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1.
Quantifying contributions to polar warming amplification in an idealized coupled general circulation model 总被引:2,自引:1,他引:1
An idealized coupled general circulation model is used to demonstrate that the surface warming due to the doubling of CO2 can still be stronger in high latitudes than in low latitudes even without the negative evaporation feedback in low latitudes
and positive ice-albedo feedback in high latitudes, as well as without the poleward latent heat transport. The new climate
feedback analysis method formulated in Lu and Cai (Clim Dyn 32:873–885, 2009) is used to isolate contributions from both radiative and non-radiative feedback processes to the total temperature change
obtained with the coupled GCM. These partial temperature changes are additive and their sum is convergent to the total temperature
change. The radiative energy flux perturbations due to the doubling of CO2 and water vapor feedback lead to a stronger warming in low latitudes than in high latitudes at the surface and throughout
the entire troposphere. In the vertical, the temperature changes due to the doubling of CO2 and water vapor feedback are maximum near the surface and decrease with height at all latitudes. The simultaneous warming
reduction in low latitudes and amplification in high latitudes by the enhanced poleward dry static energy transport reverses
the poleward decreasing warming pattern at the surface and in the lower troposphere, but it is not able to do so in the upper
troposphere. The enhanced vertical moist convection in the tropics acts to amplify the warming in the upper troposphere at
an expense of reducing the warming in the lower troposphere and surface warming in the tropics. As a result, the final warming
pattern shows the co-existence of a reduction of the meridional temperature gradient at the surface and in the lower troposphere
with an increase of the meridional temperature gradient in the upper troposphere. In the tropics, the total warming in the
upper troposphere is stronger than the surface warming. 相似文献
2.
A new framework for isolating individual feedback processes in coupled general circulation climate models. Part I: formulation 总被引:1,自引:1,他引:0
This paper proposes a coupled atmosphere–surface climate feedback–response analysis method (CFRAM) as a new framework for
estimating climate feedbacks in coupled general circulation models with a full set of physical parameterization packages.
The formulation of the CFRAM is based on the energy balance in an atmosphere–surface column. In the CFRAM, the isolation of
partial temperature changes due to an external forcing or an individual feedback is achieved by solving the linearized infrared
radiation transfer model subject to individual energy flux perturbations (external or due to feedbacks). The partial temperature
changes are addable and their sum is equal to the (total) temperature change (in the linear sense). The decomposition of feedbacks
is based on the thermodynamic and dynamical processes that directly affect individual energy flux terms. Therefore, not only
those feedbacks that directly affect the TOA radiative fluxes, such as water vapor, clouds, and ice-albedo feedbacks, but
also those feedbacks that do not directly affect the TOA radiation, such as evaporation, convections, and convergence of horizontal
sensible and latent heat fluxes, are explicitly included in the CFRAM. In the CFRAM, the feedback gain matrices measure the
strength of individual feedbacks. The feedback gain matrices can be estimated from the energy flux perturbations inferred
from individual parameterization packages and dynamical modules. The inter-model spread of a feedback gain matrix would help
us to detect the origins of the uncertainty of future climate projections in climate model simulations. 相似文献
3.
紧于水分循环和海冰物理过程是气候变化研究中两个比较薄弱的环节,而在以往的一些气候模式中往往简化甚至忽略了其中之一,给气候变化的研究带来了一定的不确定性。因此,我们设计了包含详细水分循环和海冰物理过程的一维气候模式,着重研究了存在,气候系统内部的反馈机制,得到以下几点结论:(1)无论在地表还是在大气中,水汽反馈和冰雪反照率反馈均为很强的正反馈,前者比后者要强一些,冰雪反照率反馈在极区比其它地区强一些。(2)降水过程无论在地表还是在大气中均表现为负反馈。(3)在大气中,蒸发过程表现为很强的正反馈;在地表,蒸发过程在中低纬度表现为很强的负反馈,而在高纬度却表现为正反馈。(4)大气中的潜热输送无论在大气中还是在地表均表现为正反馈,共正反馈效应通过放大水汽的温室效应体现出来。(5)大气中的感热输送无论在大气中还是在地表均表现为较弱的负反馈,其负反馈作用通过抑制冰雪反照率反馈而表现出来。(6)不同反馈之间的合成不是两者简单地线性相加,而是以一种北线性方式相互作用。 相似文献
4.
In this study, a coupled atmosphere-surface “climate feedback-response analysis method” (CFRAM) was applied to the slab ocean model version of the NCAR CCSM3.0 to understand the tropospheric warming due to a doubling of CO2 concentration through quantifying the contributions of each climate feedback process. It is shown that the tropospheric warming displays distinct meridional and vertical patterns that are in a good agreement with the multi-model mean projection from the IPCC AR4. In the tropics, the warming in the upper troposphere is stronger than in the lower troposphere, leading to a decrease in temperature lapse rate, whereas in high latitudes the opposite it true. In terms of meridional contrast, the lower tropospheric warming in the tropics is weaker than that in high latitudes, resulting in a weakened meridional temperature gradient. In the upper troposphere the meridional temperature gradient is enhanced due to much stronger warming in the tropics than in high latitudes. Using the CFRAM method, we analyzed both radiative feedbacks, which have been emphasized in previous climate feedback analysis, and non-radiative feedbacks. It is shown that non-radiative (radiative) feedbacks are the major contributors to the temperature lapse rate decrease (increase) in the tropical (polar) region. Atmospheric convection is the leading contributor to temperature lapse rate decrease in the tropics. The cloud feedback also has non-negligible contributions. In the polar region, water vapor feedback is the main contributor to the temperature lapse rate increase, followed by albedo feedback and CO2 forcing. The decrease of meridional temperature gradient in the lower troposphere is mainly due to strong cooling from convection and cloud feedback in the tropics and the strong warming from albedo feedback in the polar region. The strengthening of meridional temperature gradient in the upper troposphere can be attributed to the warming associated with convection and cloud feedback in the tropics. Since convection is the leading contributor to the warming differences between tropical lower and upper troposphere, and between the tropical and polar regions, this study indicates that tropical convection plays a critical role in determining the climate sensitivity. In addition, the CFRAM analysis shows that convective process and water vapor feedback are the two major contributors to the tropical upper troposphere temperature change, indicating that the excessive upper tropospheric warming in the IPCC AR4 models may be due to overestimated warming from convective process or underestimated cooling due to water vapor feedback. 相似文献
5.
由于全球变暖,极地地区的气候经历了明显的变暖放大.在本项研究中,我们根据CMIP6模式的三种变暖情景(SSP1-2,6,SSP2-4.5和SSP5-8.5)下,极地放大变化对各个反馈机制(包括普朗克,温度递减率,云,水蒸气,反照率反馈,CO2强迫,海洋热吸收和大气热传输)的响应进行了分析.结果表明,通过用“辐射核”方法量化不同反馈机制对地表温度的增温贡献,北极放大(AA)强于南极放大(ANA),由温度递减率反馈主导,其次是反照率和普朗克反馈.此外,海洋的热吸收导致冬季比夏季有更强的极地变暖.在冬季,温度递减率反馈主导了AA大于ANA.AA和ANA的模式间差异随着全球变暖的增强而减小. 相似文献
6.
L. D. D. Harvey 《Climate Dynamics》2000,16(7):491-500
This work uses an energy balance climate model (EBCM) with explicit infrared radiative transfer, parametrized tropospheric
temperature and humidity profiles, and separate stratosphere, troposphere, and surface energy balances, to investigate claims
that a downward redistribution of tropospheric water vapor in response to surface warming could serve as a strong negative
feedback on climatic change. A series of sensitivity tests is carried out using: (1) a variety of relationships between total
precipitable water in the troposphere and temperature; (2) feedbacks between surface temperature and the vertical distribution
of tropospheric water vapor at low latitudes; and (3) feedback between surface temperature or meridional temperature gradient
and lapse rate. Fixed relative humidity (RH) enhances the global mean surface temperature response to a CO2 doubling by only 50% compared to fixed absolute humidity, giving a response of 1.8 K. When water vapor is assumed to be redistributed
downward between 30°S–30°N such that a 1 K surface warming reduces total precipitable water above 600 hPa by 10%, the global
mean surface air temperature response is reduced to 1.2 K. Assuming a stronger downward redistribution in relation to surface
temperature change has a rapidly diminishing marginal effect on global mean and tropical surface temperature response, while
slightly increasing the warming at high latitudes due to the parametrized dependence of middle-to-high latitude lapse rate
on the meridional temperature gradient. A modest downward water vapor redistribution, such that absolute humidity in the upper
troposphere at subtropical latitudes is constant as total precipitable water increases, can reduce the tropical temperature
sensitivity to less than 1 K, while increasing the equator-to-pole amplification of the surface air temperature response from
a factor of about three to a factor of four. However, it is concluded that whatever changes in future GCM response might occur
as a result of new parametrizations of subgrid-scale processes, they are exceedingly unlikely to produce a climate sensitivity
to a CO2 doubling of less than 1 K even if there is a strong downward shift in the water vapor distribution as climate warms.
Received: 23 February 1998 / Accepted: 1 November 1999 相似文献
7.
Masakazu Yoshimori Masahiro Watanabe Ayako Abe-Ouchi Hideo Shiogama Tomoo Ogura 《Climate Dynamics》2014,42(5-6):1613-1630
The finding that surface warming over the Arctic exceeds that over the rest of the world under global warming is a robust feature among general circulation models (GCMs). While various mechanisms have been proposed, quantifying their relative contributions is an important task in order to understand model behavior. Here we apply a recently proposed feedback analysis technique to an atmosphere–ocean GCM under two and four times CO2 concentrations which approximately lead to seasonally and annually sea ice-free climates. The contribution of feedbacks to Arctic temperature change is investigated. The surface warming in the Arctic is contributed by albedo, water vapour and large-scale condensation feedbacks and reduced by the evaporative cooling feedback. The surface warming contrast between the Arctic and the global averages (AA) is maintained by albedo and evaporative cooling feedbacks. The latter contributes to AA predominantly by cooling the low latitudes more than the Arctic. Latent heat transport into the Arctic increases and hence evaporative cooling plus large-scale condensation feedback contributes positively to AA. On the other hand, dry-static energy transport into the Arctic decreases and hence dynamical heating feedback contributes negatively to AA. An important contribution is thus made via changes in hydrological cycle and not via the ‘dry’ heat transport process. A larger response near the surface than aloft in the Arctic is maintained by the albedo, water vapour, and dynamical heating feedbacks, in which the albedo and water vapour feedbacks contribute through warming the surface more than aloft, and the dynamical heating feedback contributes by cooling aloft more than the surface. In our experiments, ocean and sea ice dynamics play a secondary role. It is shown that a different level of CO2 increase introduces a latitudinal and seasonal difference into the feedbacks. 相似文献
8.
This study examines in detail the ‘atmospheric’ radiative feedbacks operating in a coupled General Circulation Model (GCM). These feedbacks (defined as the change in top of atmosphere radiation per degree of global surface temperature change) are due to responses in water vapour, lapse rate, clouds and surface albedo. Two types of radiative feedback in particular are considered: those arising from century scale ‘transient’ warming (from a 1% per annum compounded CO2 increase), and those operating under the model’s own unforced ‘natural’ variability. The time evolution of the transient (or ‘secular’) feedbacks is first examined. It is found that both the global strength and the latitudinal distributions of these feedbacks are established within the first two or three decades of warming, and thereafter change relatively little out to 100 years. They also closely approximate those found under equilibrium warming from a ‘mixed layer’ ocean version of the same model forced by a doubling of CO2. These secular feedbacks are then compared with those operating under unforced (interannual) variability. For water vapour, the interannual feedback is only around two-thirds the strength of the secular feedback. The pattern reveals widespread regions of negative feedback in the interannual case, in turn resulting from patterns of circulation change and regions of decreasing as well as increasing surface temperature. Considering the vertical structure of the two, it is found that although positive net mid to upper tropospheric contributions dominate both, they are weaker (and occur lower) under interannual variability than under secular change and are more narrowly confined to the tropics. Lapse rate feedback from variability shows weak negative feedback over low latitudes combined with strong positive feedback in mid-to-high latitudes resulting in no net global feedback—in contrast to the dominant negative low to mid-latitude response seen under secular climate change. Surface albedo feedback is, however, slightly stronger under interannual variability—partly due to regions of extremely weak, or even negative, feedback over Antarctic sea ice in the transient experiment. Both long and shortwave global cloud feedbacks are essentially zero on interannual timescales, with the shortwave term also being very weak under climate change, although cloud fraction and optical property components show correlation with global temperature both under interannual variability and transient climate change. The results of this modelling study, although for a single model only, suggest that the analogues provided by interannual variability may provide some useful pointers to some aspects of climate change feedback strength, particularly for water vapour and surface albedo, but that structural differences will need to be heeded in such an analysis. 相似文献
9.
We here use a coupled atmosphere-surface single column climate model to illustrate how the CFRAM, a new climate feedback analysis
framework formulated in Part I of the two-part series papers, can be applied to isolate individual contributions to the total
temperature change of a climate system from the external forcing alone, and from each of individual physical and dynamical
processes associated with the energy transfer with the space and within the climate system. We demonstrate that the isolation
of individual feedbacks in the CFRAM is achieved without referencing to a virtual climate system as in the online feedback
suppression method. We show that partial temperature changes estimated by the online feedback suppression method include the
“compensating effects” of other feedbacks when the feedback under consideration is suppressed. The partial temperature changes
are addable in the CFRAM but they are not in the online feedback suppression method. We also apply the CFRAM to isolate the
contributions to the lapse rate feedback from individual physical and dynamical feedback processes. We show that the lapse
rate feedback includes not only the partial effect of each feedback that directly contributes to energy flux perturbations
at the TOA (such as water vapor feedback), but also the total effects of those feedbacks that do not contribute to energy
flux perturbations at the TOA (such as evaporation and moist convection feedbacks). Because the contributions to the lapse
rate feedback from various physical and dynamical processes tend to cancel one another, the net lapse rate feedback is a residual
of many large terms. This leads to a large uncertainty not only in estimating the lapse rate feedback itself, but also in
other feedbacks whose effects are either partially or totally lumped into the lapse rate feedback. 相似文献
10.
One of the robust features in the future projections made by the state-of-the-art climate models is that the highest warming rate occurs in the upper-troposphere especially in the tropics. It has been suggested that more warming in the upper-troposphere than the lower-troposphere should exert a dampening effect on the sea surface warming associated with the negative lapse rate feedback. This study, however, demonstrates that the tropical upper-tropospheric warming (UTW) tends to trap more moisture in the lower troposphere and weaken the surface wind speed, both contributing to reduce the upward surface latent heat flux so as to trigger the initial sea surface warming. We refer to this as a ‘top-down’ warming mechanism. The rise of tropospheric moisture together with the positive water vapor feedback enhance the downward longwave radiation to the surface and facilitate strengthening the initial sea surface warming. Meanwhile, the rise of sea surface temperature (SST) can feed back to intensify the initial UTW through the moist adiabatic adjustment, completing a positive UTW–SST warming feedback. The proposed ‘top-down’ warming mechanism and the associated positive UTW–SST warming feedback together affect the surface global warming rate and also have important implications for understanding the past and future changes of precipitation, clouds and atmospheric circulations. 相似文献
11.
This study diagnoses the climate sensitivity, radiative forcing and climate feedback estimates from eleven general circulation models participating in the Fifth Phase of the Coupled Model Intercomparison Project (CMIP5), and analyzes inter-model differences. This is done by taking into account the fact that the climate response to increased carbon dioxide (CO2) is not necessarily only mediated by surface temperature changes, but can also result from fast land warming and tropospheric adjustments to the CO2 radiative forcing. By considering tropospheric adjustments to CO2 as part of the forcing rather than as feedbacks, and by using the radiative kernels approach, we decompose climate sensitivity estimates in terms of feedbacks and adjustments associated with water vapor, temperature lapse rate, surface albedo and clouds. Cloud adjustment to CO2 is, with one exception, generally positive, and is associated with a reduced strength of the cloud feedback; the multi-model mean cloud feedback is about 33 % weaker. Non-cloud adjustments associated with temperature, water vapor and albedo seem, however, to be better understood as responses to land surface warming. Separating out the tropospheric adjustments does not significantly affect the spread in climate sensitivity estimates, which primarily results from differing climate feedbacks. About 70 % of the spread stems from the cloud feedback, which remains the major source of inter-model spread in climate sensitivity, with a large contribution from the tropics. Differences in tropical cloud feedbacks between low-sensitivity and high-sensitivity models occur over a large range of dynamical regimes, but primarily arise from the regimes associated with a predominance of shallow cumulus and stratocumulus clouds. The combined water vapor plus lapse rate feedback also contributes to the spread of climate sensitivity estimates, with inter-model differences arising primarily from the relative humidity responses throughout the troposphere. Finally, this study points to a substantial role of nonlinearities in the calculation of adjustments and feedbacks for the interpretation of inter-model spread in climate sensitivity estimates. We show that in climate model simulations with large forcing (e.g., 4 × CO2), nonlinearities cannot be assumed minor nor neglected. Having said that, most results presented here are consistent with a number of previous feedback studies, despite the very different nature of the methodologies and all the uncertainties associated with them. 相似文献
12.
R. A. Colman 《Climate Dynamics》2001,17(5-6):391-405
This study addresses the question: what vertical regions contribute the most to water vapor, surface temperature, lapse rate and cloud fraction feedback strengths in a general circulation model? Multi-level offline radiation perturbation calculations are used to diagnose the feedback contribution from each model level. As a first step, to locate regions of maximum radiative sensitivity to climate changes, the top of atmosphere radiative impact for each feedback is explored for each process by means of idealized parameter perturbations on top of a control (1?×?CO2) model climate. As a second step, the actual feedbacks themselves are calculated using the changes modelled from a 2?×?CO2 experiment. The impact of clouds on water vapor and lapse rate feedbacks is also isolated using `clear sky' calculations. Considering the idealized changes, it is found that the radiative sensitivity to water vapor changes is a maximum in the tropical lower troposphere. The sensitivity to temperature changes has both upper and lower tropospheric maxima. The sensitivity to idealized cloud changes is positive (warming) for upper level cloud increases but negative (cooling) for lower level increases, due to competing long and shortwave effects. Considering the actual feedbacks, it is found that water vapor feedback is a maximum in the tropical upper troposphere, due to the large relative increases in specific humidity which occur there. The actual lapse rate feedback changes sign with latitude and is a maximum (negative) again in the tropical upper troposphere. Cloud feedbacks reflect the general decrease in low- to mid-level low-latitude cloud, with an increase in the very highest cloud. This produces a net positive (negative) shortwave (longwave) cloud feedback. The role of clouds in the strength of the water vapor and lapse rate feedbacks is also discussed. 相似文献
13.
Thorsten Mauritsen Rune G. Graversen Daniel Klocke Peter L. Langen Bjorn Stevens Lorenzo Tomassini 《Climate Dynamics》2013,41(9-10):2539-2554
Earth’s climate sensitivity to radiative forcing induced by a doubling of the atmospheric CO2 is determined by feedback mechanisms, including changes in atmospheric water vapor, clouds and surface albedo, that act to either amplify or dampen the response. The climate system is frequently interpreted in terms of a simple energy balance model, in which it is assumed that individual feedback mechanisms are additive and act independently. Here we test these assumptions by systematically controlling, or locking, the radiative feedbacks in a state-of-the-art climate model. The method is shown to yield a near-perfect decomposition of change into partial temperature contributions pertaining to forcing and each of the feedbacks. In the studied model water vapor feedback stands for about half the temperature change, CO2-forcing about one third, while cloud and surface albedo feedback contributions are relatively small. We find a close correspondence between forcing, feedback and partial surface temperature response for the water vapor and surface albedo feedbacks, while the cloud feedback is inefficient in inducing surface temperature change. Analysis suggests that cloud-induced warming in the upper tropical troposphere, consistent with rising convective cloud anvils in a warming climate enhances the negative lapse-rate feedback, thereby offsetting some of the warming that would otherwise be attributable to this positive cloud feedback. By subsequently combining feedback mechanisms we find a positive synergy acting between the water vapor feedback and the cloud feedback; that is, the combined cloud and water vapor feedback is greater than the sum of its parts. Negative synergies surround the surface albedo feedback, as associated cloud and water vapor changes dampen the anticipated climate change induced by retreating snow and ice. Our results highlight the importance of treating the coupling between clouds, water vapor and temperature in a deepening troposphere. 相似文献
14.
Simulations with the IPSL atmosphere–ocean model asynchronously coupled with the BIOME1 vegetation model show the impact of ocean and vegetation feedbacks, and their synergy, on mid- and high-latitude (>40°N) climate in response to orbitally-induced changes in mid-Holocene insolation. The atmospheric response to orbital forcing produces a +1.2 °C warming over the continents in summer and a cooling during the rest of the year. Ocean feedback reinforces the cooling in spring but counteracts the autumn and winter cooling. Vegetation feedback produces warming in all seasons, with largest changes (+1 °C) in spring. Synergy between ocean and vegetation feedbacks leads to further warming, which can be as large as the independent impact of these feedbacks. The combination of these effects causes the high northern latitudes to be warmer throughout the year in the ocean–atmosphere-vegetation simulation. Simulated vegetation changes resulting from this year-round warming are consistent with observed mid-Holocene vegetation patterns. Feedbacks also impact on precipitation. The atmospheric response to orbital-forcing reduces precipitation throughout the year; the most marked changes occur in the mid-latitudes in summer. Ocean feedback reduces aridity during autumn, winter and spring, but does not affect summer precipitation. Vegetation feedback increases spring precipitation but amplifies summer drying. Synergy between the feedbacks increases precipitation in autumn, winter and spring, and reduces precipitation in summer. The combined changes amplify the seasonal contrast in precipitation in the ocean–atmosphere-vegetation simulation. Enhanced summer drought produces an unrealistically large expansion of temperate grasslands, particularly in mid-latitude Eurasia. 相似文献
15.
An ocean general circulation model coupled to an energy-moisture balance atmosphere model is used to investigate the sensitivity
of global warming experiments to the parametrisation of sub-grid scale ocean mixing. The climate sensitivity of the coupled
model using three different parametrisations of sub-grid scale mixing is 3°C for a doubling of CO2 (6°C for a quadrupling of CO2). This suggests that the ocean has only a weak feedback on global mean surface air temperature although significant regional
differences, notably at high latitudes, exist with different sub-grid scale parametrisations. In the experiment using the
Gent and McWilliams parametrisation for mixing associated with mesoscale eddies, an enhancement of the surface response in
the Southern Ocean is found. This enhancement is largely due to the existence of more realistic sea-ice in the climatological
control integration and the subsequent enhanced ice-albedo feedback upon warming. In accordance with earlier analyses, the
Gent and McWilliams scheme decreases the global efficiency of ocean heat uptake. During the transient phase of all experiments,
the North Atlantic overturning initially weakened but ultimately recovered, surpassing its former strength. This suggests
that in the region around the North Atlantic the ocean acts as a negative feedback on local warming during the transient phase
but a positive feedback at equilibrium. During the transient phase of the experiments with a more sophisticated and realistic
parametrisation of sub-grid scale mixing, warmed Atlantic water was found to penetrate at depth into the Arctic, consistent
with recent observations in the region.
Received: 14 October 1998 / Accepted: 27 April 1999 相似文献
16.
We report the analysis of two 20-year simulations performed with the low resolution version of the IPSL coupled ocean-atmosphere
model, with no flux correction at the air-sea interface. The simulated climate is characterized by a global sea surface temperature
warming of about 4 °C in 20 years, driven by a net heat gain at the top of the atmosphere. Despite this drift, the circulation
is quite realistic both in the ocean and the atmosphere. Several distinct periods are analyzed. The first corresponds to an
adjustment during which the heat gain weakens both at the top of the atmosphere and at the ocean surface, and the tropical
circulation is slightly modified. Then, the surface warming is enhanced by an increase of the greenhouse feedback. We show
that the mechanisms involved in the model share common features with sensitivity experiments to greenhouse gases or to SST
warming. At the top of the atmosphere, most of the longwave trapping in the atmosphere is driven by the tropical circulation.
At the surface, the reduction of longwave cooling is a direct response to increased temperature and moisture content at low
levels in the atmospheric model. During the last part of the simulation, a regulation occurs from evaporation at the surface
and longwave cooling at TOA. Most of the model drift is attributed to a too large heating by solar radiation in middle and
high latitudes. The reduction of the north–south temperature gradient, and the related changes in the meridional equator-to-pole
ocean heat transport lead to a warming of equatorial and subtropical regions. This is also well demonstrated by the difference
between the two simulations which differ only in the parametrization of sea-ice. When the sea-ice cover is not restored to
climatology the model does not maintain sea-ice at high latitudes. The climate warms more rapidly and the water vapor and
clouds feedback occurs earlier.
Received: 24 May 1996 / Accepted: 29 November 1996 相似文献
17.
Studying the vegetation feedback during warm periods of the past can lead to better understanding of those in the future.In this study,we conducted several simulations to analyze vegetation feedback during the mid-Pliocene warm period.The results indicate that the main features of vegetation change in the mid-Pliocene were a northward shift of needleleaf tree,an expansion of broadleaf tree and shrub,and a northward expansion of grass,as compared to the pre-industrial period.The global annual mean warming ratio caused by vegetation feedback was 12.1%,and this warming ratio was much larger in northern middle and high latitudes.The warming caused by vegetation change was directly related to the surface albedo change and was further amplified by snow/sea ice-albedo feedback. 相似文献
18.
Whether the stratospheric radiative feedback amplifies the global warming remains under debate. The stratospheric water vapor (SWV), one of the primary feedbacks in the stratosphere, is argued to be an important contributor to the global warming. On the other hand, the overall stratospheric feedback, which consists of both the SWV feedback and the stratospheric temperature (ST) feedback, does not amount to a significant value. The key to reconciling these seemingly contradictory arguments is to understand the ST change. Here, we develop a method to decompose the ST change and to quantify the decomposed feedbacks. We find that the SWV feedback, which consists of a 0.04 W m−2 K−1 direct impact on the top-of-the-atmosphere radiation and 0.11 W m−2 K−1 indirect impact via ST cooling, is offset by a negative ST feedback of − 0.13 W m−2 K−1 that is radiatively driven by the tropospheric warming. This compensation results in an insignificant overall stratospheric feedback.
相似文献19.
Mechanisms for the land/sea warming contrast exhibited by simulations of climate change 总被引:3,自引:3,他引:0
Manoj M. Joshi Jonathan M. Gregory Mark J. Webb David M. H. Sexton Tim C. Johns 《Climate Dynamics》2008,30(5):455-465
The land/sea warming contrast is a phenomenon of both equilibrium and transient simulations of climate change: large areas
of the land surface at most latitudes undergo temperature changes whose amplitude is more than those of the surrounding oceans.
Using idealised GCM experiments with perturbed SSTs, we show that the land/sea contrast in equilibrium simulations is associated
with local feedbacks and the hydrological cycle over land, rather than with externally imposed radiative forcing. This mechanism
also explains a large component of the land/sea contrast in transient simulations as well. We propose a conceptual model with
three elements: (1) there is a spatially variable level in the lower troposphere at which temperature change is the same over
land and sea; (2) the dependence of lapse rate on moisture and temperature causes different changes in lapse rate upon warming
over land and sea, and hence a surface land/sea temperature contrast; (3) moisture convergence over land predominantly takes
place at levels significantly colder than the surface; wherever moisture supply over land is limited, the increase of evaporation
over land upon warming is limited, reducing the relative humidity in the boundary layer over land, and hence also enhancing
the land/sea contrast. The non-linearity of the Clausius–Clapeyron relationship of saturation specific humidity to temperature
is critical in (2) and (3). We examine the sensitivity of the land/sea contrast to model representations of different physical
processes using a large ensemble of climate model integrations with perturbed parameters, and find that it is most sensitive
to representation of large-scale cloud and stomatal closure. We discuss our results in the context of high-resolution and
Earth-system modelling of climate change. 相似文献
20.
Statistical and dynamical assessment of vegetation feedbacks on climate over the boreal forest 总被引:1,自引:1,他引:0
Vegetation feedbacks over Asiatic Russia are assessed through a combined statistical and dynamical approach in a fully coupled
atmosphere–ocean–land model, FOAM-LPJ. The dynamical assessment is comprised of initial value ensemble experiments in which
the forest cover fraction is initially reduced over Asiatic Russia, replaced by grass cover, and then the climatic response
is determined. The statistical feedback approach, adopted from previous studies of ocean–atmosphere interactions, is applied
to compute the feedback of forest cover on subsequent temperature and precipitation in the control simulation. Both methodologies
indicate a year-round positive feedback on temperature and precipitation, strongest in spring and moderately substantial in
summer. Reduced boreal forest cover enhances the surface albedo, leading to an extended snow season, lower air temperatures,
increased atmospheric stability, and enhanced low cloud cover. Changes in the hydrological cycle include diminished transpiration
and moisture recycling, supporting a reduction in precipitation. The close agreement in sign and magnitude between the statistical
and dynamical feedback assessments testifies to the reliability of the statistical approach. An additional statistical analysis
of monthly vegetation feedbacks over Asiatic Russia reveals a robust positive feedback on air temperature of similar quantitative
strength in two coupled models, FOAM-LPJ and CAM3–CLM3, and the observational record.
CCR Contribution # 931. 相似文献