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人才详细信息

姓名:马庆峰
性别:
学历:博士
专家类别:副研究员
电话:
传真:
电子邮箱:maqingfeng@tpestations.ac.cn
职称:副研究员
通讯地址:北京市朝阳区林萃路16号院3号楼

简介

2020.10-          中国科学院青藏高原研究所    副研究员

2014.7-2020.9   中国科学院青藏高原研究所    博士后/特别研究助理

2008.9-2014.6   中国科学院青藏高原研究所    博士

2004.9-2008.6   曲阜师范大学学士

研究方向

湖泊沉积与第四纪环境    

职务

社会任职

承担项目

1. 国家自然科学基金面上项目,青藏高原中西部典型湖泊记录的全新世环境变化与人类活动关系研究,2023–2026,主持
2. 国家自然科学基金青年项目,青藏高原中西部现代花粉气候意义及塔若错气候变化定量重建研究,2016–2018,主持
3. 国际大陆科学钻探计划(ICDP),The Nam Co Drilling Project, Tibet (NamCore): A one million year sedimentary record from the third pole,2020-,参加
4. 国家自然科学基金重点项目,青藏高原中部纳木错岩芯记录的一百万年以来水文与气候变化,2024–2028,参加
5. 国家自然科学基金重点项目,青藏高原过去40年湖泊水量与盐度变化及气候变化响应,2019–2023,参加
6. 中国科学院战略性先导科技专项(A类),季风过渡区与中亚西风区湖泊沉积记录的气候转型与特征事件,2018–2023,参加
7. 科技部基础性工作专项重点项目,青藏高原资料匮乏区综合科学考察, 2012–2017,参加

获奖及荣誉

代表论著

代表性论文:

第一/通讯作者论文

   1. Ma QF, Zhu LP*, Ju JT, Wang JB, Wang Y, Huang L, Haberzettl T. 2024. A modern pollen dataset from lake surface sediments on the central and western Tibetan Plateau. Earth System Science Data, 16, 311–320.

2. Ma QF, Zhu LP*, Wang JB, Ju JT, Lü XM, Frenzel P, Haberzettl T. 2024. Southward shifts and enhancements of the westerlies over the Tibetan Plateau during North Atlantic cooling events. Quaternary Science Reviews, 324, 108440.

   3. Ma QF, Zhu LP*, Wang JB*, Ju JT, Wang Y. 2023. Variations in spring atmospheric circulation on the southwestern Tibetan Plateau during Holocene linked to high- and low-latitude forcing. Geophysical Research Letters, 50, e2023GL103163.

   4. Ma QF*, Zhu LP, Yang RM, Huang L, Wang JB. 2023. Modern pollen distribution in moss samples along an elevational gradient in southeast Tibet. Ecological Indicators, 154, 110867.

   5. Ma QF, Zhu LP*, Wang JB, Ju JT, Wang Y, Lü XM, Kasper T, Haberzettl T. 2020. Late Holocene vegetation responses to climate change and human impact on the central Tibetan Plateau. Science of the Total Environment, 708, 135370.

6. Ma QF*, Zhu LP, Lü XM, Wang JB, Ju JT, Kasper T, Daut G, Haberzettl T. 2019. Late glacial and Holocene vegetation and climate variations at Lake Tangra Yumco, central Tibetan Plateau. Global and Planetary Change, 174, 16–25.

7. Ma QF*, Zhu LP, Lu XM, Wang Y, Guo Y, Wang JB, Ju JT, Peng P, Tang LY. 2017. Modern pollen assemblages from surface lake sediments and their environmental implications on the southwestern Tibetan Plateau. Boreas, 46, 242–253.

8. Ma QF*, Zhu LP, Wang JB, Ju JT, Lü XM, Wang Y, Guo Y, Yang RM, Kasper T, Haberzettl T, Tang LY. 2017. Artemisia/Chenopodiaceae ratio from surface lake sediments on the central and western Tibetan Plateau and its application. Palaeogeography, Palaeoclimatology, Palaeoecology, 479, 138–145.

9. Ma QF*, Zhu LP*, Lü XM, Guo Y, Ju JT, Wang JB, Wang Y, Tang LY. 2014. Pollen-inferred Holocene vegetation and climate histories in Taro Co, southwestern Tibetan Plateau. Chinese Science Bulletin, 59(31), 4101–4114.  


其他合作论文

   10. Li CL, Zhu LP, Ju JT, Ma QF, Wang JB, Kou QQ. 2024. Impacts of human and herbivorous feces on lake surface sediments of the Tibetan Plateau based on fecal stanol proxies. Ecological Indicators, 158(1), 111487.

   11. Kou QQ, Zhu LP, Wang JB, Ma QF, Ju JT. 2023. Archaeal tetraether-inferred hydrological variations of Serling Co (Central Tibet) during the late Quaternary. Global and Planetary Change, 224, 104113.

   12. Du BL, Zhu LP, Ju JT, Wang JB, Ma QF, Kou QQ. 2023. A Quantification of Heat Storage Change-Based Evaporation Behavior in Middle–Large-Sized Lakes in the Inland of the Tibetan Plateau and Their Temporal and Spatial Variations. Remote Sensing, 15(14), 3460.

   13. Yu SW, Wang JB, Rühland KM, Zhu LP, Ju JT, Liu C, Ma QF, Smol JP. 2023. Spatial distribution of surface-sediment diatom assemblages from 45 Tibetan Plateau lakes and the development of a salinity transfer function. Ecological Indicators, 155, 110952.

   14. Liu C, Zhu LP, Wang JB, Ju JT, Ma QF, Kou QQ. 2023. The decrease of salinity in lakes on the Tibetan Plateau between 2000 and 2019 based on remote sensing model inversions. International Journal of Digital Earth, 16, 2644–2659.

   15. Kou QQ, Zhu LP, Ma QF, Wang JB, Ju JT, Xu T, Liu C, Li CL, Kai JL. 2022. Distribution, potential sources, and response to water depth of archaeal tetraethers in Tibetan Plateau lake sediments. Chemical Geology, 601, 120825.

   16. Kou QQ, Zhu LP, Ju JT, Wang JB, Xu T, Li CL, Ma QF. 2022. Influence of salinity on glycerol dialkyl glycerol tetraether-based indicators in Tibetan Plateau lakes: Implications for paleotemperature and paleosalinity reconstructions. Palaeogeography, Palaeoclimatology, Palaeoecology, 601, 111127.

   17. Zhang R, Zhu LP, Ma QF, Chen H, Liu C, Zubaida M. 2021. The consecutive lake group water storage variations and their dynamic response to climate change in the central Tibetan Plateau. Journal of Hydrology, 601, 126615.

   18. Xu T, Zhu LP, Ma QF, Wang JB, Lü XM, Tang LY. 2021. Moisture and vegetation variations in the extremely cold-dry area of the Tibetan Plateau during the past 5000 years. Catena, 204, 105381.

   19. Chen H, Zhu LP, Wang JB, Ju JT, Ma QF, Xu T. 2021. Paleoclimate changes over the past 13,000 years recorded by Chibuzhang Co sediments in the source region of the Yangtze River, China. Palaeogeography, Palaeoclimatology, Palaeoecology, 573, 110433.

   20. Liu C, Zhu LP, Li JS, Wang JB, Ju JT, Qiao BJ, Ma QF., Wang SL. 2021. The increasing water clarity of Tibetan lakes over last 20 years according to MODIS data. Remote Sensing of Environment, 253, 112199.

   21. Liu C, Zhu LP, Wang JB, Ju JT, Ma QF, Qiao BJ, Wang Y, Xu T, Chen H, Kou QQ, Zhang R, Kai JL. 2021. In-situ quality investigation of the lakes on the Tibetan Plateau. Science Bulletin, 66, 1727–1730.

   22. Tang LY, Shen CM, Lu HY, Li CH, Ma QF. 2021. Fifty years of Quaternary palynology in the Tibetan Plateau. Science China: Earth Sciences, 64(11), 1825–1843.

   23. Li MH, Zhu LP, Wang JB, Ju JT, Liu C, Ma QF, Xu T, Qiao BJ, Wang XX. 2021. Holocene lake evolution and glacial fluctuations indicated by carbonate minerals and their isotopic compositions in the sediments of a glacial melt recharge lake on the northwestern Tibetan Plateau. Frontiers in Earth Science, 9, 656281.

   24. Li J, Zhu LP, Li MH, Wang JB, Ma QF. 2020. Origin of modern dolomite in surface lake sediments on the central and western Tibetan Plateau. Quaternary International, 544, 65–75.

   25. Wang JB, Huang L, Ju JT, Daut G, Ma QF, Zhu LP, Haberzettl T, Baade J, Mäusbacher R, Hamilton A, Graves K, Olsthoorn J, Laval BE. 2020. Seasonal stratification of a deep, high-altitude, dimictic lake: Nam Co, Tibetan Plateau. Journal of Hydrology, 584, 124668.

   26. Kai JL, Wang JB, Ju JT, Huang L, Ma QF, Daut G, Zhu LP. 2020. Spatio-temporal variations of hydrochemistry and modern sedimentation processes in the Nam Co basin, Tibetan Plateau: Implications for carbonate precipitation. Journal of Great Lakes Research, 46, 961–975.

   27. Gyawali AR, Wang JB, Ma QF, Wang Y, Xu T, Guo Y, Zhu LP. 2019. Paleo-environmental change since the Late Glacial inferred from lacustrine sediment in Selin Co, central Tibet. Palaeogeography, Palaeoclimatology, Palaeoecology, 516, 101–112.

   28. Xu T, Zhu LP, Lü XM, Ma QF, Wang JB, Ju JT, Huang L. 2019. Mid- to late-Holocene paleoenvironmental changes and glacier fluctuations reconstructed from the sediments of proglacial lake Buruo Co, northern Tibetan Plateau. Palaeogeography, Palaeoclimatology, Palaeoecology, 517, 74–85.

   29. Qiao BJ, Zhu LP, Wang JB, Ju JT, Ma QF, Huang L, Chen H, Liu C, Xu T. 2019. Estimation of lake water storage and changes based on bathymetric data and altimetry data and the association with climate change in the central Tibetan Plateau. Journal of Hydrology, 578, 124052.

   30. Wang JB, Huang L, Ju JT, Daut G, Wang Y, Ma QF, Zhu LP, Haberzettl T, Baade J, Mäusbacher R. 2019. Spatial and temporal variations in water temperature in a high-altitude deep dimictic mountain lake (Nam Co), central Tibetan Plateau. Journal of Great Lakes Research, 45 (2), 212–223.

   31. Zhu LP, Wang JB, Ju JT, Ma N, Zhang YS, Liu C, Han BP, Liu LS, Wang MD, Ma QF. 2019. Climatic and lake environmental changes in the Serling Co region of Tibet over a variety of timescales. Science Bulletin, 64, 422–424.

   32. Chen H, Zhu LP, Ju JT, Wang JB, Ma QF. 2019. Temporal variability of 14C reservoir effects and sedimentological chronology analysis in lake sediments from Chibuzhang Co, North Tibet (China). Quaternary Geochronology, 52, 88–102.

   33. Ju JT, Zhu LP, Wang JB, Cui YY, Huang L, Yang RM, Ma QF, Luo L, Wang YJ. 2017. Estimating the contribution of glacial meltwater to Ranwu Lake, a proglacial lake in SE Tibet, using observation data and stable isotopic analyses. Environmental Earth Sciences, 76, 229.

   34. Yang RM, Zhu LP, Wang JB, Ju JT, Ma QF, Falko T, Guo Y. 2017. Spatiotemporal variations in volume of closed lakes on the Tibetan Plateau and their climatic responses from 1976 to 2013. Climatic Change, 140, 621–633.

   35. Qiao BJ, Zhu LP, Wang JB, Ju JT, Ma QF, Liu C. 2017. Estimation of lakes water storage and their changes on the northwestern Tibetan Plateau based on bathymetric and Landsat data and driving force analyses. Quaternary International, 454, 56–67.

   36. Wang JB, Zhu LP, Wang Y, Peng P, Ma QF, Haberzettl T, Kasper T, Matsunaka T, Nakamura T. 2017. Variability of the 14C reservoir effects in Lake Tangra Yumco, Central Tibet (China), determined from recent sedimentation rates and dating of plant fossils. Quaternary International, 430, 3–11.

   37. Wang Y, Wang JB, Zhu LP, Lin X, Hu JF, Ma QF, Ju JT, Peng P, Yang RM. 2017. Mid- to late-Holocene paleoenvironmental changes inferred from organic geochemical proxies in Lake Tangra Yumco, Central Tibetan Plateau. The Holocene, 27(10), 1475–1486.

   38. Guo Y, Zhu LP, Peter F, Ma QF, Ju JT, Peng P, Wang JB, Daut G. 2016. Holocene lake level fluctuations and environmental changes at Taro Co, southwestern Tibet, based on ostracod-inferred water depth reconstruction. The Holocene, 26(1), 29–43.

   39. Turner F, Zhu LP, Lü XM, Peng P, Ma QF, Wang JB, Hou JZ, Lin QQ, Yang RM, Frenzel P. 2016. Pediastrum sensu lato (Chlorophyceae) assemblages from surface sediments of lakes and ponds on the Tibetan Plateau. Hydrobiologia, 771, 101–118.

   40. Hu X, Zhu LP, Wang Y, Wang JB, Peng P, Ma QF, Hu JF, Lin X. 2014. Climatic significance of n-alkanes and their compound-specific δ D values from lake surface sediments on the Southwestern Tibetan Plateau. Chinese Science Bulletin, 59 (24), 3022–3033.

   41. Tang LY, Mao LM, Lü XM, Ma QF, Zhou ZZ, Yang CL, Kong ZC, Batten DJ. 2013. Palaeoecological and palaeoenvironmental significance of some important spores and micro-algae in Quaternary deposits. Chinese Science Bulletin, 58 (25), 3125–3139.

   42. 马庆峰*,朱立平*,吕新苗,郭允,鞠建廷,王君波,汪勇,唐领余. 2014. 花粉揭示的青藏高原西南部塔若错全新世以来植被与气候变化. 科学通报, 5926),2630–2642.

   43. 项超生,汪勇,王君波,马庆峰,王世航. 2022. 高海拔干旱区湖泊沉积物多指标记录的环境变化研究. 干旱区地理45(2)435–444.

   44. 唐领余,沈才明,吕厚远,李春海,马庆峰. 2021. 青藏高原第四纪孢粉研究五十年. 中国科学:地球科学5112),2015–2034.

   45. 许腾,朱立平,王君波,鞠建廷,马庆峰. 2019. 青藏高原北部冰前湖沉积记录的中晚全新世冰川活动. 第四纪研究393),717–730.

   46. 朱少航,朱立平,王君波,鞠建廷,马庆峰,陈浩,许腾,开金磊. 2019. 西藏玛旁雍错沉积揭示的晚冰期以来环境变化. 第四纪研究39(3)602–614.

   47. 鞠建廷,朱立平,黄磊,杨瑞敏,马庆峰,胡星,王永杰,甄晓林. 2015. 基于监测的藏东南然乌湖现代过程:湖泊对冰川融水的响应程度. 科学通报601),16–26.

   48. 黄磊,王君波,朱立平,鞠建廷,汪勇,马庆峰. 2015. 纳木错水温变化及热力学分层特征初步研究. 湖泊科学254),711–718.

   49. 胡星,朱立平,汪勇,王君波,彭萍,马庆峰,胡建芳,林晓. 2014. 青藏高原西南部湖泊沉积正构烷烃及其单体δD的气候意义. 科学通报5919),1892–1903.

   50. 王君波,彭萍,马庆峰,朱立平. 2013. 西藏玛旁雍错和拉昂错水深、水质特征及现代沉积速率. 湖泊科学254):609–616.

   51. 唐领余,毛礼米,吕新苗,马庆峰,周忠泽,杨春蕾,孔昭宸,Batten D J. 2013. 第四纪沉积物中重要蕨类孢子和微体藻类的古生态环境指示意义. 科学通报 5820),1969–1983.

   52. 王君波,彭萍,马庆峰,朱立平. 2010. 西藏当惹雍错和扎日南木错现代湖泊基本特征. 湖泊科学224),629–632.

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