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竺可桢-南森国际研究中心
邮 箱:nzc_iap@mail.iap.ac.cn
邮 编:100029
地 址:北京市朝阳区德胜门外祁家豁子华严里40号 竺南中心
关于我们
About Our Centre姜大膀 (Jiang Dabang).研究员/Professor
姓 名:姜大膀
职 务:
职 称:研究员
研究方向:古今气候变化
进所时间:2000-09-01
教育:
1993–2000年:兰州大学大气科学系学习,获天气动力学专业学士、气象学专业硕士学位
2000–2003年:中国科学院大气物理研究所,获气象学专业博士学位
研究经历:
2003年至今在中国科学院大气物理研究所从事科研工作,2006年起任副研究员,2010年起任研究员,2016年起任研究员二级;2015年起受聘中国科学院首批特聘研究员、中国科学院大学岗位教授。曾两次赴挪威南森环境与遥感中心进行共为期半年的工作访问,曾在德国马普生物地球化学研究所做博士后两年。
论文250余篇,其中SCI期刊论文180余篇(*为通讯作者),主要论文有:
(1) Jiang*, D., H.-J. Wang, H. Drange, and X. Lang, Last glacial maximum over China: Sensitivities of climate to paleovegetation and Tibetan ice sheet, Journal of Geophysical Research, 2003, 108(D3), 4102, doi: 10.1029/2002JD002167.
(2) Jiang*, D., and H.-J. Wang, Natural interdecadal weakening of East Asian summer monsoon in the late 20th century, Chinese Science Bulletin, 2005, 50, 1923−1929.
(3) Jiang*, D., H.-J. Wang, and X. Lang, Evaluation of East Asian climatology as simulated by seven coupled models, Advances in Atmospheric Sciences, 2005, 22, 479−495.
(4) Jiang*, D., H.-J. Wang, Z. L. Ding, X. Lang, and H. Drange, Modeling the middle Pliocene climate with a global atmospheric general circulation model, Journal of Geophysical Research, 2005, 110, D14107, doi: 10.1029/2004JD005639.
(5) Jiang*, D., and Z. Zhang, Paleoclimate modelling at the Institute of Atmospheric Physics, Chinese Academy of Sciences, Advances in Atmospheric Sciences, 2006, 23, 1040−1049.
(6) Jiang*, D., Projected potential vegetation change in China under the SRES A2 and B2 scenarios, Advances in Atmospheric Sciences, 2008, 25, 126−138.
(7) Jiang*, D., Z. L. Ding, H. Drange, and Y. Gao, Sensitivity of East Asian climate to the progressive uplift and expansion of the Tibetan Plateau under the mid-Pliocene boundary conditions, Advances in Atmospheric Sciences, 2008, 25, 709−722.
(8) Jiang*, D., Vegetation and soil feedbacks at the last glacial maximum, Palaeogeography, Palaeoclimatology, Palaeoecology, 2008, 268, 39−46.
(9) Jiang*, D., Y. Zhang, and J. Sun, Ensemble projection of 1–3°C warming in China, Chinese Science Bulletin, 2009, 54, 3326−3334.
(10) Jiang*, D., and X. Lang, Last glacial maximum East Asian monsoon: Results of PMIP simulations, Journal of Climate, 2010, 23, 5030−5038.
(11) Jiang*, D., X. Lang, Z. Tian, and D. Guo, Last glacial maximum climate over China from PMIP simulations, Palaeogeography, Palaeoclimatology, Palaeoecology, 2011, 309, 347−357.
(12) Jiang*, D., Y. Zhang, and X. Lang, Vegetation feedback under future global warming, Theoretical and Applied Climatology, 2011, 106, 211−227.
(13) Jiang*, D., X. Lang, Z. Tian, and T. Wang, Considerable model–data mismatch in temperature over China during the mid-Holocene: Results of PMIP simulations, Journal of Climate, 2012, 25, 4135−4153.
(14) Jiang*, D., Z. Tian, and X. Lang, Mid-Holocene net precipitation changes over China: Model–data comparison, Quaternary Science Reviews, 2013, 82, 104−120.
(15) Jiang*, D., X. Lang, Z. Tian, and L. Ju, Mid-Holocene East Asian summer monsoon strengthening: Insights from Paleoclimate Modeling Intercomparison Project (PMIP) simulations, Palaeogeography, Palaeoclimatology, Palaeoecology, 2013, 369, 422−429.
(16) Jiang*, D., and Z. Tian, East Asian monsoon change for the 21st century: Results of CMIP3 and CMIP5 models, Chinese Science Bulletin, 2013, 58, 1427−1435.
(17) Sui, Y., X. Lang, and D. Jiang*, Time of emergence of climate signals over China under the RCP4.5 scenario, Climatic Change, 2014, 125, 265−276.
(18) Jiang*, D., G. Yu, P. Zhao, X. Chen, J. Liu, X. Liu, S. Wang, Z. Zhang, Y. Yu, Y. Li, L. Jin, Y. Xu, L. Ju, T. Zhou, and X. Yan, Paleoclimate modeling in China: A review, Advances in Atmospheric Sciences, 2015, 32, 250−275.
(19) Jiang*, D., Z. Tian, and X. Lang, Mid-Holocene global monsoon area and precipitation from PMIP simulations, Climate Dynamics, 2015, 44, 2493−2512.
(20) Jiang*, D, Z. Tian, X. Lang, M. Kageyama, and G. Ramstein, The concept of global monsoon applied to the last glacial maximum: A multi-model analysis, Quaternary Science Reviews, 2015, 126, 126−139.
(21) Li, X., D. Jiang*, Z. Zhang, R. Zhang, Z. Tian, and Q. Yan, Mid-Pliocene westerlies from PlioMIP simulations, Advances in Atmospheric Sciences, 2015, 32, 909−923.
(22) Sui, Y., X. Lang, and D. Jiang*, Temperature and precipitation signals over China with a 2 °C global warming, Climate Research, 2015, 64, 227−242.
(23) Jiang*, D., Z. Tian, and X. Lang, Reliability of climate models for China through the IPCC Third to Fifth Assessment Reports, International Journal of Climatology, 2016, 36, 1114−1133.
(24) Jiang*, D, Y. Sui, and X. Lang, Timing and associated climate change of a 2°C global warming, International Journal of Climatology, 2016, 36, 4512−4522.
(25) Liu, Y., and D. Jiang*, Mid-Holocene permafrost: Results from CMIP5 simulations, Journal of Geophysical Research: Atmospheres, 2016, 121, 221−240.
(26) Liu, Y., and D. Jiang*, Last glacial maximum permafrost in China from CMIP5 simulations, Palaeogeography, Palaeoclimatology, Palaeoecology, 2016, 447, 12−21.
(27) Wang, X., D. Jiang*, and X. Lang, Future extreme climate changes linked to global warming intensity, Science Bulletin, 2017, 62, 1673−1680.
(28) Yang, K., and D. Jiang*, Interannual climate variability change during the medieval climate anomaly and little ice age in the PMIP3 last millennium simulations, Advances in Atmospheric Sciences, 2017, 34, 497−508.
(29) Hu, Q., D. Jiang*, X. Lang, Sources of moisture for different intensities of summer rainfall over the Chinese Loess Plateau during 1979–2009, International Journal of Climatology, 2018, 38, e1280−e1287.
(30) Hu, Q., D. Jiang*, X. Lang, and B. Xu, Moisture sources of the Chinese Loess Plateau during 1979–2009, Palaeogeography, Palaeoclimatology, Palaeoecology, 2018, 509, 156−163.
(31) Jiang*, D., Y. Sui, X. Lang, and Z. Tian, Last glacial maximum and mid-Holocene thermal growing season simulations, Journal of Geophysical Research: Atmospheres, 2018, 123, 11466−11478.
(32) Li, X., D. Jiang*, Z. Tian, and Y. Yang, Mid-Pliocene global land monsoon from PlioMIP1 simulations, Palaeogeography, Palaeoclimatology, Palaeoecology, 2018, 512, 56−70.
(33) Liu, S., D. Jiang*, and X. Lang, A multi-model analysis of moisture changes during the last glacial maximum, Quaternary Science Reviews, 2018, 191, 363−377.
(34) Liu, Y., and D. Jiang*, Mid-Holocene frozen ground in China from PMIP3 simulations, Boreas, 2018, 47, 498−509.
(35) Su, B., D. Jiang*, R. Zhang, P. Sepulchre, and G. Ramstein, Difference between the North Atlantic and Pacific meridional overturning circulation in response to the uplift of the Tibetan Plateau, Climate of the Past, 2018, 14, 751−762.
(36) Sui, Y., X. Lang, and D. Jiang*, Projected signals in climate extremes over China associated with a 2°C global warming under two RCP scenarios, International Journal of Climatology, 2018, 38, e678−e697.
(37) Wang, N., D. Jiang*, and X. Lang, Northern westerlies during the last glacial maximum: Results from CMIP5 simulations, Journal of Climate, 2018, 31, 1135−1153.
(38) Wang, N., D. Jiang*, and X. Lang, Metric-dependent tendency of tropical belt width changes during the last glacial maximum, Journal of Climate, 2018, 31, 8527−8540.
(39) Wang, X., D. Jiang*, and X. Lang, Climate change of 4°C global warming above pre-industrial levels, Advances in Atmospheric Sciences, 2018, 35, 757−770.
(40) Jiang*, D., Y. Liu, and X. Lang, A multi-model analysis of glacier equilibrium line altitudes in western China during the last glacial maximum, Science China Earth Sciences, 2019, 62, 1241−1255.
(41) Liu, S., D. Jiang*, and X. Lang, Mid-Holocene drylands: A multi-model analysis using Paleoclimate Modelling Intercomparison Project Phase III (PMIP3) simulations, The Holocene, 2019, 29, 1425−1438.
(42) Wang, X., D. Jiang*, and X. Lang, Extreme temperature and precipitation changes associated with four degree of global warming above pre-industrial levels, International Journal of Climatology, 2019, 39, 1822−1838.
(43) Zhou, X., D. Jiang*, and X. Lang, A multi-model analysis of ‘Little Ice Age’ climate over China, The Holocene, 2019, 29, 592−605.
(44) Jiang*, D., D. Si, and X. Lang, Evaluation of East Asian summer climate prediction from the CESM large-ensemble initialized decadal prediction project. Journal of Meteorological Research, 2020, 34, 252−263.
(45) Jiang*, D., D. Hu, Z. Tian, and X. Lang, Differences between CMIP6 and CMIP5 models in simulating climate over China and the East Asian monsoon, Advances in Atmospheric Sciences, 2020, 37, 1102−1118.
(46) Liu, S., D. Jiang*, and X. Lang*, The weakening and eastward movement of ENSO impacts during the last glacial maximum, Journal of Climate, 2020, 33, 5507−5526
(47) Wang, N., D. Jiang*, and X. Lang*, Mechanisms for spatially inhomogeneous changes in East Asian summer monsoon precipitation during the mid-Holocene, Journal of Climate, 2020, 33, 2945−2965.
(48) Wang, N., D. Jiang*, and X. Lang, Seasonality in the response of East Asian westerly jet to the mid-Holocene forcing, Journal of Geophysical Research: Atmospheres, 2020, 125, e2020JD033003.
(49) Zhou, X., D. Jiang*, and X. Lang, Unstable relationship between the Pacific Decadal Oscillation and eastern China summer precipitation: Insights from the Medieval Climate Anomaly and Little Ice Age, The Holocene, 2020, 30, 799−809.
(50) Chen, W., D. Jiang*, X. Lang, and Z. Tian, Understanding the cold biases of CMIP5 models over China with weather regimes, Advances in Climate Change Research, 2021, 12, 373–383.
(51) Liu, S., X. Lang, and D. Jiang*, Time-varying responses of dryland aridity to external forcings over the last 21 ka, Quaternary Science Reviews, 2021, 262, 106989.
(52) Liu, Z., X. Lang, and D. Jiang*, Impact of stratospheric aerosol injection geoengineering on the summer climate over East Asia, Journal of Geophysical Research: Atmospheres, 2021, 126, e2021JD035049.
(53) Miao*, J., and D. Jiang*, Multidecadal variations in the East Asian winter monsoon and their relationship with the Atlantic multidecadal oscillation since 1850, Journal of Climate, 2021, 34, 7525–7539.
(54) Wang, X., D. Jiang*, and X. Lang, Future changes in aridity index at two and four degrees of global warming above preindustrial levels, International Journal of Climatology, 2021, 41, 278–294.
(55) Wu, B., X. Lang, and D. Jiang*, Koppen climate zones in China over the last 21,000 years, Journal of Geophysical Research: Atmospheres, 2021, 126, e2020JD034310.
(56) Wu, B., X. Lang, and D. Jiang*, Migration of the northern boundary of the East Asian summer monsoon over the last 21,000 years, Journal of Geophysical Research: Atmospheres, 2021, 126, e2021JD035078.
(57) Yao, S., D. Jiang*, and Z. Zhang, Moisture sources of heavy precipitation in Xinjiang characterized by meteorological patterns, Journal of Hydrometeorology, 2021, 22, 2213–2225.
(58) Yao, S., D. Jiang*, and Z. Zhang, Lagrangian simulations of moisture sources for Chinese Xinjiang precipitation during 1979–2018, International Journal of Climatology, 2021, 41, E216–E232.
(59) Chen, W., D. Jiang*, X. Lang, and Z. Tian, Improved skill of Coupled Model Intercomparison Project phase 6 over phase 5 models in reproducing weather regimes in East Asia, International Journal of Climatology, 2022, 42, 9271–9287.
(60) Hu, D., D. Jiang*, Z. Tian, and X. Lang, How skillful was the projected temperature over China during 2002–2018? Science Bulletin, 2022, 67, 1077–1085.
(61) Hu, D., D. Jiang*, Z. Tian, and X. Lang, Weakened amplitude and delayed phase of the future temperature seasonal cycle over China during the twenty-first century, International Journal of Climatology, 2022, 42, 7133–7145.
(62) Liu, Z., X. Lang, and D. Jiang*, Impact of stratospheric aerosol intervention geoengineering on surface air temperature in China: a surface energy budget perspective, Atmospheric Chemistry and Physics, 2022, 22, 7667–7680.
(63) Shi, J., D. Jiang*, Z. Tian, and X. Lang, Enhanced interannual variability in temperature during the last glacial maximum, Journal of Climate, 2022, 35, 5933–5950.
(64) Tian, Z., D. Hu, X. Lang, and D. Jiang*, Index- and model-dependent projections of East Asian summer monsoon in Coupled Model Intercomparison Project Phase 6 simulaitons, International Journal of Climatology, 2022, 42, 2208–2224.
(65) Wang, X., D. Jiang*, and X. Lang, Future changes in aridity in the Upper Indus Basin during the twenty-first century, Climate Research, 2022, 87, 117–132.
(66) Wang, X., X. Lang, and D. Jiang*, Detectable anthropogenic influence on summer compound hot events over China from 1965 to 2014, Environmental Research Letters, 2022, 17, 034042.
(67) Wu, X., and D. Jiang*, Probabilistic impacts of compound dry and hot events on global gross primary production, Environmental Research Letters, 2022, 17, 034049.
(68) Ge, Y., J. Miao, X. Lang, D. Si, and D. Jiang*, Combined impacts of the Pacific Decadal Oscillation and Atlantic Multidecadal Oscillation on summer precipitation in eastern China during the Medieval Climate Anomaly and Little Ice Age, Journal of Geophysical Research: Atmospheres, 2023, 128, e2023JD038920.
(69) Hu, D., Z. Tian, X. Lang, and D. Jiang*, Limited skill of projected land precipitation by IPCC models during 2002–2020, Journal of Geophysical Research: Atmospheres, 2023, 128, e2022JD037851.
(70)
Hu, D., Z. Tian, X. Lang, and D. Jiang*, Regional difference in precipitation seasonality over China from CMIP6 projections, International Journal of Climatology, 2023, 43, 6179–6190.
(71) Liu, Z., X. Lang, J. Miao, and D. Jiang*, Impact of stratospheric aerosol injection on the East Asian winter monsoon, Geophysical Research Letters, 2023, 50, e2022GL102109.
(72) Shi, J., Z. Tian, X. Lang, and D. Jiang*, Past to future drylands in China: A multimodel analysis using CMIP6 simulations, Journal of Climate, 2023, 36, 2735–2751.
(73) Wang, L., Z. Liu, X. Lang, and D. Jiang*, Understanding surface air temperature cold bias over China in CMIP6 models, Journal of Geophysical Research: Atmospheres, 2023, 128, e2023JD039515.
(74) Wang, T., N. Wang, and D. Jiang*, Last glacial maximum ITCZ changes from PMIP3/4 simulations, Journal of Geophysical Research: Atmospheres, 2023, 128, e2022JD038103.
(75) Wu, B., X. Lang, and D. Jiang*, Changes in summer precipitation modes over eastern China in simulated warm intervals of the last interglacial, mid-Holocene, and twenty-first century, Journal of Climate, 2023, 36, 2401–2420.
(76) Wu, X., Y. Yang, and D. Jiang*, Dramatic increase in the probability of 2006-like compound dry and hot events over Southwest China under future global warming, Weather and Climate Extremes, 2023, 41, 100592.
(77) Yang, Y., Z. Lin, L. Luo, L. Zhong, and D. Jiang*, Variation of surface air temperature induced by enhanced land–atmosphere coupling during 1981–2020 in Xinjiang, Northwest China, Journal of Geophysical Research: Atmospheres, 2023, 128, e2022JD037983.
(78) Yao, S., and D. Jiang*, Lagrangian simulations of moisture sources for Northeast China precipitation during 1979–2018, Journal of Hydrometeorology, 2023, 24, 2225–2238.
(79) Ge, Y., J. Miao, and D. Jiang*, Contributions of internal variability and external forcing to interdecadal variations of East Asian winter temperature during the last millennium, Climate Dynamics, 2024, 62, 8573–8585.
(80) Han, Y., D. Jiang*, D. Si, Y. Ma, and W. Ma, Time-lagged effects of the spring atmospheric heat source over the Tibetan Plateau on summer precipitation in Northeast China during 1961–2020: Role of soil moisture, Advances in Atmospheric Sciences, 2024, 41, 1527–1538.
(81) Han, Y., D. Jiang*, D. Si, Y. Ma, W. Ma, and W. Hu, Influence of winter northern Eurasian snow depth on the early summer Tibetan Plateau heat source during 1950–2019, Climate Dynamics, 2024, 62, 4253–4266.
(82) Liu, Z., X. Lang, and D. Jiang*, Stratospheric aerosol injection geoengineering would mitigate greeenhouse gas-induced drying and affect global drought patterns, Journal of Geophysical Research: Atmospheres, 2024, 129, e2023JD039988.
(83) Miao, J., Y. Ge. and D. Jiang*, Changes of Atlantic multidecadal variability during the Medieval Climate Anomaly and Little Ice Age and associated causes, Journal of Geophysical Research: Atmospheres, 2024, 129, e2023JD039966.
(84) Shi, J., Z. Tian, X. Lang, and D. Jiang*, Projected changes in the interannual variability of surface air temperature using CMIP6 simulations, Climate Dynamics, 2024, 62, 431–446.
(85) Shi, Z., D. Jiang*, and Y. Wang, Spatiotemporal dependence of compound drought–heatwave and fire activity in China, Weather and Climate Extremes, 2024, 45, 100695.
(86) Wang, L., Z. Liu, and D. Jiang*, Tropospheric cooling induces annual wet biases over China in CMIP6 models, Climate Dynamics, 2024, 62, 9673–9685.
(87) Wang, T., Z. Tian, and D. Jiang*, Changes in the Asian ITCZ during the Last Interglacial, the Last Glacial Maximum, and the mid-Holocene, Journal of Geophysical Research: Atmospheres, 2024, 129, e2023JD040212.
(88) Wu, B., and D. Jiang*, Unstable interdecadal relationship between the Pacific Decadal Oscillation and eastern China summer precipitation in simulated interglacial epochs and twenty-first century, Global and Planetary Change, 2024, 237, 104458.
(89) Yao, Q., D. Jiang*, B. Zheng, X. Wang*, X. Zhu, K. Fang, L. Shi, Z. Wang, Y. Wang, L. Zhong, Y. Pei, A. Hudson, S. Xu, M. Bai, X. Huang, and V. Trouet*, Anthropogenic warming is a key climate indicator of rising urban fire activity in China, National Science Review, 2024, 11, nwae163.
(90) Zhang, R., Z. Liu, D. Jiang*, Y. Yu, Z. Zhang, Y. Yang, N. Tan, D. Si, Q. Zhang, and X. Zhou, Cenozoic Indo-Pacific warm pool controlled by both atmospheric CO2 and paleogeography, Science Bulletin, 2024, 69, 1323–1331.
(91) Chen, X., D. Jiang*, H. Fan, Y. Liu, and C. Huang, Changes in human-perceived temperature extremes and associated population exposure across China, Atmospheric Research, 2025, 315, 107896.
(92) Lu, Z., L. Zhong, Y. Yang, X. Han, X. Jiang, Z. Shi, and D. Jiang*, Spatial characteristics and connectivity of urban floods in eastern China: Insights from a newly established data set during 2010–2020, Geophysical Research Letters, 2025, 52, e2024GL113017.
(93) Wu, X., D. Jiang*, and Y. Yang, ENSO exacerbated the impact of compound dry–hot events on mainze yield over China during 1961–2020, Global and Planetary Change, 2025, 251, 104828.