共查询到19条相似文献,搜索用时 359 毫秒
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本文对全球平均、各纬带平均和几种特殊下垫面条件下大气顶和地表面的净辐射随云量变化的情况进行定量分析,并讨论了净辐射对云量变化的敏感性随各参数改变的情况。另外还定性地讨论了云在全球气候中的反馈作用以及这种反馈作用随各参数变化的特点。指出:一般条件下,净辐射对于云量变化是敏感的,只有当气候参数变化到临界值附近时,对气候的模拟可以不考虑云量的变化。从云量对气候的反馈来看,在气候参数发生变化时,气候系统的稳定性会发生本质的改变。 相似文献
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本文利用地球辐射平衡试验(ERBE)和国际卫星云气候计划(ISCCP)提供的地气系统行星反射率,长波射出辐射(OLR)和云量资料,计算出中国地区年、月总云量对地气系统净辐射的强迫,分别讨论了其与总云量及地气系统晴天净辐射的关系。结果表明:地气系统净辐射云强迫与总云量有较好的抛线物关系,各月净辐射云强迫与地气系统晴天净辐射的曲线相关也很明显,如以曲线上净辐射云强迫为零时的晴天净辐射值代表各月曲线位置,则该值随天文辐射作规律性季节变化。地气系统净辐射云强迫的地理分布与总云量及地气晴天净辐射分布有关,其在各地的年变化则主要由天文因素及雨季进行退决定。 相似文献
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中国地区云对地-气系统辐射强迫温度效应的气候研究 总被引:4,自引:2,他引:4
文中利用地球辐射平衡试验 (ERBE)和国际卫星云气候计划 (ISCCP)提供的地 气系统行星反射率、射出长波辐射 (OLR)和云量资料 ,计算了中国地区年、月平均总云量对地 气系统短波辐射、长波辐射以及净辐射强迫的温度效应和敏感性系数 ,并讨论了云对各辐射分量强迫的温度效应与总云量的关系。结果表明 :地 气系统云辐射强迫温度效应与总云量间具有较明显的曲线相关。云辐射强迫温度效应及其敏感性系数具有明显的时空变化特点。就中国全国平均而言 ,各月地 气系统云辐射强迫净温度效应一般表现为降温作用。 相似文献
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IAP AGCM对全球海温异常的响应——CO_2引起气候变化的等效研究 总被引:2,自引:0,他引:2
本文用IAP AGCM研究全球海温异常引起的气候变化,这种变化可以看作是由于CO_2含量改变引起的响应。按照Ramanathan和Cess等的观点,太阳常数的改变、CO_2含量的增减及全球海温异常对地气系统能量收支的影响是一致的,主要受控于射出净辐射的改变.本工作分别以+4℃和-4℃作为全球海温异常得到两次积分,分别记为I和D,模式的长期气候平均用作基本状态试验,记为C. 当海温增加4℃时,地表气温约增加4.4℃,而且主要由于热带对流加热的影响,气温的变化随高度增加,冬半球地表气温的增加明显大于夏半球,这是由雪的反照率和垂直温度递减率的反馈作用引起的。虽然全球平均总云量随海温增加而减少,但其纬向分布是不均匀的,尤其对个别类型的云更是如此。云的反馈在辐射能量收支中起着重要作用,例如,热带模式层顶净向下太阳辐射(S)和净向上长波辐射(R)减少(或增加最少)就归咎于穿透性对流云的增加. 全球平均降水I比C多18%.降水的变化呈正反馈趋势,即热带降水最大的地区降水加大,而在副热带地区降水增加很小,甚至减少.纬度-时间图上,降水的变化呈带状分布,正象降水本身的变化一样. 虽然我们得到的全球平均和纬向平均与Mitchell的结果一致,但区域性海温异常响应存在很大差别. 相似文献
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青藏高原地区云对地表净辐射的影响 总被引:8,自引:2,他引:8
利用1982年8月-1983年7月青藏高原地面热源观测实验资料,分析了云量,云状对地表净辐射的影响,计算了与云对地表净辐射强迫作用有关的参数。研究表明:地表净辐射是云量的线性函罢 2对地表净辐射的影响有明显的季节性差异,在春季和夏季,云对地表净辐射的影响非常强烈,并且地表净辐射随云量的增多而减小,在秋季和冬季,云对地表净辐的影响较小,并且地表净辐射随云量的增多百增大。 相似文献
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本世纪海洋云量变化与全球增暖问题 总被引:6,自引:0,他引:6
本文分析了1900~1990年间全球海洋总云量。为消除资料序列中非气候因素的影响,序列被分为3个时段进行讨论。发现本世纪内与气候增暖的同时全球海洋云量有明显增加,但云量变化落后于全球平均气温变化1~4年,落后于全球平均海温1~2年,且云与温度变化的关系在不同气候带不同,这可能是不同气候带上主要云型不同,以致产生的辐射强迫效应不同。 相似文献
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区域气候模式中云量参数化方案的研究 总被引:5,自引:1,他引:5
首先统计并分析了模式区域内夏季平均的云量分布状况,然后在一有限区域模式中,引进了云-辐射计算模式。比较了3种不同的云量参数化方案,最后提出了一种考虑了大气相对湿度、垂直运动速度的本模式的云量参数化方案,并简要介绍了模式引入不同方案后的模拟结果。模拟结果表明,本模式的方案模拟的云量分布及气候要素场都与实况最接近,说明这一机制反映了云在气候系统中的反馈作用。不同的区域模式宜用不同的云量参数化方案。云量 相似文献
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文章提出了一种简单且适用于大气环流模式(GCM)的冰云辐射参数化。利用该参数化和UGAMP大气环流模式研究了混合云在GCM气候模拟中的重要性。结果表明,云的相态变化及其所产生的反馈作用对模拟的气候状态有显著的影响。在高纬地区,云的相态变化可使地气系统净辐射增加。而在热带则使净辐射减少。 相似文献
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青藏高原云对地气系统净辐射强迫的气候研究 总被引:1,自引:0,他引:1
利用地球辐射平衡试验(ERBE)和国际卫星云气候计划(ISCCP)提供的地气系统行星反射率、长波射出辐射(OLR)和云量资料,计算了青藏高原地区云对地气系统净辐射的强迫,并讨论其与总云量及地气系统晴天净辐射的关系。结果表明:高原各季净辐射云强迫与总云量有较好的非线性关系,其中以暖季更明显;各月净辐射云强迫与地气系统晴天净辐射的曲线相关很明显,各条曲线均存在一个与净辐射云强迫零值相对应的晴天净辐射值 相似文献
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Prof. K. N. Liou J. L. Lee S. C. Ou Q. Fu Y. Takano 《Meteorology and Atmospheric Physics》1991,46(1-2):41-50
Summary Parameterization programs for cloud microphyscs and radiative transfer involving ice clouds have been developed in terms of the mean effective size and ice water path. The mean effective size appears to be adequate in representing the ice crystal size distribution for radiative parameterizations. For a given ice water path, smaller mean effective sizes reflect more solar radiation, emit more IR radiation and enhance net radiative heating/cooling at the cloud top and bottom than larger sizes. The presence of small ice crystals may generate steeper lapse rates in clouds. A 3-D global cloud model that prescribes the horizontal wind fields in a 24 hour period is used to investigate the sensitivity of the mean effective size of ice crystals on the simulation of radiative heating, temperature, cloud cover and ice water content. A variation in the mean effective size from 75 to 50 m in a 24 hour prediction on simulation generates more cooling above the high cloud top and a decrease of temperature. These results lead to an increase of high cloud cover in some latitudes by as much as 4% and, at the same time, a decrease of middle cloud cover by 3–4% in latitudes between 60°S and 60°N.With 7 Figures 相似文献
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Summary Global maps of the monthly mean net upward longwave radiation flux at the ocean surface have been obtained for April, July, October 1985 and January 1986. These maps were produced by blending information obtained from a combination of general circulation model cloud radiative forcing fields, the top-of-the-atmosphere cloud radiative forcing from ERBE and TOVS profiles and sea surface temperature on ISCCP C1 tapes. The fields are compatible with known meteorological regimes of atmospheric water vapor content and cloudiness. There is a vast area of high net upward longwave radiation flux (> 80 W m–2) in the eastern Pacific Ocean throughout most of the year. Areas of low net upward longwave radiation flux (< 40 Wm–2) are the tropical convective regions and extra tropical regions that tend to have persistent low cloud cover. The technique used in this study relies on GCM simulations and so is subject to some of the uncertainties associated with the model. However, all input information regarding temperature, moisture and cloud cover is from satellite data having near global coverage. This feature of the procedure alone warrants its consideration for further use in compiling global maps of the net longwave radiation at the surface over the oceans.With 9 Figures 相似文献
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根据ERBE和ISCCP资料讨论了总云量等因子对地-气系统净辐射的影响,分析了地-气系统净辐射与其各分量及地表净辐射的相关联系。发现行星反射率和地气短波吸收辐射对地-气净辐射的影响最大,而云和纬度的作用主要通过该两因子变化表现出来,OLR的作用则相对较弱。地-气净辐射与地表净辐射的相关性也较明显。文中还就地-气净辐射在全国的地理分布作了分析。各地区地-气净辐射的年变曲线均为简单的夏大冬小型,云等因素的影响主要造成最大值出现月份的推移。 相似文献
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本文在全海洋地球的假定下,建立了一个包括太阳辐射、海面温度等季节变化的理想动力气候模式。模拟结果指出:平衡态及其对外参数敏感性的季节变化很大,而且都是夏季比其它季节大得多;四个季节敏感性的平均值也比年平均模式的敏感性大,这可能主要是太阳辐射季节变化引起的。另外,当太阳常数或二氧化碳浓度减小至一定值时,会出现分岔,若继续减小到分岔点以下,则会发生气候灾变—"深冻"。分岔点上外参数的值在夏季要比其它三个季节大得多。以上结果表明物理过程的季节变化在长期气候变化的研究中是不可忽视的。 相似文献
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Sensitivity of tropical climate to low-level clouds in the NCEP climate forecast system 总被引:1,自引:1,他引:0
Zeng-Zhen Hu Bohua Huang Yu-Tai Hou Wanqiu Wang Fanglin Yang Cristiana Stan Edwin K. Schneider 《Climate Dynamics》2011,36(9-10):1795-1811
In this work, we examine the sensitivity of tropical mean climate and seasonal cycle to low clouds and cloud liquid water path (CLWP) by prescribing them in the NCEP climate forecast system (CFS). It is found that the change of low cloud cover alone has a minor influence on the amount of net shortwave radiation reaching the surface and on the warm biases in the southeastern Atlantic. In experiments where CLWP is prescribed using observations, the mean climate in the tropics is improved significantly, implying that shortwave radiation absorption by CLWP is mainly responsible for reducing the excessive surface net shortwave radiation over the southern oceans in the CFS. Corresponding to large CLWP values in the southeastern oceans, the model generates large low cloud amounts. That results in a reduction of net shortwave radiation at the ocean surface and the warm biases in the sea surface temperature in the southeastern oceans. Meanwhile, the cold tongue and associated surface wind stress in the eastern oceans become stronger and more realistic. As a consequence of the overall improvement of the tropical mean climate, the seasonal cycle in the tropical Atlantic is also improved. Based on the results from these sensitivity experiments, we propose a model bias correction approach, in which CLWP is prescribed only in the southeastern Atlantic by using observed annual mean climatology of CLWP. It is shown that the warm biases in the southeastern Atlantic are largely eliminated, and the seasonal cycle in the tropical Atlantic Ocean is significantly improved. Prescribing CLWP in the CFS is then an effective interim technique to reduce model biases and to improve the simulation of seasonal cycle in the tropics. 相似文献
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Solar Radiation Climatology of Alaska 总被引:1,自引:1,他引:0
Summary There are only six locations in Alaska for which global radiation data of more than a year in duration are available. This
is an extremely sparse coverage for a state which covers 1.5×10&6 km2 and stretches over at least three climatic zones. Cloud observations are, however, available from 18 stations. We used fractional
cloud cover and cloud type data to model the global radiation and thus obtain a more complete radiation coverage for Alaska.
This extended data set allowed an analysis of geographic and seasonal trends.
A simple 1-layer model based on Haurwitz’s semi-empirical approach, allowing for changes in cloud type and fractional coverage,
was developed. The model predicts the annual global radiation fluxes to within 2–11% of the observed values. Estimated monthly
mean values gave an average accuracy within about 6% of the measurements. The estimates agree well with the observations during
the first four months of the year but less so for the last four. Changing surface albedo might explain this deviation.
Previously, the 1993 National Solar Radiation Data Base (NSRDB) from the National Renewable Energy Laboratory (NREL) modeled
global radiation data for 16 Alaskan stations. Although more complete and complex, the NREL model requires a larger number
of input parameters, which are not available for Alaska. Hence, we believe that our model, which is based on cloud-radiation
relationship and is specifically tuned to Alaskan conditions, produces better results for this region. Annual global solar
radiation flux measurements are compared with results from global coverage models based on the International Satellite Cloud
Climatology Project (ISCCP) data. Contour plots of seasonal and mean annual spatial distribution of global radiation for Alaska
are presented and discussed in the context of their climatic and geographic settings.
Received July 16, 1997 Revised May 18,1998 相似文献
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Abstract The sensitivity of the annual cycle of ice cover in Baffin Bay to short‐wave radiation is investigated. The Princeton Ocean Model (POM) is used and is coupled with a multi‐category, dynamic‐thermodynamic sea‐ice model in which the surface energy balance governs the growth rates of ice of varying thickness. During spring and summer the short‐wave radiation flux dominates other surface heat fluxes and thus has the greatest effect on the ice melt. The sensitivity of model results to short‐wave radiation is tested using several, commonly used, shortwave parameterizations under climatological, as well as short‐term, atmospheric forcing. The focus of this paper is short‐term and annual variability. It is shown that simulated ice cover is sensitive to the short‐wave radiation formulation during the melting phase. For the Baffin Bay simulation, the differences in the resulting ice area and volume, integrated from May to November, can be as large as 45% and 70%, respectively. The parameterization of the effect of cloud cover on the short‐wave radiation can result in the sea‐ice area and volume changes reaching 20% and 30%, respectively. The variation of the cloud amount represents cloud data error, and has a relatively small effect (less then ±4%) on the simulated ice conditions. This is due to the fact that the effect of cloud cover on the short‐wave radiation flux is largely compensated for by its effect on the net near‐surface long‐wave radiation flux. 相似文献