PDF(3353 KB)
PDF(3353 KB)
PDF(3353 KB)
东亚夏季风对全新世暖期与当前增暖的响应差异及成因
Response differences and causes of the East Asian Summer Monsoon to the Holocene Thermal Maximum and current warming
为弥补东亚夏季风现代观测资料的不足,完善其动力学认识,提升对其未来演变的预估能力,本文利用CMIP6-PMIP4多模式,对全新世暖期与当前增暖下东亚夏季风的响应进行模拟,明确其差异、成因和影响因素。研究发现:东亚夏季风在全新世暖期的增强幅度远大于当前增暖,该响应差异源于全新世暖期和当前增暖驱动因素的不同,当前增暖下气溶胶排放的影响进一步减弱了东亚夏季风的响应幅度。全新世暖期东亚夏季风显著增强,呈现北方降水增多、南方降水减少的空间分布;当前增暖下季风响应微弱,降水空间分布与全新世暖期明显不同。夏季海陆热力对比差异是两类暖期季风响应差异的核心机制。本研究明晰了东亚夏季风对不同外强迫驱动增暖的响应规律,深化了对季风动力学的认识,可为东亚夏季风未来演变的准确预估提供科学依据。
To address the scarcity of modern East Asian Summer Monsoon (EASM) observations, improve dynamical mechanisms and enhance future projection capability, multiple CMIP6-PMIP4 models were adopted to investigate EASM responses to the Holocene Thermal Maximum and current warming, with their differences, mechanisms and controlling factors were clarified. The EASM intensification during the Holocene Thermal Maximum was far stronger than that under current warming, which originates from distinct forcings between the Holocene Thermal Maximum and current warming, and aerosol emissions under current warming further dampen the response amplitude of the EASM. Remarkable EASM intensification occurred during the Holocene Thermal Maximum, featuring increased northern precipitation and reduced southern precipitation. By contrast, weak monsoon responses appeared under current warming with distinct precipitation spatial patterns. Summer land-sea thermal contrast differences dominated such divergent responses. This study elucidates the response law of the EASM to warming driven by distinct external forcings, deepens the understanding of monsoon dynamics, and provides theoretical support for future EASM projection.
东亚夏季风 / 增暖 / 全新世 / 太阳辐射 / 海陆热力对比 / 动力学 / 温室气体 / 气溶胶
East Asian Summer Monsoon / warming / Holocene / solar insolation / land-ocean thermal contrast / dynamics / greenhouse gases / aerosols
| [1] |
A detailed and well-dated proxy record of summer rainfall variation in arid Central Asia is lacking. Here, we report a long-term, high resolution record of summer rainfall extracted from a peat bog in arid eastern-Central Asia (AECA). The record indicates a slowly but steadily increasing trend of summer rainfall in the AECA over the past 8500 years. On this long-term trend are superimposed several abrupt increases in rainfall on millennial timescales that correspond to rapid cooling events in the North Atlantic. During the last millennium, the hydrological climate pattern of the AECA underwent a major change. The rainfall in the past century has reached its highest level over the 8500-year history, highlighting the significant impact of the human-induced greenhouse effect on the hydrological climate in the AECA. Our results demonstrate that even in very dry eastern-Central Asia, the climate can become wetter under global warming.
|
| [2] |
|
| [3] |
|
| [4] |
The responses of the East Asian summer monsoon (EASM) to the Indian summer monsoon (ISM) have been the subject of extensive investigation. Nevertheless, it remains uncertain whether the ISM can serve as a predictor for the EASM. Here, on the basis of both observations and a large-ensemble climate model experiment, we show that the subseasonal variability of abnormal diabatic heating over India enhances precipitation over central East China, the Korean Peninsula, and southern Japan in June. ISM heating triggers Rossby wave propagation along the subtropical jet, promoting southerly winds over East Asia. The southerly winds helps steer anomalous mid-tropospheric warm advection and lower-tropospheric moisture advection toward East Asia, providing conditions preferential for rainband formation. Cluster analysis shows that, depending on jet structures, ISM heating can serve as a trigger as well as a reinforcer of the rainband.© 2023. Springer Nature Limited.
|
| [5] |
|
| [6] |
The costs of climate change are often estimated in monetary terms, but this raises ethical issues. Here we express them in terms of numbers of people left outside the ‘human climate niche’—defined as the historically highly conserved distribution of relative human population density with respect to mean annual temperature. We show that climate change has already put ~9% of people (>600 million) outside this niche. By end-of-century (2080–2100), current policies leading to around 2.7 °C global warming could leave one-third (22–39%) of people outside the niche. Reducing global warming from 2.7 to 1.5 °C results in a ~5-fold decrease in the population exposed to unprecedented heat (mean annual temperature ≥29 °C). The lifetime emissions of ~3.5 global average citizens today (or ~1.2 average US citizens) expose one future person to unprecedented heat by end-of-century. That person comes from a place where emissions today are around half of the global average. These results highlight the need for more decisive policy action to limit the human costs and inequities of climate change.
|
| [7] |
IPCC. Summary for policymakers[R]//Climate Change 2021:The physical science basis. Contribution of working group I to the sixth assessment report of the Intergovernmental Panel on Climate Change. Cambridge: Cambridge University Press, 2021: 3-32.
|
| [8] |
The Madden–Julian oscillation (MJO) identified by Madden and Julian in the early 1970s has been well recognized as the most prominent intraseasonal signal in the tropics. Its discovery and its relationship with other weather phenomena such as tropical cyclones (TCs) are among the most significant advancements in modern meteorology with broad and far-reaching impacts. The original study by Madden and Julian used radiosonde data on Canton Island, and their spectral analysis revealed the signal of a 40–50-day oscillation.
|
| [9] |
|
| [10] |
\n The climate has been warming since the industrial revolution, but how warm is climate now compared with the rest of the Holocene?\n \n Marcott\n et al.\n \n (p.\n 1198\n ) constructed a record of global mean surface temperature for more than the last 11,000 years, using a variety of land- and marine-based proxy data from all around the world. The pattern of temperatures shows a rise as the world emerged from the last deglaciation, warm conditions until the middle of the Holocene, and a cooling trend over the next 5000 years that culminated around 200 years ago in the Little Ice Age. Temperatures have risen steadily since then, leaving us now with a global temperature higher than those during 90% of the entire Holocene.\n
|
| [11] |
The Asian monsoon (AM) played an important role in the dynastic history of China, yet it remains unknown whether AM-mediated shifts in Chinese societies affect earth surface processes to the point of exceeding natural variability. Here, we present a dust storm intensity record dating back to the first unified dynasty of China (the Qin Dynasty, 221-207 B.C.E.). Marked increases in dust storm activity coincided with unified dynasties with large populations during strong AM periods. By contrast, reduced dust storm activity corresponded to decreased population sizes and periods of civil unrest, which was co-eval with a weakened AM. The strengthened AM may have facilitated the development of Chinese civilizations, destabilizing the topsoil and thereby increasing the dust storm frequency. Beginning at least 2000 years ago, human activities might have started to overtake natural climatic variability as the dominant controls of dust storm activity in eastern China.
|
| [12] |
周爱锋, 孙惠玲, 陈发虎, 等. 黄土高原六盘山天池记录的中晚全新世高分辨率气候变化及其意义[J]. 科学通报, 2010, 55(22):2264-2267.
|
| [13] |
|
| [14] |
An extensive new multi-proxy database of paleo-temperature time series (Temperature 12k) enables a more robust analysis of global mean surface temperature (GMST) and associated uncertainties than was previously available. We applied five different statistical methods to reconstruct the GMST of the past 12,000 years (Holocene). Each method used different approaches to averaging the globally distributed time series and to characterizing various sources of uncertainty, including proxy temperature, chronology and methodological choices. The results were aggregated to generate a multi-method ensemble of plausible GMST and latitudinal-zone temperature reconstructions with a realistic range of uncertainties. The warmest 200-year-long interval took place around 6500 years ago when GMST was 0.7 °C (0.3, 1.8) warmer than the 19th Century (median, 5th, 95th percentiles). Following the Holocene global thermal maximum, GMST cooled at an average rate −0.08 °C per 1000 years (−0.24, −0.05). The multi-method ensembles and the code used to generate them highlight the utility of the Temperature 12k database, and they are now available for future use by studies aimed at understanding Holocene evolution of the Earth system.
|
| [15] |
|
| [16] |
|
| [17] |
. By coordinating the design and distribution of global climate model simulations of the past, current, and future climate, the Coupled Model Intercomparison Project (CMIP) has become one of the foundational elements of climate science. However, the need to address an ever-expanding range of scientific questions arising from more and more research communities has made it necessary to revise the organization of CMIP. After a long and wide community consultation, a new and more federated structure has been put in place. It consists of three major elements: (1) a handful of common experiments, the DECK (Diagnostic, Evaluation and Characterization of Klima) and CMIP historical simulations (1850–near present) that will maintain continuity and help document basic characteristics of models across different phases of CMIP; (2) common standards, coordination, infrastructure, and documentation that will facilitate the distribution of model outputs and the characterization of the model ensemble; and (3) an ensemble of CMIP-Endorsed Model Intercomparison Projects (MIPs) that will be specific to a particular phase of CMIP (now CMIP6) and that will build on the DECK and CMIP historical simulations to address a large range of specific questions and fill the scientific gaps of the previous CMIP phases. The DECK and CMIP historical simulations, together with the use of CMIP data standards, will be the entry cards for models participating in CMIP. Participation in CMIP6-Endorsed MIPs by individual modelling groups will be at their own discretion and will depend on their scientific interests and priorities. With the Grand Science Challenges of the World Climate Research Programme (WCRP) as its scientific backdrop, CMIP6 will address three broad questions: – How does the Earth system respond to forcing? – What are the origins and consequences of systematic model biases? – How can we assess future climate changes given internal climate variability, predictability, and uncertainties in scenarios? This CMIP6 overview paper presents the background and rationale for the new structure of CMIP, provides a detailed description of the DECK and CMIP6 historical simulations, and includes a brief introduction to the 21 CMIP6-Endorsed MIPs.
|
| [18] |
The performance of a new historical reanalysis, the NOAA–CIRES–DOE Twentieth Century Reanalysis version 3 (20CRv3), is evaluated via comparisons with other reanalyses and independent observations. This dataset provides global, 3-hourly estimates of the atmosphere from 1806 to 2015 by assimilating only surface pressure observations and prescribing sea surface temperature, sea ice concentration, and radiative forcings. Comparisons with independent observations, other reanalyses, and satellite products suggest that 20CRv3 can reliably produce atmospheric estimates on scales ranging from weather events to long-term climatic trends. Not only does 20CRv3 recreate a “best estimate” of the weather, including extreme events, it also provides an estimate of its confidence through the use of an ensemble. Surface pressure statistics suggest that these confidence estimates are reliable. Comparisons with independent upper-air observations in the Northern Hemisphere demonstrate that 20CRv3 has skill throughout the twentieth century. Upper-air fields from 20CRv3 in the late twentieth century and early twenty-first century correlate well with full-input reanalyses, and the correlation is predicted by the confidence fields from 20CRv3. The skill of analyzed 500-hPa geopotential heights from 20CRv3 for 1979–2015 is comparable to that of modern operational 3–4-day forecasts. Finally, 20CRv3 performs well on climate time scales. Long time series and multidecadal averages of mass, circulation, and precipitation fields agree well with modern reanalyses and station- and satellite-based products. 20CRv3 is also able to capture trends in tropospheric-layer temperatures that correlate well with independent products in the twentieth century, placing recent trends in a longer historical context.
|
| [19] |
|
| [20] |
|
| [21] |
. Two interglacial epochs are included in the suite of Paleoclimate Modeling Intercomparison Project (PMIP4) simulations in the Coupled Model Intercomparison Project (CMIP6). The experimental protocols for simulations of the mid-Holocene (midHolocene, 6000 years before present) and the Last Interglacial (lig127k, 127 000 years before present) are described here. These equilibrium simulations are designed to examine the impact of changes in orbital forcing at times when atmospheric greenhouse gas levels were similar to those of the preindustrial period and the continental configurations were almost identical to modern ones. These simulations test our understanding of the interplay between radiative forcing and atmospheric circulation, and the connections among large-scale and regional climate changes giving rise to phenomena such as land–sea contrast and high-latitude amplification in temperature changes, and responses of the monsoons, as compared to today. They also provide an opportunity, through carefully designed additional sensitivity experiments, to quantify the strength of atmosphere, ocean, cryosphere, and land-surface feedbacks. Sensitivity experiments are proposed to investigate the role of freshwater forcing in triggering abrupt climate changes within interglacial epochs. These feedback experiments naturally lead to a focus on climate evolution during interglacial periods, which will be examined through transient experiments. Analyses of the sensitivity simulations will also focus on interactions between extratropical and tropical circulation, and the relationship between changes in mean climate state and climate variability on annual to multi-decadal timescales. The comparative abundance of paleoenvironmental data and of quantitative climate reconstructions for the Holocene and Last Interglacial make these two epochs ideal candidates for systematic evaluation of model performance, and such comparisons will shed new light on the importance of external feedbacks (e.g., vegetation, dust) and the ability of state-of-the-art models to simulate climate changes realistically.
|
| [22] |
|
| [23] |
|
| [24] |
The East Asian summer monsoon (EASM) intensified during the early to mid-Holocene relative to the present primarily due to orbital forcing. However, on the regional scale, changes in the monsoonal precipitation exhibit considerable spatial disparity, and the underlying mechanisms remain unresolved. In this study, the dynamic processes responsible for the difference of the EASM precipitation between the mid-Holocene and preindustrial period are systematically examined using the CMIP5 multimodel simulations. The moisture budget diagnostic identifies vertical motion as the key factor determining the cross-like precipitation pattern in East Asia. Relative to the preindustrial period, the mid-Holocene anomalous ascending motion corresponds well with the excessive precipitation over northern and southern China, and vice versa for west-central China, the Korean peninsula, Japan, and its marginal seas. In the framework of the moist static energy budget, the increased insolation and the attendant intensification of land–sea thermal contrast give rise to anomalous ascending motions, while descending motions are fundamentally forced by the decreased latitudinal insolation gradient. In particular, thermodynamic changes, namely, the reduced pole–equator temperature and humidity gradients, account for the downward motions over the northwestern Pacific. Dynamic changes, namely, the weakened westerlies, play a leading role in suppressing updrafts in west-central China. This study highlights that the orbital-scale monsoonal precipitation changes are not solely determined by local radiative forcing as repeatedly emphasized before. The latitudinal uneven distribution of insolation is crucial to explain the spatial inhomogeneity in the EASM precipitation changes during the Holocene.
|
| [25] |
田芝平, 张冉, 姜大膀. 全新世中期中国气候和东亚季风: PMIP4模式结果[J]. 地学前缘, 2022, 29(5):355-371.
利用国际古气候模拟比较计划(PMIP)最新第四阶段(PMIP4)中14个气候模式的试验数据,集中研究了距今约6 000年的全新世中期中国气候和东亚季风。与早期PMIP第三阶段(PMIP3)多模式结果类似,全新世中期中国年、冬季和春季地表气温较工业革命前期偏冷,而夏季和秋季偏暖,其中年和冬季模拟偏冷与大部分地质记录显示的偏暖不符;所有14个PMIP4模式集合的中国区域平均年和季节温度变化绝对值为0.08~1.69 ℃,较PMIP3多模式平均结果额外偏小0.01~0.45 ℃,这部分源于大气二氧化碳浓度的减少。在用于分析的11个PMIP4模式平均结果中,全新世中期中国年平均降水、蒸发和有效降水(即降水量减蒸发量)相对于工业革命前期分别增加2%、减少1%和增加7%,所有3个物理量在季节上均表现为冬春季减少,夏秋季增加。对比PMIP4模式和PMIP3多模式平均结果,上述3个物理量的中国区域平均值和区域变化差异均在夏、秋季大于年和冬、春季;相比于PMIP3模式,PMIP4模式模拟的年有效降水变化与地质记录更为接近。全新世中期东亚冬、夏季风在14个PMIP4模式中均模拟加强,所有模式平均较工业革命前期分别增强11%和32%;在区域尺度上,与早期PMIP3模式相比,当前PMIP4模式模拟的季风环流增强幅度在东亚北部更强,南部偏弱。
We revisited the climate in China and the East Asian monsoon during the mid-Holocene (6,000 years ago) via PMIP4 (Paleoclimate Modeling Intercomparison Project phase 4) simulation using 14 climate models. Similar to the previous simulation results using PMIP3 models, the mid-Holocene surface air temperatures were cooler for the annual (-0.61 ℃), winter (-1.65 ℃) and spring (-1.69 ℃) means and warmer for the summer (+0.80 ℃) and autumn (+0.08 ℃) means compared to the preindustrial period. The annual and winter cooling results run contrary to the warming results as inferred from most geological records. There was an extra cooling of 0.01-0.45 ℃ over the PMIP3 results, partly due to a reduction in the atmospheric carbon dioxide concentration. By PMIP4 simulation using 11 climate models, the mid-Holocene annual precipitation increased by 2%, evaporation decreased by 1%, and net precipitation (i.e., precipitation minus evaporation) increased by 7% relative to their preindustrial levels in terms of arithmetic means; seasonally, all three variables decreased for winter and spring and increased for summer and autumn. Comparatively, between PMIP4 and PMIP3 models for the above three variables, the differences in their national means and regional changes were relatively larger for summer and autumn than for the year and the other two seasons. And compared to the PMIP3 model results, the annual net precipitation change by PMIP4 simulation is closer to geological records. All 14 PMIP4 models reproduced a consistent strengthening of the East Asian winter and summer monsoon intensities during the mid-Holocene by 11% and 32% on average, respectively, compared to the preindustrial period. Regionally, the increases in monsoon circulation by PMIP4 simulation were larger in the north and smaller in the south of East Asia relative to the increases by PMIP3 simulation. |
| [26] |
The El Niño-Southern Oscillation (ENSO) used to affect the Asian summer monsoon (ASM) and Australian summer monsoon (AusSM) precipitation in different ways but global warming may have changed it. This study built robust annual ASM (AusSM) precipitation reconstructions during 1588–2013 (1588–1999) to examine the ENSO-monsoon relationship and how it has changed. During the period of 1588–1850 when natural climate variability was dominant, the ENSO-monsoon and inter-monsoon relationship was weak and non-stationary. Since 1850, however, both the inter-monsoon and ENSO-monsoon relationships saw an enhancement and this trend has been persistent to the present day, suggesting the influence of anthropogenic climate warming. Further analysis of climate model projections found that global warming can strengthen the ENSO-monsoon association that, subsequently, acts to synchronize the ASM and AusSM variations.
|
| [27] |
|
| [28] |
|
| [29] |
The large-scale Asian summer monsoon circulation has experienced a weakening tendency in recent decades. Using observed data and output from model experiments with the atmospheric component of the NCEP Climate Forecast System, the authors show that a relatively smaller warming in Asia compared to the surrounding regions may be a plausible reason for this change in the monsoon. Although the surface temperature over Asia has increased, the landmass has become a relative “heat sink” because of the larger warming in other regions of the world. Indeed, over Asia, the vertically integrated tropospheric temperature in the most recent decades is colder than that in the earlier decades, a feature different from the characteristics outside Asia.
|
| [30] |
|
| [31] |
. The South Asian and East Asian summer monsoons are globally significant meteorological features, creating a strongly seasonal pattern of precipitation, with the majority of the annual precipitation falling between June and September. The stability the monsoons is of extreme importance for a vast range of ecosystems and for the livelihoods of a large share of the world's population. Simulations are performed with an intermediate-complexity climate model in order to assess the future response of the South Asian and East Asian monsoons to changing concentrations of aerosols and greenhouse gases. The radiative forcing associated with absorbing aerosol loading consists of a mid-tropospheric warming and a compensating surface cooling, which is applied to India, Southeast Asia, and eastern China both concurrently and independently. The primary effect of increased absorbing aerosol loading is a decrease in summer precipitation in the vicinity of the applied forcing, although the regional responses vary significantly. The decrease in precipitation is not ascribable to a decrease in the precipitable water and instead derives from a reduction in the precipitation efficiency due to changes in the stratification of the atmosphere. When the absorbing aerosol loading is added in all regions simultaneously, precipitation in eastern China is most strongly affected, with a quite distinct transition to a low precipitation regime as the radiative forcing increases beyond 60 W m−2. The response is less abrupt as we move westward, with precipitation in southern India being least affected. By applying the absorbing aerosol loading to each region individually, we are able to explain the mechanism behind the lower sensitivity observed in India and attribute it to remote absorbing aerosol forcing applied over eastern China. Additionally, we note that the effect on precipitation is approximately linear with the forcing. The impact of doubling carbon dioxide levels is to increase precipitation over the region while simultaneously weakening the circulation. When the carbon dioxide and absorbing aerosol forcings are applied at the same time, the carbon dioxide forcing partially offsets the surface cooling and reduction in precipitation associated with the absorbing aerosol response. Assessing the relative contributions of greenhouse gases and aerosols is important for future climate scenarios, as changes in the concentrations of these species has the potential to impact monsoonal precipitation.
|
/
| 〈 |
|
〉 |