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南北极海区碳循环与全球变化研究 总被引:14,自引:1,他引:14
南北极是全球变化研究领域中十分重要的地区 ,也是世界大洋对全球变化反馈的一个重要窗口。文章论述了南北极海区碳循环研究的国内外研究动态 ,阐述了目前南大洋及北冰洋的生产力水平及碳收支平衡状态 ,讨论需要进一步研究的一些存在问题以及将来的发展方向。目前的研究表明 ,北极的生产力比历史上所认为的要高 ,在全球变化的作用下 ,其将成为越来越重要的碳汇区 ;南大洋主控着人为源CO2 的海气交换通量 ,而生产力所受到的限制也影响着其吸收CO2 的潜力。目前制约着对两极碳循环进一步认识所缺乏的资料包括 :极区碳汇的时空变异、南大洋的Fe限制及Fe假说、紫外增强对极区碳循环可能产生的影响等。今后研究的重点将集中在全球变化对两极碳循环的影响及其反馈 ,碳循环的机制及其动力学过程 ,以及通过碳循环人为干预全球变化的可行性。近年来 ,中国也十分重视极区碳循环的研究 ,取得了许多积极的成果。我们的研究结果表明 ,在 80°E~ 80°W之间 ,南大洋基本上是大气CO2 的汇 ,其中在 45°W~ 30°W及 10°W~ 10°E之间 ,是CO2 的强汇区。北冰洋的一些海区也表现为很强的碳汇区。计算得出 ,楚科奇海及其附近海区 7月到 9月CO2 吸收通量为 0 13g/ (m2 ·d) (碳 )。南大洋夏季CO2 吸收通量为 0 1g/ (m2 · 相似文献
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Marine carbon cycle of the South China Sea is an important part of global carbon cycle. Researches on the air-sea CO2 flux in the South China Sea will help us understand the global carbon cycle and improve the global carbon system parameter database. This paper concisely summarized the changes of partial pressure of CO2 (pCO2), air-sea CO2 fluxes (FCO2), and related environmental factors in four regions in domains in the South China Sea. The low-salinity area of the upper reaches of the Pearl River estuary in the northern of South China Sea shelf area acted as a strong source of atmospheric CO2, with high pCO2(405.3~810.6 Pa)all year round. The lower area of the Pearl River estuary (salinity > 33.7) acted as a weak sink of CO2 in winter, with relatively low pCO2 (35.2~37.0 Pa). The northern slope/basin in the South China Sea acted as a source of CO2 in warm seasons with a relatively high pCO2 (45.0 Pa), and acted as a sink of CO2 in cold seasons with a relatively low pCO2 (34.7 Pa). The west of the Luzon Strait acted as a sink of CO2 in spring, while it acted as a source of CO2 in other seasons, with relative high pCO2 (38.4~47.5 Pa) in winter. The central/southern basin in the South China Sea acted as sources of CO2, with relative high pCO2 (41.0 Pa) all the year. Generally, the estimation of annual sea-air CO2 fluxes showed that most domains in the South China Sea served as weak sources of atmospheric CO2. In the future, more researches should be focused on the time-series of sea surface pCO2 and the remote sensing of the sea-air CO2 fluxes. 相似文献
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未来百年全球气候变化的影响是当前学术界激烈争议的议题,深入探讨全球气候变化的驱动机理才能正确认识全球气候变化.持续生长的青藏高原吸收了巨量的CO2,导致大气中CO2浓度大幅下降,使地球从温室气候进入到以冰期、间冰期交替出现为特征的冰室气候,青藏高原成为新生碳储库.在间冰期,青藏高原和蒙古高原将淡水输送到中低纬度内陆区(... 相似文献
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In recent decades, humans have become a very important force in the Earth system, demonstrating that emissions (gaseous, liquid, and solid) are the cause of many of our environmental issues. These emissions are responsible for major global reorganizations of the biogeochemical cycles. The oceans are now a net sink of atmospheric CO2, whereas in their preindustrial state they were a source; the trophic state of the coastal oceans is progressively moving toward increased heterotrophy; and the terrestrial realm is now vacillating between trophic states, whereas in preindustrial times it was autotrophic. In this paper, we present model calculations that underscore the role of human-induced perturbations in changing Earth's climate, specifically the role of anthropogenic nitrogen and phosphorus in controlling processes in the global carbon cycle since the year 1850 with projections to the year 2035. Our studies show that since the late 1940's emissions of nitrogen and phosphorus have been sequestered in the terrestrial living phytomass and groundwater. This nutrient-enhanced fertilization of terrestrial biota, coupled with rising atmospheric CO2 and global temperature, has induced a sink of anthropogenic CO2 that roughly balances the emission of CO2 owing to land use change. In the year 2000, for example, the model-calculated terrestrial biotic sink was 1730 Mtons C/year, while the emission of CO2 from changes in land use was 1820 Mtons C/year, a net flux of 90 Mtons C/year emitted to the atmosphere. In the global aquatic environment, enhanced terrestrial inputs of biotically reactive phosphorus (about 8.5 Mtons P/year) and inorganic nitrogen (about 54 Mtons N/year), have induced increased new production and burial of organic carbon in marine sediments, which is a small sink of anthropogenic CO2. It is predicted that the response of the global land reservoirs of C, N, and P to sustained anthropogenic perturbations will be maintained in the same direction of change over the range of projected scenarios of global population increase and temperature change for the next 35 years. The magnitude of change is significantly larger when the global temperature increase is maximum, especially with respect to the processes of remobilization of the biotically important nutrients nitrogen and phosphorus. 相似文献
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The Antarctic and the Arctic regions play a key role in global sea level change and carbon cycle, and reserve key information of the Cenozoic transition from a green-house to an ice-house Earth. They have become hot spots in earth science studies. The geological drilling projects in both polar regions (e.g., DSDP/ODP/IODP/ICDP) have achieved remarkable successes, which have freshened the knowledge of global environmental and climatic evolution. Along with the Cenozoic global cooling, the timing of glaciation was almost synchronous on both the Antarctic and the Arctic. Accompanied with the Antarctic ice sheet build-up and increased terrestrial weathering, the enhanced formation of Antarctic Bottom Water exerts significant impact on global ocean circulation. The volume of unstable West Antarctic Ice Sheet fluctuates during glacial-interglacial periods showing 40 ka obliquity cycles, its volume significantly reduced or collapsed during several peak interglacials or long warm intervals. The Southern Ocean plays a significant role modulating atmospheric CO2 concentration, global deep water circulation and nutrient distribution, productivity at different time scales. Sea level responses to the waxing and waning of polar ice sheets at different time intervals were tested, which provide valuable clue for predicting future sea level changes. The upcoming IODP drilling projects on polar regions will keep focusing on the high latitude ice sheet development, Southern Ocean paleoceanographic evolution, land-ocean linkages in the Arctic, and the impacts on the global climate, which will provide important boundary conditions for predicting global future climate evolution. 相似文献
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Abuse of fossil energy resources results in the excessive discharge of greenhouse gases, especially CO2, enhancing the trend of global climate warming. Carbon sequestration is an important method to lower the increasing rate of CO2 concentration in the atmosphere. Marine carbon sequestration is a novel idea for reducing CO2 emission, and its reservoir mainly includes seawater and submarine sediment, which not only possess a great potential capacity of carbon sequestration, but also have high safety in relation to continental reservoirs. In this paper, we expounded the technique principle and mechanisms of marine carbon sequestration, potential capacity and time duration of marine carbon sequestration, main factors influencing marine carbon sequestration, CO2 injection technique, impacts on marine biota from over emission of CO2 and technique monitoring the leakage of CO2. Finally, a prospect of marine carbon sequestration was proposed, and its hot topics were accordingly pointed out. 相似文献
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2030年前实现碳达峰,2060年前实现碳中和是2020年我国提出的国家重大战略目标。以当前我国的二氧化碳排放及能源结构现状,要实现这一伟大目标形势十分严峻。介绍了全球碳循环过程,阐述了碳源与碳汇对于大气CO2浓度的贡献,从减源与增汇2个方面,初步分析了地质调查在推动碳达峰与碳中和目标实现中的作用与可能的贡献,并提出了地质解决路径。生态碳汇固然非常重要,但仍不能完全消除人为CO2排放,且其具有不确定性,因此,需要充分发挥地质调查作用、挖掘地质碳汇潜力,使其成为实现碳中和目标过程中不可或缺的有力支撑。 相似文献
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藏南碳酸岩脉成因及其气候效应 总被引:1,自引:0,他引:1
始新世末期以来,全球大气CO2浓度持续下降,但长期以来不清楚为何这一时期全球大气CO2浓度下降,巨量的大气CO2赋存于何处。深入研究该问题有助于准确理解未来大气CO2浓度变化的趋势,特别是有助于进一步评估人类自身碳排放的后果。这一时期,小印度陆块持续与大亚洲陆块汇聚,导致了以喜马拉雅为代表的山脉群和青藏高原的形成。很早就有学者从地球表层碳循环的角度提出了"青藏高原的隆升导致了全球变冷"的观点,但这一观点既没有解释清楚"巨量大气CO2到何处去"的问题,也没有讨论青藏高原本身向大气圈排放CO2等问题,因此该观点最近受到了强烈的质疑。这些激烈的争论充分反映了传统的地球表层碳循环研究已不能充分满足当前社会的需求。本文从深部碳循环这个视角重新探讨青藏高原在全球碳循环中的作用。在印度与亚洲陆块持续汇聚期间,以喜马拉雅为代表的巨型山脉快速崛起,然后持续遭受化学风化作用,大量消耗大气CO2。化学风化的产物堆积在喜马拉雅山前的前陆盆地内,形成了巨量含新生碳酸盐矿物和有机碳的西瓦里克沉积杂岩,随后新生的西瓦里克杂岩又随持续平板俯冲的印度陆壳被带入青藏高原内部,与平板俯冲的印度陆壳共同经历高温变质作用。俯冲板片内的(黑)云母等含水矿物发生脱水,形成花岗岩浆。花岗岩浆再与俯冲的西瓦里克杂岩内的碳酸盐岩发生交代反应,释放出含钙、镁离子、以CO2和水为主的高温流体,本文称其为壳源火成碳酸岩浆。碳酸岩浆沿张性裂隙上侵、冷凝之后形成藏南的碳酸岩脉。虽然青藏高原内部的火山、温泉等均向大气圈排放CO2,但所排放的碳均为再循环来自大气圈的碳,并且排放量略小于吸收量,否则消耗大气CO2所新生的碳酸岩脉就不会在青藏高原内部保存下来。藏南大量晚新生代碳酸岩脉的发现充分说明了喜马拉雅山脉和藏南高原是一个巨大的碳储库,在其形成过程中将巨量大气CO2转化为流体(岩浆)的形式封存于青藏高原内部,从而大幅降低了大气CO2浓度,最终导致了全球变冷。上述过程充分说明,大气CO2浓度的变化实质上是受控于地球内部的构造运动。进一步可推论出,"全球变化"只是一个自然现象,虽然它有独特的运行轨迹,但与人类的碳排放量无因果关系。 相似文献
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通过对中国第3次和第4次北极考察在白令海和西北冰洋采集的65个表层样沉积物中生物标记物四醚膜类脂物(GDGTs)的研究,发现西北冰洋表层沉积物中类异戊二烯和支链GDGTs的浓度分布大致以楚科奇海和波弗特海的陆坡为界线,呈现南高北低的特征,这一特征主要与水体生产力和陆源有机质的输入量有关.基于GDGTs的陆源输入指数BIT显示,从楚科奇海北部到高纬度区的阿尔法脊,陆源有机质的相对比例明显增加,与有机碳稳定同位素等结果一致,表明BIT可以用来指示北极陆源有机质输入量的变化.应用前人TEXL86-SST方程估算的研究区表面海水温度SST与现代年均SST和夏季平均SST的相关性较差,原因可能与陆源输入的类异戊二烯GDGTs干扰以及低的古菌生产力有关.从季节性海冰覆盖区到永久性海冰覆盖区,基于支链GDGTs的环化指数CBT明显升高,可能反映了CBT对海冰覆盖状况的响应,但其响应机制还不清楚.基于支链GDGTs的环化指数CBT和甲基化指数MBT估算的北极陆地年均大气温度和土壤pH差异较大,可能是由表层沉积物的来源复杂以及混合作用造成的. 相似文献
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人类巨量碳排放究竟导致什么后果,争议颇大,只有深入研究始新世以来大气CO2浓度与环境变化,才有可能正确认识未来人类自身巨量碳排放之后果。大量研究揭示出: 从始新世到渐新世末期,大气CO2浓度大幅下降,全球变冷,形成了大陆冰川; 中新世至今,大气CO2浓度在低浓度背景之下长周期缓慢下降。当前尚不清楚何种机制主导了这一变化过程,也不清楚形成大陆冰川的水来自何方。为此,从青藏高原深部碳循环、表层水循环和环境变化的角度探讨这些问题,再分析未来人类巨量碳排放之后果。青藏高原在生长、隆升过程中,通过硅酸岩化学风化、植物光合作用、陆内俯冲(深埋)、水岩反应等方式,持续将巨量大气CO2转化为富含碳元素的固、流体,封存在青藏高原新生的厚地壳之中,大幅降低了大气CO2浓度,导致了全球变冷、大陆内陆(含青藏高原,下同)表层失水变干,形成了大陆冰川。渐新世—中新世之交,青藏高原生长到改变大气环流的规模,形成了亚洲季风,大陆内陆进一步荒漠化,捕获CO2的量大幅下降,并与青藏高原内部所释放CO2的量达到了准动态平衡,这是中新世以来大气CO2浓度变化的主要机制。人类巨量碳排放彻底扭转了大气CO2浓度长周期缓慢下降的趋势,大陆冰川因全球变暖所形成的液态水不会长期停留在海洋里,而以大气降水的方式重新回到干冷的大陆内陆,青藏高原将因此再次成为巨型水塔,缓解30多亿人的清洁饮用水问题。持续生长的高原和当前干冷荒漠化的大陆内陆通过前述多种方式固化人类排放的巨量CO2,导致未来大气CO2浓度在较高浓度背景下保持稳定,届时沙漠变绿洲,黄土高原变成有机质丰富的黑土高原,人居环境大幅改善; 但在盆地内部,PM2.5难以扩散,易形成雾霾。全球平均海平面因海水热膨胀而缓慢上升,上升速率约为1 mm/a。水主要在大陆冰川与内陆表层之间循环,与海平面升降之间没有因果关系。因此,人类巨量碳排放所导致的全球变暖对于人类自身的发展是利大于弊。 相似文献
11.
Response and Feedback of Marine Carbon Sink to Climate Change 总被引:1,自引:0,他引:1
The response and feedback of ocean carbon sequestration to climate changes is a international hot topic and requires large spatial/temporal scale, collaborative and multi-disciplinary research. In the first conference of GRC Ocean biogeochemistry, scientists focus on three biologically-driven ocean carbon pumps (Biological Pump, BP; Microbial Carbon Pump, MCP; Carbonate Counter Pump, CCP) and their environmental and climate consequences. As a sister meeting in China, we organized the session to show the efforts and progress of ocean carbon sequestration of Chinese scientists. The microbial ecological processes of phytoplankton, bacteria, archaea and viruses and interactions between them were highlighted in the session. Use coral reefs in the South China Sea as an example, the presenters and the participants come to an agreement that interdisciplinary collaborations are needed to ensure a comprehensive understanding of the interactions between microbes and their geochemical environment and the consequences of microbial processing of carbon on outgassing of CO2 and carbon sequestration. The session also have presentations focusing on paleo-environmental reconstruction for carbon sinks as well as their paleo-ecological effects in ancient oceans with time spanning from the 1.8~0.8 Ga Proterozoic to the 2.5 Ma Quaternary. These talks provide specific geological cases for the oceanic carbon sink research and convey the emerging geological view of paleooceanic carbon sinks to the research community of modern ocean carbon sinks. As a summary, the discussion in this session of biological pump, microbial carbon pump and carbonate counter pump shows the latest research progress and future development trend in this field. 相似文献
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以岩溶湖泊——红枫湖的微藻为研究对象,通过添加两种标记稳定碳同位素组成的无机碳进行室内模拟岩溶环境条件;并通过添加不同浓度的乙酰唑胺(AZ),来模拟岩溶湖泊中碳酸酐酶胞外酶活性差异的各类微藻。重点监测微藻蛋白质含量及其稳定碳同位素组成变化等指标,计算其对不同来源无机碳的吸收利用份额,并结合微藻的生物量生长指标,最终计算出碳酸酐酶胞外酶活性差异的各种微藻的碳汇能力。结果显示:在岩溶湖泊的自然水体中,碳酸酐酶胞外酶活性强的微藻碳汇能力是缺乏碳酸酐酶胞外酶的微藻碳汇能力的5倍。碳酸酐酶胞外酶对微藻光合碳汇能力的影响显著。 相似文献
14.
目前约25%化石燃料来源的CO2被海洋吸收,缓解了人类活动对气候变化的影响。海洋通过多个概念的碳泵将大气中的CO2输送到深海。深海高压和低温的特点有利于CO2溶解,目前已经储存了相当于大气含量50倍的无机碳,另外,深海沉积物中还储存有大量甲烷水合物。认识深海中的碳循环过程,对于保护海洋固碳能力、开发固碳潜力有重要意义。总结了国内外在海洋碳库、碳输送研究方面的进展,重点讨论了深海C元素转化循环的过程以及高压对生命活动的影响。微生物驱动了深海碳循环,大部分浮游植物所包含的有机碳在沉降过程中被微生物矿化成CO2以及转化为难降解的有机碳,使深海成为巨大的、长周转时间的有机碳库; 高压能提高古菌甲烷厌氧氧化的活性,提升屏蔽海底甲烷释放的能力,同时,高压下氧化甲烷的过程中不仅产生碳酸氢盐,还产生可支持异养生物的乙酸,因此,全球甲烷厌氧氧化的通量可能被低估; 高压下细胞代谢额外产生的氨,可作为氨氧化古菌固定无机碳的潜在能量来源。总之,研究现在以及未来的人类活动对深海碳循环过程的影响以及环境效应,评估应用深海作为地球工程技术平台封存CO2的可能性,都迫切需要加深对碳循环在内的深海元素循环的认识。 相似文献
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大气 CO2浓度在控制全球气候变化方面具有至关重要的作用,研究碳循环、CO2收支平衡和精确评估是制定区域CO2减排策略和寻找新的碳汇途径最重要的组成部分。碳酸盐风化碳汇是全球碳循环研究的一个重要方向。为此,本研究以天津平原区浅层地下水为研究对象,通过对地下水调查及水样的采集与分析,运用水化学分析方法分析了地下水水化学特征,并估算了地下水总储存量、DIC储量和碳酸盐风化碳汇量。研究结果表明:浅层地下水化学场自北部山前平原向南部冲积平原和滨海平原,呈现出自北而南和由北西向南东的水平水化学分带规律,地下水由低浓度的淡水、微咸水变为高浓度咸水,沿此方向水化学类型由HCO3-Ca·Na·Mg→Cl·SO4-Na→Cl·HCO3-Na→Cl-Na型转变;淡水区、微咸水区和咸水区面积分别为733、3 034和6 564 km2。地下水水化学组分中Ca2+、Mg2+和 主要来源于碳酸盐的溶解作用。研究区浅层地下水总储存量为2 241 640万m3,总DIC储量为8.13×106 t,总碳汇量为4.11×106 t。研究区浅层地下水淡水区、微咸水区和咸水区地下水储存量分别为157 799万、6 245 936万和1 459 247万 m3,DIC浓度分别为19200、19200和19342 mg/L,DIC储量分别为0.67×106、1.65×106和0.58×106 t,碳汇量分别为0.22×106、0.90×106和2.98×106 t。沿地下水流向,DIC、储量和碳汇量的空间分布均呈现出由低到高的趋势。 相似文献
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人为排放CO2导致全球气候变暖已经对人类生存和发展造成威胁,碳捕获与封存是世界公认的实现碳减排的主要途径之一。基性-超基性岩碳酸盐化固碳作为地质碳汇之一,是一种经济、安全且长久的碳捕获与封存方式,引起了国际社会越来越多的重视。本文阐述了自然条件下基性-超基性岩碳酸盐化反应过程,分析其固碳机理和影响基性-超基性岩碳酸盐化速率的主要因素。在此基础上,梳理并总结了目前国际上基性-超基性岩固碳技术的研究进展和典型应用实例,认为全球广泛分布的基性-超基性岩具有巨大的固碳潜力。该技术的推广和应用将对未来大气CO2减排具有重要意义。 相似文献
17.
由于海冰覆盖,北极碳汇(Arctic Carbon Sink)在全球碳通量预算中经常被忽略或简单处理。但随着全球变化加剧,北极发生快速变化,北极碳循环及其对全球变化的响应与反馈日趋重要。综合对北极碳汇的研究结果,分析了北极碳汇的来源、变化以及主要调控因子,评估了北极碳汇现状。探讨了在全球变化中,影响北极碳汇变化的因素及其对未来北极碳汇变化趋势的影响。
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18.
简要介绍了千年生态系统评估(MA)项目亚全球评估工作组的报告《生态系统与人类福祉:多尺度评估》的核心内容,重点在于多尺度评估的贡献以及从中获取的经验教训。多尺度评估的贡献主要表现在:① 全面、系统地阐述了生态系统服务与人类福祉在多种尺度上的重要联系;② 从多种尺度上揭示了生态系统服务的状况与变化趋势;③ 制定提高人类福祉和保护生态系统服务的有效对策,需要考虑不同尺度上的驱动力和利益相关方的参与;④ 当地社区对生态系统服务的变化具有积极的适应与管理能力。此外,在对全球评估的概念框架的修改、对开展多尺度评估的利弊分析、多尺度评估需要克服的限制因素以及今后需要权衡与考虑的问题等方面,MA的多尺度评估也提供了宝贵的经验教训。
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19.
The Southern Ocean is a strong sink for atmospheric CO2, making it especially vulnerable to ocean acidification (OA). The aragonite saturation state (Ωarg) of seawater has been used as an index for the estimation of OA, which plays a critical role in evaluating the living environment of marine calcified organisms. However, it is very difficult to perform the studies of OA and Ωarg in the Southern Ocean due to its harsh climate. Therefore, in order to better understand the OA and its further influences, the advances of Ωarg studies were summarized in the oceans surrounding the Antarctica. Significant spatial and temporal variations of surface seawater Ωarg are demonstrated in the Southern Ocean. In general, the surface seawater Ωarg shows a lower value in the off-shore areas than in the open oceans. And, Ωarg also exhibits a strong seasonal cycle with a higher value in summer than in winter. The distributions of Ωarg in vertical water column generally present a declining tendency from surface to bottom. In addition, the shoaling of Ωarg horizon at high latitude could be attributed to the ventilation and upwelling of deep waters in the Southern Ocean. There are many factors that could impact the Ωarg in the Southern Ocean, including sea ice melting, sea-air CO2 exchange, biological activities and hydrological processes, etc. Finally, the future changes and key scientific problems of OA in the Southern Ocean are proposed. 相似文献
20.
Aiming at the current climate status, i.e., drastic rise of atmospheric greenhouse gases and the apparent trend of global warming, the International Ocean Discovery Program (IODP), launched in 2013, proposed four scientific challenges, including the response of global climate to CO2 rise, the feedback of ice-sheet and sea-level to global warming, the dynamics of the mid- and low-latitude hydro-cycle, and the mechanism of the marine carbon-chemical buffering system. By August 2017, eight IODP expeditions of climate-related themes were implemented, focusing on the Neogene evolution of the monsoon system over Asia-Pacific-Indian and the West Pacific Warm Pool, with specific interests in the variabilities and mechanisms of the Asian Monsoon system on orbital-to millennial-scales, as well as the connections between Asian Monsoon and the uplift/weathering of the Tibetan Plateau on tectonic time scale. The planned IODP expeditions in the forthcoming two years will explore the Southern high-latitude climate histories of West Antarctic ice in the Cenozoic, and Southern Ocean currents and carbon cycle in the Cretaceous-Paleogene. In sum, during the current phase of IODP (2013-2023), our knowledge about the marine climate system would be greatly advanced via deciphering the past changes in tropical processes of Asian Monsoon and West Pacific Warm Pool, as well as in high-latitude factors of the West Antarctic ice. A better scientific background of natural variability would be provided, accordingly, for predicting the future tendency in climate change. In this context, China’s strategic directions include the global monsoon concept, the tropical forcing hypothesis, and in particular the climate effect of the Sunda Shelf. 相似文献