共查询到19条相似文献,搜索用时 609 毫秒
1.
一个气候系统模式对小冰期外强迫变化的平衡态响应 总被引:3,自引:1,他引:2
本文利用中国科学院大气物理研究所大气科学和地球流体力学数值模拟国家重点实验室发展的气候系统模式FGOALS_gl, 通过设定小冰期的太阳辐射变化, 模拟了小冰期的气候平衡态, 讨论了小冰期气候变化的机理。数值试验结果表明, 由太阳辐照度变化和火山活动共同作用造成的太阳辐射减少是小冰期气候的重要成因, 模拟的小冰期表层气温变化分布与重建资料在全球大多数地区较为一致。就全球平均情况而言, 小冰期的年平均气温较之1860年偏冷0.15℃, 较之20世纪平均情况偏冷0.6℃左右。小冰期温度变化存在显著的地域和季节特征, 表现为北半球降温幅度大于南半球, 高纬地区降温幅度大于低纬地区, 夏季的降温幅度大于冬季。东亚地区小冰期温度较之1860年和20世纪分别偏冷0.3℃和0.6℃。小冰期的降水异常中心位于低纬地区, 主要表现为赤道中东太平洋降水负异常和赤道中西太平洋降水正异常, 以及位于热带印度洋的降水偶极子型。除欧洲和北美外, 全球其他地区陆地降水均减少。东亚地区小冰期夏季降水的变化最为显著, 较之1860年, 华北、 东北地区降水增加, 而长江流域以南降水则减少; 较之20世纪, 东部降水异常表现出华北地区偏多、长江流域偏少、华南地区偏多的“三极型” 分布特征。 相似文献
2.
3.
文章比较了各种气候模式对温室效应的估计,及其可能对中国气候的影响。分析和预测了太阳活动与火山活动的长期变化,在此基础上估计了未来可能产生的自然气候变化。结果表明,在未来50年中太阳活动和火山活动均可能使气候变冷。因此,可能在一定程度上抵消因温室效应加剧而产生的变暖。但在2010年之后,温室效应可能逐步占据主导地位,到2030年全球平均气温可能比1961~1990年平均上升0.6℃以上,东亚地区的增温,可能比全球平均稍强。气候变暖后,东亚地区降水可能增加。但在我国北方,夏季干旱程度可能加大。 相似文献
4.
利用参与第三次古气候模式评估比较计划(Paleoclimate Modelling Intercomparison Project Phase III,PMIP3)过去千年气候模拟试验以及参与第五次耦合模式评估比较计划(Paleoclimate Model Intercomparison Project Phase 5,CMIP5)全强迫历史情景试验的9个地球系统模式模拟试验结果,对过去千年3个特征时段(中世纪气候异常期、小冰期和现代暖期)北极涛动(Arctic Oscillation, AO)的变率及成因进行了分析。通过与NCEP再分析资料的对比发现,模式能够较好地模拟出AO的空间模态及年际变化周期,且大部分模式能够模拟出过去50年AO的增强趋势。过去千年3个特征时段中,不同模式对中世纪气候异常期AO位相的模拟并不一致,但大部分模式显示小冰期AO基本呈现负位相,而现代暖期则表现为显著的正位相,与重建结果一致。基于多模式集合平均的机制分析表明,中世纪气候异常期北极地区海平面气压变化不显著,小冰期北极地区海平面气压显著偏正,现代暖期海平面气压显著偏负,这与现代暖期北极温度偏高而小冰期北极温度偏低有关。过去千年中,小冰期和现代暖期的AO变率分别受自然外强迫和人为外强迫的影响。 相似文献
5.
通过对小冰期研究文献进行综述,并对已发表的小冰期温度和降水数据进行综合对比分析,探讨小冰期时期中国气候特征的区域性.结果表明,小冰期在中国地区不同区域代用指标记录中均存在,但是小冰期的起讫及持续时间具有区域差异性,温湿配置也不尽相同.小冰期的起始时间主要呈现出由西向东推移的趋势,即青藏高原最早,华北地区次之而东部地区最晚.温湿配置的差异主要体现在东部季风区小冰期时期总体上是冷干的气候环境,而西部地区气候变化则呈现冷湿的气候特征. 相似文献
6.
近千年全球温度变化研究的新进展 总被引:16,自引:0,他引:16
结合国内外有关研究,综合评述了美国国家科学院国家研究理事会的报告 --"近两千年地面温度的重建"。重点介绍了气候变暖的新证据,3个特征时期即20世纪气候变暖、小冰期(LIA)、中世纪暖期(MWP)和近千年温度变化模拟的结果。 相似文献
7.
利用冰芯、树轮、石笋、湖泊沉积和历史文献等多种代用资料进行小冰期的研究已取得了较大进展。研究表明:小冰期是全球性的气候异常期,时间跨度约为500 a (1400-1900 AD);小冰期气候变化的干(湿)/冷(暖)配置在全球存在区域性差异,其变化幅度、起讫和持续时间也因地而异。小冰期气候的形成,受到太阳、火山活动、大气环流,以及大气、海洋和陆地间相互作用的影响。综合分析小冰期在全球的时空分布特点和形成的可能原因,对小冰期研究中仍未解决的主要问题及今后研究的重点进行了展望。 相似文献
8.
CMIP3气候模式对东亚冬季大气环流模拟能力的评估 总被引:1,自引:0,他引:1
利用1960—1999年ECMWF月平均再分析资料(ERA40)和耦合模式比较计划(Phase 3 of the CoupledModel Intercomparison Project,简称CMIP3)21个气候耦合模式对20世纪气候模拟试验的模式结果,从气候态和年际变化两个方面,评估了CMIP3气候模式对东亚冬季大气环流的模拟能力。结果表明:(1)模式对东亚地区冬季海平面气压、850 hPa纬向风、经向风和500 hPa高度场气候态的模拟存在不同程度的偏差,但均能较好模拟出上述要素气候态的空间分布特征。总体而言,模式对500 hPa高度场气候态的模拟效果最好,而对850 hPa经向风的模拟效果较差。(2)模式基本上能抓住近40年来东亚地区冬季500 hPa高度场的主要变化特征,但基本上不能模拟出冬季海平面气压、850 hPa纬向风和经向风的变化特征。此外,模式对阿留申低压、蒙古高压和东亚冬季风强度的变化特征几乎没有模拟能力。 相似文献
9.
区域气候模式对东亚气候时空演变特征的模拟研究 总被引:4,自引:2,他引:2
利用区域环境集成模式系统对东亚地区进行了1987年1月到1996年12月的长期积分试验,重点采用经验正交函数分析方法分析和比较模式模拟及观测气候主分量时空特征,从而考察区域气候模式对东亚地区的区域气候模拟能力.结果表明:(1) RIEMS能够较好地抓住地面气温年平均状况及其年变化和年际变率的主要特征;(2)尽管模式对降水的模拟能力没有对地面气温模拟的强,但RIEMS模式基本上能够模拟出降水的空间分布以及降水的季节变化特征,同时能够抓住降水的年际变率.
相似文献
10.
利用改进的区域气候模式(RegCM-NCC)对东亚区域进行了连续5年(1998~2002年)的气候模拟,并对模拟的东亚冬季风情况进行了全面分析.结果表明该模式能够较好地模拟出东亚地区冬季平均环流特征,较真实反映出冬季低层大陆冷高压的平均位置与强度,也能够揭示出冬季风场变化的主要特征,如低层的冬季风气流及高层的西风急流;对冬季风强度及年际变化也有较好的反映,对冬季季风涌出现的频率、主要区域以及温度的演变等气候特征的模拟与实况一致.通过比较分析,对该模式在东亚冬季风等方面模拟性能有较全面的认识,便于模式的应用及进一步改进. 相似文献
11.
Youbing Peng Hai Cheng Caiming Shen Ying Xu Naifang Bei 《Asia-Pacific Journal of Atmospheric Sciences》2018,54(3):445-455
Widely distributed proxy records show that there were out-of-phase behaviors of moisture change between arid central Asia (ACA) and monsoonal northern China during the Little Ice Age (LIA) and Medieval Climate Anomaly (MCA). We examined spatial pattern differences between the MCA and LIA to identify contrasting patterns of summer precipitation variability, and to diagnose explanatory mechanisms through the analysis of a 1000-year global climate model simulation driven by natural and anthropogenic forcing. The results show that the model was able to roughly produce the general features of MCA-LIA hydroclimatic spatial differences between monsoonal northern China and ACA, with a relatively wet MCA found in monsoonal northern China and a relatively dry MCA found in ACA. A further analysis of associated circulations shows that increased summer precipitation in monsoonal northern China was caused by the strengthening of summer monsoon, while the decline in summer precipitation in ACA was caused by an anomalous northward displacement of the subtropical westerly jet stream. Our analyses suggest that both effective solar forcing and El-Niño Southern Oscillation (ENSO) may produce these contrasting patterns of precipitation between monsoonal northern China and ACA. Due to a change in the probability of ENSO phases at the centennial time scale found in our experiments may be attributed to solar irradiances, higher effective solar irradiances during the MCA relative to those of the LIA may have been the ultimate forcing mechanism for the simulated precipitation differences between the MCA and LIA. 相似文献
12.
An analytic solution of an energy balance model (EBM) is presented which can beused as a recursive filter for time series analysis. It is shown that the EBM can reproduce the solution of a coupled atmosphere-ocean general circulation model (AOGCM) experiment. Contrary to the AOGCM, the EBM easily allows for variations in climate sensitivity to satisfy the full range of uncertainty concerned with this parameter. The recursive filter is applied to two natural and two anthropogenic forcing mechanisms which are expressed in terms of heating rate anomaly time series: volcanism, solar activity, greenhouse gases (GHG), and anthropogenic tropospheric aerosols. Thus, we obtain modelled global mean temperature variations as a response to the different forcings and with respect to the uncertainty in the forcing approximations and climate sensitivity. In addition, it is shown that the observed (ENSO-corrected) global mean temperature time series within the period from 1866 to 1997 can be explained by the external forcings which have been considered and an additional white noise forcing. In this way we are able to separate different signals and compare them. As a result, global anthropogenic climate change due to GHG forcing can be detected at a high level of significance without considering spatial patterns of climate change but including natural forcing, which is usually not done. Furthermore, it is shown that solar forcing alone does not lead to significantclimate change, whereas solar and volcanic forcing together lead to a significant natural climate change signal. Anthropogenic climate change due to GHG forcing may partly be masked by anthropogenic aerosol cooling. 相似文献
13.
Prediction of the Pacific sea surface temperature (SST) anomaly in the coming decades is a challenge as the SST anomaly changes over time due to natural and anthropogenic climate forcing. The climate changes in the mid-1970s and late-1990s were related to the decadal Pacific SST variability. The changes in the mid-1970s were associated with the positive phase of decadal El Niño-Southern Oscillation (ENSO)-like SST variation, and the changes in the late-1990s were related to its negative phase. However, it is not clear whether this decadal SST variability is related to any external forcing. Here, we show that the effective solar radiation (ESR), which includes the net solar radiation and the effects of volcanic eruption, has modulated this decadal ENSO-like oscillation. The eastern Pacific warming (cooling) associated with this decadal ENSO-like oscillation over the past 139 years is significantly related to weak (strong) ESR. The weak ESR with strong volcanic eruption is found to strengthen the El Niño, resulting in an El Niño-like SST anomaly on the decadal time scale. The strong eruptions of the El Chicho’n (1982) and Pinatubo (1991) volcanoes reduced the ESR during the 1980s and 1990s, respectively. The radiation reduction weakened the Walker circulation due to the “ocean thermostat” mechanism that generates eastern Pacific warming associated with a decadal El Niño-like SST anomaly. This mechanism has been confirmed by the millennium run of ECHO-G model, in which the positive eastward gradient of SST over the equatorial Pacific was simulated under the weak ESR forcing on the decadal time scale. We now experience a reversal of the trend in the ESR. The strong solar radiation and lack of strong volcanic eruptions over the past 15 years have resulted in strong ESR, which should enhance the Walker circulation, leading to a La Niña-like SST anomaly. 相似文献
14.
Volcanic and solar impacts on climate since 1700 总被引:6,自引:0,他引:6
Numerical experiments have been carried out with a two-dimensional sector averaged global climate model with a detailed radiative
scheme in order to assess the possible impact of solar and volcanic activities on the Earth’s surface temperature at the secular
time scale from 1700 to 1992. Our results indicate that while the general trend of the observed temperature variations on
the century time scale can be generated in response to both the solar and volcanic forcings, these are clearly not sufficient
to explain the observed 20th century warming and more specifically the warming trend which started at the beginning of the
1970s. However, the lack of volcanism during the period 1925–1960 could account, at least partly, for the observed warming
trend in this period. Finally, while Schlesinger and Ramankutty (1994) assumed that random forcing could not be a possible
source of the 65–70 year oscillation they detected in the global climate system, our results indicate that the volcanic forcing
over the past 150 years could have introduced an oscillation of around 70 years in the Earth’s surface temperature.
Received: 25 August 1997/Accepted: 27 November 1998 相似文献
15.
Xiaodong XIE Xiaoxian HUANG Tijian WANG Mengmeng LI Shu LI Pulong CHEN 《Journal of Meteorological Research》2018,(3)
Carbon dioxide(CO_2) is an important greenhouse gas that influences regional climate through disturbing the earth's energy balance. The CO_2 concentrations are usually prescribed homogenously in most climate models and the spatiotemporal variations of CO_2 are neglected. To address this issue,a regional climate model(RegCM4) is modified to investigate the non-homogeneous distribution of CO_2 and its effects on regional longwave radiation flux and temperature in East Asia. One-year simulation is performed with prescribed surface CO_2 fluxes that include fossil fuel emission, biomass burning, air-sea exchange, and terrestrial biosphere flux. Two numerical experiments(one using constant prescribed CO_2 concentrations in the radiation scheme and the other using the simulated CO_2 concentrations that are spatially non-homogeneous) are conducted to assess the impact of non-homogeneous CO_2 on the regional longwave radiation flux and temperature. Comparison of CO_2 concentrations from the model with the observations from the GLOBALVIEW-CO_2 network suggests that the model can well capture the spatiotemporal patterns of CO_2 concentrations. Generally, high CO_2 mixing ratios appear in the heavily industrialized eastern China in cold seasons, which probably relates to intensive human activities. The accommodation of non-homogeneous CO_2 concentrations in the radiative transfer scheme leads to an annual mean change of -0.12 W m~(-2) in total sky surface upward longwave flux in East Asia. The experiment with non-homogeneous CO_2 tends to yield a warmer lower troposphere.Surface temperature exhibits a maximum difference in summertime, ranging from -4.18 K to 3.88 K, when compared to its homogeneous counterpart. Our results indicate that the spatial and temporal distributions of CO_2 have a considerable impact on regional longwave radiation flux and temperature, and should be taken into account in future climate modeling. 相似文献
16.
Forced response of the East Asian summer rainfall over the past millennium: results from a coupled model simulation 总被引:1,自引:0,他引:1
The centennial?Cmillennial variation of the East Asian summer monsoon (EASM) precipitation over the past 1000?years was investigated through the analysis of a millennium simulation of the coupled ECHO-G model. The model results indicate that the centennial?Cmillennial variation of the EASM is essentially a forced response to the external radiative forcing (insolation, volcanic aerosol, and green house gases). The strength of the response depends on latitude; and the spatial structure of the centennial?Cmillennial variation differs from the interannual variability that arises primarily from the internal feedback processes within the climate system. On millennial time scale, the extratropical and subtropical precipitation was generally strong during Medieval Warm Period (MWP) and weak during Little Ice Age (LIA). The tropical rainfall is insensitive to the effective solar radiation forcing (insolation plus radiative effect of volcanic aerosols) but significantly responds to the modern anthropogenic radiative forcing. On centennial time scale, the variation of the extratropical and subtropical rainfall also tends to follow the effective solar radiation forcing closely. The forced response features in-phase rainfall variability between the extratropics and subtropics, which is in contrast to the anti-correlation on the interannual time scale. Further, the behavior of the interannual?Cdecadal variation in the extratropics is effectively modulated by change of the mean states on the millennial time scale, suggesting that the structure of the internal mode may vary with significant changes in the external forcing. These findings imply that on the millennial time scale, (a) the proxy data in the extratropical EA may more sensitively reflect the EASM rainfall variations, and (b) the Meiyu and the northern China rainfall provide a consistent measure for the EASM strength. 相似文献
17.
The Dalton Minimum (1790–1830) was a period with reduced solar irradiance and strong volcanic eruptions. Additionally, the
atmospheric CO2 concentrations started to rise from the background level of previous centuries. In this period most empirical climate reconstructions
indicate a minimum in global or hemispheric temperatures. Here, we analyse several simulations starting in 1755 with the coupled
atmosphere-ocean model ECHO-G driven by different forcing combinations to investigate which external forcing could have contributed
most strongly to the reduced temperatures during the Dalton Minimum. Results indicate that on global and hemispheric scales,
the volcanic forcing is largely responsible for the temperature drop in this period, especially during its second half, whereas
changes in solar forcing and the increasing atmospheric CO2 concentrations were of minor importance. At regional scales, especially the extratropical, the impact of volcanic forcing
is much less discernible due to the large regional variability, a finding that agrees with empirical temperature reconstructions. 相似文献
18.
Hyung-Gyu Lim Sang-Wook Yeh Ji-Won Kim Rokjin Park Chang-Keun Song 《Meteorology and Atmospheric Physics》2014,126(1-2):71-79
Due to the dramatic increase in the global mean surface temperature (GMST) during the twentieth century, the climate science community has endeavored to determine which mechanisms are responsible for global warming. By analyzing a millennium simulation (the period of 1000–1990 ad) of a global climate model and global climate proxy network dataset, we estimate the contribution of solar and greenhouse gas forcings on the increase in GMST during the present warm period (1891–1990 ad). Linear regression analysis reveals that both solar and greenhouse gas forcing considerably explain the increase in global mean temperature during the present warm period, respectively, in the global climate model. Using the global climate proxy network dataset, on the other hand, statistical approach suggests that the contribution of greenhouse gas forcing is slightly larger than that of solar forcing to the increase in global mean temperature during the present warm period. Overall, our result indicates that the solar forcing as well as the anthropogenic greenhouse gas forcing plays an important role to increase the global mean temperature during the present warm period. 相似文献
19.
George C. Reid 《Climatic change》1997,37(2):391-405
Spacecraft measurements of the sun's total irradiance since 1980 have revealed a long-term variation that is roughly in phase with the 11-year solar cycle. Its origin is uncertain, but may be related to the overall level of solar magnetic activity as well as to the concurrent activity on the visible disk. A low-pass Gaussian filtered time series of the annual sunspot number has been developed as a suitable proxy for solar magnetic activity that contains a long-term component related to the average level of activity as well as a short-term component related to the current phase of the 11-year cycle. This time series is also assumed to be a proxy for solar total irradiance, and the irradiance is reconstructed for the period since 1617 based on the estimate from climatic evidence that global temperatures during the Maunder Minimum of solar activity, which coincided with one of the coldest periods of the Little Ice Age, were about 1 °C colder than modern temperatures. This irradiance variation is used as the variable radiative forcing function in a one-dimensional ocean–climate model, leading to a reconstruction of global temperatures over the same period, and to a suggestion that solar forcing and anthropogenic greenhouse-gas forcing made roughly equal contributions to the rise in global temperature that took place between 1900 and 1955. The importance of solar variability as a factor in climate change over the last few decades may have been underestimated in recent studies. 相似文献