Asia from 8,000 to ∼3,000 cal yr BP, Indonesia and Australia from
11,000 to 4,000 cal yr BP, and southern South America from 6,000 to 3,000 cal yr BP where fire activity was less than present.
Regional coherence in the patterns of change in fire activity was evident throughout the post-glacial period. These complex
patterns can largely be explained in terms of large-scale climate controls modulated by local changes in vegetation and fuel
load.
The readers are requested to refer to the section “List of contributors” for the complete list of author affiliation details. 相似文献
7.
To interpret past vegetation and climate changes from pollen data, we need to reveal the degree of similarity between modern analogues and fossil pollen spectra, which would help us predict the future climate and vegetation. Ninety surface pollen samples across six vegetation zones along an altitudinal gradient from 460 to 3510 m and 44 fossil samples at Caotan Lake were collected in the central Tianshan Mountains, northern Xinjiang, China. Discriminant analyses results, fossil pollen and phytolith assemblages were then used to reconstruct palaeovegetation and palaeoclimate in the area. The 90 surface samples were divided into six pollen zones (alpine cushion, alpine and subalpine meadow, montane Tianshan spruce forest, forest-steppe ecotone, Artemisia desert, typical desert), corresponding to the major vegetation types in the area. These zones follow a climatic gradient of increasing precipitation with increasing elevation. Paleovegetation reconstructed from 44 fossil pollen assemblages through discriminant analysis reflects the regional vegetation shifted from typical desert to Artemisia desert since 4640 cal. year BP in the Caotan Lake wetland. The fossil pollen and phytolith record also reveal the arid climate has not fundamentally changed in the period. But a dry-wet-dry local climate oscillation since 2700 cal. year BP has a fundamental influence on local wetland vegetation dynamics and peat accumulation of the Caotan wetland. Modern wetland landscape and surface pollen assemblages from the Ebinur Lake Wetland Nature Reserve provide further evidence for ferns and Betula growing in the Caotan Lake wetland during the historical period. 相似文献
8.
Urban greening can enhance quality of life by generating ecosystem services and has been proposed as a way of mitigating adverse consequences of global warming for human health. However, there is limited knowledge on global trends in urban vegetation and their relation to economic development and climate change. Here we studied 1,688 major cities worldwide and show that 70% (1,181) show an increase in vegetation derived from satellite observations (2000–2018). For 68% (1,138) of the cities studied, the increase in the urban vegetation is less strong as compared to the vegetation increase found in the surroundings of these cities. Overall, positive vegetation trends are widely observed in cities in Europe and North America, whereas negative vegetation trends in cities occur primarily in Africa, South America and Asia. Gross Domestic Product growth, population growth as well as temperature are found to be the main underlying drivers of the observed contrasts in changes in urban vegetation as compared to surrounding areas across continents. From a global synthesis of urban vegetation change, we quantify the role of social-economic development and climate change in regulating urban vegetation growth, and the contrasting imprint on cities of developed and developing countries. 相似文献
9.
Holocene vegetation and climate history at Haligu on the Jade Dragon Snow Mountain, Yunnan, SW China 总被引:1,自引:0,他引:1
Xiao-Yan Song Yi-Feng Yao A. H. Wortley K. N. Paudayal Shao-Hua Yang Cheng-Sen Li S. Blackmore 《Climatic change》2012,113(3-4):841-866
This paper uses pollen analysis to investigate and document the changing climate and vegetation during the Holocene based on a 400?cm core in depth obtained at a wetland site at Haligu (3,277?m a. s. l.) on the Jade Dragon Snow Mountain in Yunnan, China. By applying the Coexistence Approach to pollen data from this core, a quantitative reconstruction of climate over the last 9,300?years was made based on each pollen zone and individual core sample, which reveals the temperature and precipitation change frequently during that time. The qualitative analyses show that from 9300 to 8700?cal. yr BP, the vegetation was dominated by needle-leaved forest (mainly Pinus and Abies), indicating a slightly cool and moderately humid climate. Between 8700 and 7000?cal. yr BP, evergreen broad-leaved forest, dominated by Quercus, became the predominant vegetation type, replacing needle-leaved forest at this elevation, implying a warmer and more humid climate. During the period 7000 to 4000?cal. yr BP, the vegetation changed to mixed needle-leaved and evergreen broad-leaved forest, indicating a warm and moderately humid climate, but somewhat cooler than the preceding stage. From 4000 to 2400?cal. yr BP, the vegetation was again dominated by evergreen broad-leaved forest, but coniferous trees (mainly Pinus) began to increase, especially relative to a decline in Quercus. This implies that the climate remained warm and humid but slight drier than previously. The evergreen Quercus phase (8700–2400?yr BP) was designated as the Holocene climatic optimum in the Haligu core sediments. It is correlated with a markedly greater abundance and diversity of pteridophytes spores than was recorded before or after this period. From 2400?cal. yr BP to present, the vegetation was dominated by needle-leaved forest, of which Pinus formed the predominant component, accompanied by Abies and Tsuga. This reflects a slightly cooler, humid climate but also correlates with a period of increasing human settlement on the lower slopes of the mountain. At this elevated site, several hundred metres above the highest present day settlements, direct palynological evidence of anthropogenic activity is uncertain but we discuss ways in which the marked decline in Quercus pollen during this period may reflect the impact of ways in which natural resources of the mountain have been utilised. 相似文献
10.
Stephen F. Wathen 《Climatic change》2011,108(1-2):333-356
This paper provides both a detailed history of environmental change in the Sierra Nevada over the past 1,800 years and evidence for climate teleconnections between the Sierra Nevada and Greenland during the late Holocene. A review of Greenland ice core data suggests that the magnitudes of abrupt changes in temperature and precipitation increased beginning c. 3,700 and 3,000 years ago, respectively. Precipitation increased abruptly 1,300 years ago. Comparing paleotemperature data from Cirque Peak, CA with paleoprecipitation data from Pyramid Lake, NV suggests that hot temperatures occurred at the beginnings of most severe droughts in the Sierra Nevada over the past 1,800 years. Severe fires and erosion also occurred at Coburn Lake, CA at the beginning of all severe droughts in the Sierra Nevada over the past 1,800 years. This suggests that abrupt climate change during the late Holocene caused vegetation and mountain slopes in some areas to be out of equilibrium with abruptly changed climates. Finally, the ending of drought conditions in Greenland coincided with the beginning of drought conditions in the Sierra Nevada over the past 1,800 years, perhaps as a result of the rapidly changed locations of the Earth??s major precipitation belts during abrupt climate change events. 相似文献
11.
Within the framework of the PMIP (Paleoclimate Modelling Intercomparison Project), we have compared mid-Holocene climate
simulations from 16 atmospheric general circulation models (AGCMs) with new pollen-based reconstructions of the European bioclimatic
variables for winter and growing season temperatures as well as annual water budget changes. In winter, some models are able
to simulate the reconstructed northeastern warming, due to an increased heat transport from the ocean, associated with a larger
north-south pressure gradient over the northern Atlantic. Whereas most models are only able to simulate a strong summer warming,
data indicate a shorter and/ or colder growing season in southern Europe and a longer and/or warmer growing season in northwestern
Europe. The reconstructed change in annual water budget indicates drier conditions in northwestern Europe and wetter conditions
in southern Europe. Some models simulate such moisture changes, due to more summer evaporation over Scandinavia during summer,
and more autumn-winter-spring precipitation over southern Europe. To address the PMIP approximation of no change in ocean
and land boundary conditions, we have performed short sensitivity experiments to surface boundary conditions (sea-surface-temperatures,
vegetation) using one single model. The model-data disagreements over Europe are probably due to the local influence of the
surrounding oceans which are not taken into account in the first PMIP simulations. We therefore stress the need for more mid-Holocene
SST reconstructions and further analysis of pollen data in the Mediterranean region.
Received: 23 February 1998 /Accepted: 19 September 1998 相似文献
12.
Future changes of terrestrial ecosystems due to changes in atmospheric CO2 concentration and climate are subject to a large degree of uncertainty, especially for vegetation in the Tropics. Here, we evaluate the natural vegetation response to projected future changes using an improved version of a dynamic vegetation model (CLM-CN-DV) driven with climate change projections from 19 global climate models participating in the Coupled Model Intercomparison Project Phase 5 (CMIP5). The simulated equilibrium vegetation distribution under historical climate (1981–2000) has been compared with that under the projected future climate (2081–2100) scenario for Representative Concentration Pathway 8.5 (RCP8.5) to qualitatively assess how natural potential vegetation might change in the future. With one outlier excluded, the ensemble average of vegetation changes corresponding to climates of 18 GCMs shows a poleward shift of forests in northern Eurasia and North America, which is consistent with findings from previous studies. It also shows a general “upgrade” of vegetation type in the Tropics and most of the temperate zones, in the form of deciduous trees and shrubs taking over C3 grass in Europe and broadleaf deciduous trees taking over C4 grasses in Central Africa and the Amazon. LAI and NPP are projected to increase in the high latitudes, southeastern Asia, southeastern North America, and Central Africa. This results from CO2 fertilization, enhanced water use efficiency, and in the extra-tropics warming. However, both LAI and NPP are projected to decrease in the Amazon due to drought. The competing impacts of climate change and CO2 fertilization lead to large uncertainties in the projection of future vegetation changes in the Tropics. 相似文献
13.
After the last glacial maximum (LGM; 18,000 years. bp) plants migrated onto areas made free by the retreating ice sheets. Pollen records document changes in ecosystems and are an important proxy for the reconstruction of climate parameters. Here, we quantify changes in January temperature (Tjan) over the past 14,000 years using 216 European pollen records. We used functional principal component analysis to evaluate the patterns of change over this period of time. Between 14 and 12 ka, Tjan records show comparable changes across Europe. After this time period, northwest and southeast Europe experienced differing trends in Tjan, trends that became pronounced by 9 ka. The spatial gradient of Tjan records is well-correlated with the overall change from steppe to increasingly diverse forest ecosystems. In particular, differential incorporation of conifer vs. deciduous species into forest ecosystems, based on differential colonization out of refugia, likely resulted in albedo gradients over Europe that affected regional Tjan. 相似文献
14.
Some mechanisms of mid-Holocene climate change in Europe,inferred from comparing PMIP models to data
We propose a new approach for comparing mid-Holocene climates from 18 PMIP simulations with climate reconstructions of winter and growing season temperatures and the annual water budget inferred from European pollen and lake-level data. A cluster analysis is used to extract patterns of multivariate climate response from the reconstructions; these are then compared to the patterns simulated by models. According to paleodata, summers during mid-Holocene were warmer-than-present in the north, and cooler-than-present in the south, while winters were colder-than-present in the southwest but milder-than-present in the northeast. Whereas warmer summers and colder winters may easily be explained as a direct response to the amplified seasonal cycle of insolation during the mid-Holocene, the other recorded responses are less straightforward to explain. We have identified, from the models that correctly simulate the recorded climate change, two important atmospheric and hydrological processes that can compensate for direct insolation effects. First, a stronger-than-present airflow from southwestern Europe that veers to the north over Eastern Europe, in winter, can consistently explain the reconstructed changes in this seasons temperatures and water budget. Second, the increased winter soil moisture allows a shift of the partitioning of net radiative energy towards latent rather than sensible heat fluxes, thereby decreasing surface temperature during the following summer season. Our approach therefore solves one of the recurring problems in model-data comparisons that arises when a model simulates the correct response but in the wrong location (as a consequence, for instance, of model resolution and topography). 相似文献
15.
IPCC第五次评估报告(AR5)第二工作组(WGII)报告认为,气候变化对世界上大部分区域的自然和人类系统的影响将进一步加剧,其对非洲最大的影响预计发生在半干旱的环境,增加现有的水资源可利用量和农业系统的压力;气候变化已导致北欧地区的谷物产量增加而南欧地区的产量降低,未来的变化将增加欧洲的灌溉需求;在亚洲的许多地区,气候变化将导致农业生产率下降;气候、大气CO2和海洋酸化的进一步变化预计将对大洋洲的水资源、海岸生态系统、基础设施、健康、农业和生物多样性产生实质性的影响;在北美,许多带来风险的气候压迫力的频率和强度将在未来几十年增加;中美洲和南美洲许多国家的持续高水平贫困导致了对气候变率和变化的高脆弱性;在北极,气候变化与非气候相关驱动在确定的物理、生物和社会经济风险上交互作用,变化率可能超过了社会系统适应的速率;在气候和非气候因素的影响下,小岛屿具有高度的脆弱性,同时,气候变暖将增加海洋生态系统的风险。 相似文献
16.
Biomes computed from simulated climatologies 总被引:4,自引:0,他引:4
The biome model of Prentice et al. (1992a) is used to predict global patterns of potential natural plant formations, or biomes, from climatologies simulated by ECHAM, a model used for climate simulations at the Max-Planck-Institut fur Meteorologie. This study is undertaken in order to show the advantage of this biome model in diagnosing the performance of a climate model and assessing effects of past and future climate changes predicted by a climate model. Good overall agreement is found between global patterns of biomes computed from observed and simulated data of present climate. But there are also major discrepancies indicated by a difference in biomes in Australia, in the Kalahari Desert, and in the Middle West of North America. These discrepancies can be traced back to failures in simulated rainfall as well as summer or winter temperatures. Global patterns of biomes computed from an ice age simulation reveal that North America, Europe, and Siberia should have been covered largely by tundra and taiga, whereas only small differences are seen for the tropical rain forests. A potential northeast shift of biomes is expected from a simulation with enhanced C02 concentration according to the IPCC Scenario A. Little change is seen in the tropical rain forest and the Sahara. Since the biome model used is not capable of predicting changes in vegetation patterns due to a rapid climate change, the latter simulation has to be taken as a prediction of changes in conditions favourable for the existence of certain biomes, not as a prediction of a future distribution of biomes.[/ab] 相似文献
17.
Potential future changes in the characteristics of daily precipitation in Europe simulated by the HIRHAM regional climate model 总被引:1,自引:1,他引:0
Wilhelm May 《Climate Dynamics》2008,30(6):581-603
In this study the potential future changes in various aspects of daily precipitation events over Europe as a consequence of
the anticipated future increase in the atmospheric greenhouse gas concentrations are investigated. This is done by comparing
two 3-member ensembles of simulations with the HIRHAM regional climate model for the period 1961–1990 and 2071–2100, respectively.
Daily precipitation events are characterized by their frequency and intensity, and heavy precipitation events are described
via 30-year return levels of daily precipitation. Further, extended periods with and without rainfall (wet and dry spells)
are studied, considering their frequency and length as well as the average and extreme amounts of precipitation accumulated
during wet spells, the latter again described via 30-year return levels. The simulations show marked changes in the characteristics
of daily precipitation in Europe due to the anticipated greenhouse warming. In winter, for instance, the frequency of wet
days is enhanced over most of the European continent except for the region on the Norwegian west coast and the Mediterranean
region. The changes in the intensity and the 30-year return level of daily precipitation are characterized by a similar pattern
except for central Europe with a tendency of decreased 30-year return levels and increased precipitation intensity. In summer,
on the other hand, the frequency of wet days is decreased over most of Europe except for northern Scandinavia and the Baltic
Sea region. In contrast, the precipitation intensity and the 30-year return level of daily precipitation are increased over
entire Scandinavia, central and eastern Europe. The changes in the 30-year return level of daily precipitation are generally
stronger than the corresponding changes in the precipitation intensity but can have opposite signs in some regions. Also the
distribution of wet days is changed in the future. During summer, for instance, both the frequency and the length of dry spells
are substantially increased over most of the European continent except for the Iberian Peninsula. The frequency and the length
of wet spells, on the other hand, are generally reduced during summer and increased during winter, again, with the exception
of the Iberian Peninsula. The future changes in the frequency of wet days in winter are related to a change in the large-scale
flow over the North Atlantic and a corresponding shift of the North Atlantic storm track. The reduction in the frequency of
wet days in summer is related to a northward extension of the dry subtropical region in the future, with a reduction of the
convective activity because of the large-scale sinking motion in the downward branch of the Hadley cell. Because the atmosphere
contains more moisture in the warmer future climate, the amount of precipitation associated with individual low-pressure systems
or with individual convective events is increased, leading to a general increase in the intensity of individual precipitation
events. Only in regions, where all the moisture evaporates from the ground already in spring, the intensity of precipitation
events is reduced in summer. 相似文献
18.
William R. L. Anderegg 《Climatic change》2012,111(3-4):983-991
Drought-induced vegetation mortality has been documented on every vegetated continent in recent decades and constitutes a major uncertainty in climate change impacts on terrestrial ecosystems and carbon cycle feedbacks. While recent research has focused on specific failure mechanisms during drought-induced forest die-off, a broader understanding of the physiology of trees under drought, especially changes in growth and carbon allocation, is needed for determining the sensitivity of forests to drought and interacting mechanisms during forest mortality. I present here multi-tissue and high-resolution temporal dynamics of tree carbon resources during moderate experimental and natural drought in trembling aspen (Populus tremuloides) forests, a major forest type in western North America that recently experienced widespread drought-induced die-off. Drought led to substantial declines in inferred carbon uptake. Tree carbohydrate concentrations, however, largely increased in concert with substantial decreases in growth and severe declines in root biomass. These findings highlight that growth declines, especially in fine roots which are important to water uptake, and increased carbon allocation to root non-structural carbohydrates are key responses to drought in aspen and could play an important role in widespread die-off. They suggest multi-year consequences of drought and carbon-hydraulic interconnections. They underscore the need for a more integrated multi-tissue, multi-process, and multi-year perspective of climate-induced forest mortality. 相似文献
19.
Modeling the Influence of Topographic Barriers on Treeline Advance at the Forest-Tundra Ecotone in Northwestern Alaska 总被引:1,自引:0,他引:1
The response of terrestrial ecosystems to climate warming has important implications to potential feedbacks to climate. The interactions between topography, climate, and disturbance could alter recruitment patterns to reduce or offset current predicted positive feedbacks to warming at high latitudes. In northern Alaska the Brooks Range poses a complex environmental and ecological barrier to species migration. We use a spatially explicit model (ALFRESCO) to simulate the transient response of subarctic vegetation to climatic warming in the Kobuk/Noatak River Valley (200 × 400 km) in northwest Alaska. The model simulations showed that a significantly warmer (+6 °C) summer climate would cause expansion of forest through the Brooks Range onto the currently treeless North Slope only after a period of 3000–4000 yr. Substantial forest establishment on the North Slope didnot occur until temperatures warmed 9 °C, and only following a 2000 yr time lag. The long time lags between change in climate and change in vegetation indicate current global change predictions greatly over-estimate the response of vegetation to a warming climate in Alaska. In all the simulations warming caused a steady increase in the proportion of early successional deciduous forest. This would reduce the magnitude of the predicted decrease in regional albedo and the positive feedback to climate warming. Simulation of spruce forest refugia on the North Slope showed forest could survive with only a 4 °C warming and would greatly reduce the time lag of forest expansion under warmer climates. Planting of spruce on the North Slope by humans could increase the likelihood of large-scale colonization of currently treeless tundra. Together, the long time lag and deciduous forest dominance would delay the predicted positive regional feedback of vegetation change to climatic warming. These simulated changes indicate the Brooks Range would significantly constrain regional forest expansion under a warming climate, with similar implications for other regions possessing major east-west oriented mountain ranges. 相似文献
20.
N. E. Graham C. M. Ammann D. Fleitmann K. M. Cobb J. Luterbacher 《Climate Dynamics》2011,37(5-6):1217-1245
Widely distributed proxy records indicate that the Medieval Climate Anomaly (MCA; ~900–1350 AD) was characterized by coherent shifts in large-scale Northern Hemisphere atmospheric circulation patterns. Although cooler sea surface temperatures in the central and eastern equatorial Pacific can explain some aspects of medieval circulation changes, they are not sufficient to account for other notable features, including widespread aridity through the Eurasian sub-tropics, stronger winter westerlies across the North Atlantic and Western Europe, and shifts in monsoon rainfall patterns across Africa and South Asia. We present results from a full-physics coupled climate model showing that a slight warming of the tropical Indian and western Pacific Oceans relative to the other tropical ocean basins can induce a broad range of the medieval circulation and climate changes indicated by proxy data, including many of those not explained by a cooler tropical Pacific alone. Important aspects of the results resemble those from previous simulations examining the climatic response to the rapid Indian Ocean warming during the late twentieth century, and to results from climate warming simulations—especially in indicating an expansion of the Northern Hemisphere Hadley circulation. Notably, the pattern of tropical Indo-Pacific sea surface temperature (SST) change responsible for producing the proxy-model similarity in our results agrees well with MCA-LIA SST differences obtained in a recent proxy-based climate field reconstruction. Though much remains unclear, our results indicate that the MCA was characterized by an enhanced zonal Indo-Pacific SST gradient with resulting changes in Northern Hemisphere tropical and extra-tropical circulation patterns and hydroclimate regimes, linkages that may explain the coherent regional climate shifts indicated by proxy records from across the planet. The findings provide new perspectives on the nature and possible causes of the MCA—a remarkable, yet incompletely understood episode of Late Holocene climatic change. 相似文献