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New Record Ocean Temperatures and Related Climate Indicators in 2.2.

中国科学院地质与地球物理研究所2.08学术年会

作者： Z.T.Guo~1,B.Sun~(1,2.,Z.S.Zhang~(1,3),S.Z.Peng~1,G.Q.Xiao~4,J.Y.Ge~4,Q.Z.Hao~1,Y.S.Qiao~1,M.Y.Liang~1, J.F.Liu~1,Q.Z.Yin~1,and J.J.Wei~1 1 Key Laboratory of Cenozoic Geology and Environment,institute of Geology and Geophysics,{2. academy of sciences,P.O.Box 982.,beijing,10002.,China 2.Shandong institute and Laboratory of Geological sciences,Jinan,2.0013,China 3 nansen-zhu international {12. center,institute of atmospheric physics,{2. academy of sciences,beijing, 10002.,China 4 State Key Laboratory of Loess and Quaternary Geology,institute of Earth Environment,{2. academy of sciences,P.O. Box 17,Xian,710075,China

The global climate system experienced a series of drastic changes during the *** Asia,these include the climate transformation from a zonal pattern to a monsoon-dominated pattern,the disappearance of typical subtropical aridity,and the onset of inland *** major advances in the last two decades in characterizing and understanding these climate phenomena,disagreements persist relative to the timing,behaviors and underlying causes. This paper addresses these issues mainly based on two lines of ***,we compiled newly collected data from geological indicators of the Cenozoic environment in China as paleoenvironmental maps of ten *** confirming the earlier observation that a zonal climate pattern was transformed into a monsoonal one,the maps within the Miocene indicate that this change was achieved by the early Miocene,roughly consistent with the onset of loess deposition in *** a monsoon-like regime would have existed in the Eocene,it was restricted to tropical-subtropical *** latitudinal oscillations of the climate zones during the Paleogene are likely attributable to the imbalance in evolution of polar ice-sheets between the two hemispheres. Secondly,we examine the relevant depositional and soil forming processes of the Miocene loess-soil sequences to determine the circulation characteristics with emphasis on the early *** eolian deposition in the middle reaches of the Yellow River since the early Miocene firmly indicates the formation of inland deserts,which have been constantly maintained during the past 2. ***- size gradients between loess sections indicate northerly dust-carrying winds from northern sources,a clear indication of an Asian winter monsoon ***,welldeveloped Luvisols show evidence that moisture from the oceans reached northern *** evidence shows the coexistence of two kinds of circulations,one from the ocean carrying moisture and another from the inland des

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Advances in atmospheric {1. 2024年第6期41卷 1068-1082页

作者： Lijing CHENG John ABRAHAM Kevin E.TRENBERTH Tim BOYER Michael EMANN jiang {1. Fan {2. Fujiang YU Ricardo LOCARNINI John FASULLO Fei ZHENG Yuanlong LI Bin ZHANG Liying WAN Xingrong CHEN Dakui {2. Licheng FENG Xiangzhou SONG Yulong LIU Franco RESEGHETTI Simona SIMONCELLI Viktor GOURETSKI Gengxin CHEN Alexey MISHONOV Jim REAGAN Karina VON SCHUCKMANN Yuying PAN Zhetao TAN Yujing {1. {2.xu WEI Guancheng LI Qiuping REN Lijuan CAO Yayang LU international {1. for Climate and Environment {2. Institute of Atmospheric PhysicsChinese Academy of SciencesBeijing 100029China University of St.Thomas School of EngineeringMinnesota 55105USA NSF National center for {1. {2. BoulderColorado 80307USA University of Auckland Auckland 1010New Zealand National Oceanic and atmospheric Administration National Centers for Environmental InformationSilver SpringMaryland 20910USA Department of Earth and Environmental Science University of PennsylvaniaPhiladelphiaPennsylvania 19104USA institute of Oceanology Chinese Academy of SciencesQingdao 266071China National Marine Environmental Forecasting center Ministry of Natural Resources of ChinaBeijing 100081China Oceanographic Data center Chinese Academy of SciencesQingdao 266071China College of Oceanography Hohai UniversityNanjing 210098China National Marine Data and Information Service Tianjin 300171China Italian National Agency for New Technologies Energy and Sustainable Economic DevelopmentS.Teresa Research CenterLerici 19032Italy Istituto Nazionale di Geofisica e Vulcanologia Sede di BolognaBologna 40128Italy South China Sea institute of Oceanology Chinese Academy of SciencesGuangzhou 510301China ESSIC/CISESS-MD University of MarylandCollege ParkMD20740USA Mercator Ocean international Toulouse 31400France Eco-Environmental Monitoring and research {1. Pearl River Valley and South China Sea Ecology and Environment AdministrationMinistry of Ecology and EnvironmentPRCGuangzhou 510611China National Meteorological Information center China Meteorological AdministrationBeijing 100081China international {1. {2. of Big Data for Sustainable Development Goals Beijing 100094China

The global physical and biogeochemical environment has been substantially altered in response to increased atmospheric greenhouse gases from human *** 2.2.,the sea surface temperature(SST)and upper 2.00 m ocean heat content(OHC)reached record *** 0–2.00 m OHC in 2.2. exceeded that of 2.2. by 1.±1. ZJ(1.Zetta Joules=1.2.1}Joules)(updated IAP/CAS data);9±5 ZJ(NCEI/NOAA data).The Tropical Atlantic Ocean,the Mediterranean Sea,and southern oceans recorded their highest OHC observed since the *** with the onset of a strong El Niño,the global SST reached its record high in 2.2. with an annual mean of~0.2.℃ higher than 2.2. and an astounding>0.3℃ above 2.2. values for the second half of *** density stratification and spatial temperature inhomogeneity indexes reached their highest values in 2.2..

关键词： ocean heat content salinity stratification global warming climate

年际增量的预测方法在北大西洋飓风频次的季节预测(英文)

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年际增量的预测方法在北大西洋飓风频次的季节预测(英文)

Interdecadal changes in the frequency of winter extreme cold events in North China during 1.89–2.2.

第2.届中国气象学会年会

作者： Ke Fan1,2.1 nansen-zhu {2. {2. center,institute of atmospheric physics,chinese academy of sciences,beijing {12.,China 2.Key Laboratory of Regional Climate-Environment {2. for Temperate East Asia chinese academy of Science,beijing {12.,China

基于年际增量的预测方法发展高效的飓风季节（6月1.-1.月30日）内大西洋热带风暴（包括飓风）频次的预测模型。首先预测大西洋热带风暴频次的年际增量再预测大西洋热带风暴频次。通过以下两个途径考察年际增量预测方法的应用潜力:（1...

基于年际增量的预测方法发展高效的飓风季节（6月1.-1.月30日）内大西洋热带风暴（包括飓风）频次的预测模型。首先预测大西洋热带风暴频次的年际增量再预测大西洋热带风暴频次。通过以下两个途径考察年际增量预测方法的应用潜力:（1.将年际增量的预测方法分别与原始变量线性和非线性Poisson预测模型比较（图）;（2.与Gray等（2.09,2.1.）发展大西洋热带风暴频次的预测系统比较。研究表明,年际增量的方法及预测模型有较高的预测技巧。相对于大西洋热带风暴的气候预测平均的绝对误差4.1.在2.04-2.09年际增量的预测模型预测技巧提高了2.%,1.85-2.09的交叉检验的回报的预测技巧提高46%,高于同期Gray等（2.09,2.1.）的预测技巧。作者已基于年际增量的方法发展了有效的东亚夏季降水、气温,西太平洋台风频次和登陆气旋数的预测模型,此项工作表明它还可以应用到大西洋热带风暴（包括飓风频次）的季节预测中。

关键词： year-by-year increment Atlantic named tropical storm prediction model

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atmospheric and Oceanic Science Letters 2024年第4期17卷 1-7页

作者： Yali zhu Fangwu Song Dong Guo nansen‐{1. {2. {2. Centre Institute of Atmospheric PhysicsChinese Academy of SciencesBeijingChina Collaborative Innovation center on Forecast and Evaluation of Meteorological Disasters Nanjing University of Information Science and TechnologyNanjingChina Carbon Neutrality research {1. Institute of Atmospheric PhysicsChinese Academy of SciencesBeijingChina College of Earth and Planetary sciences University of Chinese Academy of SciencesBeijingChina

全球变暖背景下,极端天气气候事件的变化受到关注.本文研究发现, 1.89-2.2.0}期间,华北地区极端冷日数在2.03和2.1.年发生了年代际变化.极端冷日数先增加后减少. 2.03-2.1.年,西伯利亚-乌拉尔高压偏强,极地西风急流偏弱,有利于冷空气南... 详细信息

全球变暖背景下,极端天气气候事件的变化受到关注.本文研究发现, 1.89-2.2.0}期间,华北地区极端冷日数在2.03和2.1.年发生了年代际变化.极端冷日数先增加后减少. 2.03-2.1.年,西伯利亚-乌拉尔高压偏强,极地西风急流偏弱,有利于冷空气南下入侵华北地区,华北极端冷日数偏多.而在1.89-2.02.和2.1.-2.2.0},情况相反.虽然三个时段华北极端冷日的强度没有显著差异,但与其相联系的冷空气强度变得更强, 2.1.-2.2.0}冷空气中心区域往西北扩张到了贝加尔湖以西地区.

关键词：华北极端冷事件西伯利亚–乌拉尔高压北大西洋涛动极地急流东亚西风急流

Interdecadal changes in the western Siberian summer mean and extreme rainfall during 1.82.2.2.

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atmospheric and Oceanic Science Letters 2024年第3期17卷 37-41页

作者： Yali zhu Fangwu Song Dong Guo nansen-{1. {2. {2. Centre Institute of Atmospheric PhysicsChinese Academy of SciencesBeijingChina Collaborative Innovation center on Forecast and Evaluation of Meteorological Disasters Nanjing University of Information Science and TechnologyNanjingChina Carbon Neutrality research {1. Institute of Atmospheric PhysicsChinese Academy of SciencesBeijingChina College of Earth and Planetary sciences University of Chinese Academy of SciencesBeijingChina

本文研究发现,西西伯利亚夏季降水在1.95年后显著增加,2.1.年后又有所减少,极端降水日数和强度呈现一致的变化特征.伴随这两次降水的年代际增加/减少,西西伯利亚上空出现异常气旋/反气旋和水汽幅合/幅散.极端降水发生时的区域环流特征... 详细信息

本文研究发现,西西伯利亚夏季降水在1.95年后显著增加,2.1.年后又有所减少,极端降水日数和强度呈现一致的变化特征.伴随这两次降水的年代际增加/减少,西西伯利亚上空出现异常气旋/反气旋和水汽幅合/幅散.极端降水发生时的区域环流特征在三个时段基本一致:西西伯利亚低空出现气旋性异常,高空为西北-东南向的异常气旋-反气旋偶极子型.1.95-2.1.年期间,极端降水日数更多,强度更强,上述异常环流型也更强.

关键词：西伯利亚夏季降水年代际变化乌拉尔高压北大西洋波流相互作用

Mid-Pliocene Westerlies from Plio MIP Simulations

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Advances in atmospheric {1. 2015年第7期32卷 909-923页

作者： LI Xiangyu jiang {1. ZHANG Zhongshi ZHANG Ran TIAN Zhiping YAN Qing nansen–{1. {2. {2. Centre Institute of Atmospheric PhysicsChinese Academy of Sciences University of chinese academy of sciences CAS center for Excellence in Tibetan Plateau Earth {1. Climate Change research {1. Chinese Academy of Sciences Uni research Bjerknes Centre for Climate Research

The midlatitude westerlies are one of the major components of the global atmospheric circulation. They play an important role in midlatitude weather and climate, and are particularly significant in interpreting aeolian sediments. In this study, we analyzed the behavior and the possible mechanism involved in the change of the westerlies, mainly in terms of the jet stream position, in the mid-Pliocene warm period （3.3 to 3.0 million years ago） using simulations of 1. climate models from the Pliocene Model Intercomparison Project （PlioMIP）. Compared to the reference period, the mid-Pliocene midlatitude westerlies generally shifted poleward （approximately 3.6° of latitude in the Northern Hemisphere and 1.9~ of latitude in the Southern Hemisphere at 850 hPa level） with a dipole pattern. The dipole pattern of the tropospheric zonal wind anomalies was closely related to the change of the tropospheric meridional temperature gradient as a result of thermal structure adjustment. The poleward shift of the midlatitude westerly jet corresponded to the poleward shift of the mean meridional circulation. The sea surface temperatures and sea ice may have affected the simulated temperature structure and zonal winds, causing the spread of the westerly anomalies in the mid-Pliocene between the atmosphere-only and coupled atmosphere-ocean general circulation model simulations.

关键词： mid-Pliocene westerly climate model PlioMIP

Emerging contaminants:A One Health perspective

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The Innovation 2024年第4期5卷 140-170,139页

作者： Fang wang Leilei Xiang Kelvin Sze-Yin Leung Martin Elsner Ying Zhang Yuming Guo Bo Pan Hongwen Sun Taicheng An Guangguo Ying Bryan WBrooks Deyi Hou Damian EHelbling Jianqiang Sun Hao Qiu Timothy MVogel Wei Zhang Yanzheng Gao Myrna JSimpson Yi Luo Scott XChang Guanyong Su Bryan MWong Tzung-May Fu Dong {1. Karl JJobst Chengjun Ge Frederic Coulon Jean Damascene Harindintwali Xiankui Zeng Haijun wang Yuhao Fu Zhong Wei Rainer Lohmann Changer Chen Yang Song Concepcion Sanchez-Cid Yu wang Ali El-Naggar Yiming Yao Yanran Huang Japhet Cheuk-Fung Law Chenggang Gu Huizhong Shen Yanpeng Gao Chao Qin Hao Li Tong Zhang Natàlia Corcoll Min Liu Daniel SAlessi Hui Li Kristian KBrandt Yolanda Pico Cheng Gu Jianhua Guo Jianqiang Su Philippe Corvini Mao Ye Teresa Rocha-Santos Huan He Yi Yang Meiping Tong Weina Zhang Fidèle Suanon Ferdi Brahushi Zhenyu wang Syed AHashsham Marko Virta Qingbin Yuan Gaofei jiang Louis A.Tremblay Qingwei Bu Jichun Wu Willie Peijnenburg Edward Topp Xinde Cao Xin jiang Minghui Zheng Taolin Zhang Yongming Luo Lizhong {1. Xiangdong Li DamiàBarceló Jianmin Chen Baoshan Xing Wulf Amelung Zongwei Cai Ravi Naidu Qirong Shen Janusz Pawliszyn Yong-guan {1. Andreas Schaeffer Matthias C.Rillig Fengchang Wu Gang Yu James M.Tiedje State Key Laboratory of Soil and Sustainable Agriculture Institute of Soil ScienceChinese Academy of SciencesNanjing 210008China University of chinese academy of sciences Beijing 100049China Department of Chemistry Hong Kong Baptist UniversityHong KongChina HKBU institute of {1. and Continuing Education Shenzhen Virtual University ParkShenzhenChina Technical University of Munich TUM School of Natural SciencesInstitute of Hydrochemistry85748 GarchingGermany School of Resources&Environment Northeast Agricultural UniversityHarbin 150030China Climate Air Quality Research UnitSchool of Public Health and Preventive MedicineMonash UniversityMelbourneVICAustralia Faculty of Environmental Science&Engineering Kunming University of Science&TechnologyKunming 650500China Ministry of Education Key Laboratory of Pollution Processes and Environmental Criteria College of Environmental Science and EngineeringNankai UniversityTianjin 300350China Guangdong Key Laboratory of Environmental Catalysis and Health Risk Control School of Environmental Science and EngineeringInstitute of Environmental Health and Pollution ControlGuangdong University of TechnologyGuangzhou 510006China Ministry of Education Key Laboratory of Environmental Theoretical Chemistry South China Normal UniversityGuangzhouGuangdong 510006China Department of Environmental Science Baylor UniversityWacoTXUSA center for Reservoir and Aquatic Systems {1.(CRASR) Baylor UniversityWacoTXUSA School of Environment Tsinghua UniversityBeijing 100084China School of Civil and Environmental Engineering Cornell UniversityIthacaNY 14853USA Key Laboratory of Microbial Technology for Industrial Pollution Control of Zhejiang Province Zhejiang University of TechnologyHangzhou 310014China School of Environmental Science and Engineering Shanghai Jiao Tong UniversityShanghai 200240China Laboratoire d’Ecologie Microbienne Universite Claude Bernard Lyon 1UMR CNRS 5557UMR INRAE 1418VetAgro Sup69622 VilleurbanneFrance Department of Pla

Environmental pollution is escalating due to rapid global development that often prioritizes human needs over planetary *** global efforts to mitigate legacy pollutants,the continuous introduction of new substances remains a major threat to both people and the *** response,global initiatives are focusing on risk assessment and regulation of emerging contaminants,as demonstrated by the ongoing efforts to establish the UN’s Intergovernmental Science-Policy Panel on Chemicals,Waste,and Pollution *** review identifies the sources and impacts of emerging contaminants on planetary health,emphasizing the importance of adopting a One Health *** for monitoring and addressing these pollutants are discussed,underscoring the need for robust and socially equitable environmental policies at both regional and international *** actions are needed to transition toward sustainable pollution management practices to safeguard our planet for future generations.

关键词： pollution planet contaminants

Relationship between Solar Wind-Magnetosphere Energy and Eurasian Winter Cold Events

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Advances in atmospheric {1. 2020年第6期37卷 652-661页

作者： Xinping XU Shengping HE huijun {1. Collaborative Innovation center on Forecast and Evaluation of Meteorological Disasters/Key Laboratory of Meteorological Disaster Ministry of EducationNanjing University of Information Science and TechnologyNanjing 210044China Geophysical institute University of Bergen and Bjerknes Centre for Climate ResearchBergen 5007Norway nansen-{1. {2. {2. center Institute of Atmospheric PhysicsChinese Academy of SciencesBeijing 100029China Climate Change research {1. Chinese Academy of SciencesBeijing 100029China

The profound impact of solar irradiance variations on the decadal variability of Earth’s climate has been investigated by previous ***,it remains a challenge to quantify the energetic particle precipitation(EPP)influence on the surface climate,which is an emerging research *** solar wind is a source of magnetospheric EPP,and the total energy input from the solar wind into Earth’s magnetosphere(Ein)shows remarkable interdecadal and interannual variability.B ased on the new Ein index,this study reveals a significant interannual relationship between the annual mean Einand Eurasian cold extremes in the subsequent *** frequent cold events are observed over Eurasia(primarily north of 50°N)following the higher-than-normal Ein activity in the previous year,accompanied by more frequent cold events over northern Africa,and vice *** response pattern shows great resemblance to the first empirical orthogonal function of the variability of cold extremes over Eurasia,with a spatial correlation coefficient of *** pronounced intensification of the positive North Atlantic Oscillation events and poleward shift of the North Atlantic storm track associated with the anomalously higher Ein favor the anomalous extreme {1. circulation events,and thus less frequent extreme cold temperatures over northern Eurasia on the interannual time *** is further hypothesized that the wave-mean flow interaction in the stratosphere and troposphere is favorable for the connection of Ein signals to tropospheric circulation and climate in the following winter.

关键词： Eurasian interannual winter

Dominant Modes of Interannual Variability in atmospheric Water Vapor Content over East Asia during Winter and Their Associated Mechanisms

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Advances in atmospheric {1. 2021年第10期38卷 1706-1722页

作者： Wenyue HE Bo SUN huijun {1. nansen-{1. {2. {2. Centre Institute of Atmospheric PhysicsChinese Academy of SciencesBeijing 100029China University of chinese academy of sciences Beijing 100049China Collaborative Innovation center on Forecast and Evaluation of Meteorological Disasters/Key Laboratory of Meteorological Disaster Ministry of EducationNanjing University of Information Science and TechnologyNanjing 210044China Southern Marine Science and Engineering Guangdong Laboratory(zhuhai) Zhuhai 519080China

atmospheric water vapor content(WVC)is a critical factor for East Asian winter *** study investigates the dominant modes of interannual variability in WVC over East Asia during winter and their underlying *** on the empirical orthogonal function(EOF)method,the leading mode(EOF1.R2.2..9%)of the interannual variability in the East Asian winter WVC exhibits a meridional dipole pattern characterized by opposite WVC anomalies over northeastern China and eastern China;the second mode(EOF2.R2.2..3%)of the interannual variability in the East Asian winter WVC exhibits a monopole pattern characterized by consistent WVC anomalies over eastern ***1.is mainly modulated by two anomalous zonal water vapor transport(WVT)branches over northeastern China and eastern China,which are associated with an anomalous atmospheric wave train over Eurasia affected by sea ice cover in the Kara Sea-Barents Sea(SIC-KSBS)area in the preceding October-November(ON).EOF2.is mainly modulated by an anomalous westerly WVT branch over eastern China,which is associated with a circumglobal atmospheric zonal wave train in the Northern *** circumglobal zonal wave train is modulated by concurrent central and eastern tropical Pacific sea surface temperature *** SIC-KSBS anomalies in ON and the concurrent SST anomalies over tropical Pacific may partially account for the interannual variability of EOF1.and EOF2.winter WVC,and thus may provide a theoretical basis for improving the prediction of winter climate over East Asia.

关键词： interannual variability leading modes watervapor content East Asia