牛富俊，1970年8月出生，汉族，甘肃人。

1998年9月博士毕业于西安工程学院水文地质工程地质系；

1999年3月—2002年7月在中科院寒区旱区环境与工程研究所冻土工程国家重点实验室博士后流动站工作，专业：冻土工程；

2000年被聘任为中科院寒区旱区环境与工程研究所冻土工程国家重点实验室创新副研究员；

2004年11月任项目研究员；

2005年8—10月北海道大学工学部和低温科学研究所高访学者；

2006年任创新研究员、博士生导师，目前从事冻土工程、冻土环境研究工作；

2010年8-12月加拿大渥太华大学高访学者。目前担任冻土工程国家重点实验室副主任，并任国际冻土协会冻土工程工作组副主席、中国地理学会冰川冻土分会理事、甘肃省地质学会理事、甘肃省岩石力学学会理事、甘肃省岩石与地球化学学会常务理事。

岩土工程

防灾减灾工程及防护工程

入选“国家百千万人才工程”、甘肃省领军人才，曾获国家科技进步一等奖（创新团队奖）、甘肃省科学技术进步一等奖3次、中国科学院杰出科技成就奖、中国铁道学会科学技术奖一等奖、第五届中国科协期刊优秀学术论文特别优秀学术论文奖，及中国地质学会第十一届青年地质科技奖（银锤奖）、中国地理学会第十届全国青年地理科技奖、第七届青藏高原研究会青年科技奖、中科院优秀导师奖及兰州分院优秀导师奖等。

正式发表论文300余篇，其中SCI收录论文100余篇。

部分论文：

[1]      Luo J, Niu F*, Lin Z, et al. Abrupt increase in thermokarst lakes on the central Tibetan Plateau over the last 50 years[J]. Catena, 2022, 217: 106497.

[2]      Zhang S, Niu F*, Wang S, et al. Risk assessment of engineering diseases of embankment–bridge transition section for railway in permafrost regions[J]. Permafrost and Periglacial Processes, 2022, 33(1): 46-62.

[3]      Niu F, Jiang H, Su W, et al. Performance degradation of polymer material under freeze-thaw cycles: A case study of extruded polystyrene board[J]. Polymer Testing, 2021, 96: 107067.

[4]      Zhang S, Niu F*, Wang J, et al. Evaluation of damage probability of railway embankments in permafrost regions in Qinghai–Tibet Plateau[J]. Engineering Geology, 2021, 284: 106027.

[5]      Zhang S, Niu F*, Wang S, et al. Necessity of cooling methods for transportation infrastructure construction in permafrost regions of Qinghai–Tibet Plateau[J]. Bulletin of Engineering Geology and the Environment, 2021, 80(9): 6705-6723.

[6]      Liu M, Niu F*, Lin Z, et al. Field investigation on thermal characteristics of a slope-cooling structure for permafrost embankment in the Qinghai-Tibet Plateau[J]. Cold Regions Science and Technology, 2020, 179: 103150.

[7]      Li A, Matsuoka N, Niu F, et al. Ice needles weave patterns of stones in freezing landscapes[J]. Proceedings of the National Academy of Sciences, 2021, 118(40).

[8]      Gao Z, Niu F*, Lin Z, et al. Fractal and multifractal analysis of soil particle-size distribution and correlation with soil hydrological properties in active layer of Qinghai–Tibet Plateau, China[J]. CATENA, 2021, 203: 105373.

[9]      Gao Z, Niu F*, Wang Y, et al. Suprapermafrost groundwater flow and exchange around a thermokarst lake on the Qinghai–Tibet Plateau, China[J]. Journal of Hydrology, 2021, 593: 125882.

[10]   Niu F, Zheng H, Li A. The study of frost heave mechanism of high-speed railway foundation by field-monitored data and indoor verification experiment[J]. Acta Geotechnica, 2020, 15(3): 581-593.

[11]   Gao Z, Niu F*, Lin Z. Effects of permafrost degradation on thermokarst lake hydrochemistry in the Qinghai‐Tibet Plateau, China[J]. Hydrological Processes, 2020, 34(26): 5659-5673.

[12]   Shang Y, Niu F*, Lin Z, et al. Analysis of the cooling effect of a concrete thermal pile in permafrost regions[J]. Applied Thermal Engineering, 2020, 173: 115254.

[13]   Liu M, Niu F*, Luo J, et al. Performance, applicability, and optimization of a new slope cooling and protection structure for road embankment over warm permafrost[J]. International Journal of Heat and Mass Transfer, 2020, 162: 120388.

[14]   Wang S, Niu F*, Chen J, et al. Permafrost research in China related to express highway construction[J]. Permafrost and Periglacial Processes, 2020, 31(3): 406-416.

[15]   Miao Q, Niu F*, Lin Z, et al. Comparing frost heave characteristics in cut and embankment sections along a high-speed railway in seasonally frozen ground of Northeast China[J]. Cold regions science and technology, 2020, 170: 102921.

[16]   Shi Y, Niu F*, Lin Z, et al. Freezing/thawing index variations over the circum-Arctic from 1901 to 2015 and the permafrost extent[J]. Science of the Total Environment, 2019, 660: 1294-1305.

[17]   Luo J, Niu F*, Lin Z, et al. Recent acceleration of thaw slumping in permafrost terrain of Qinghai-Tibet Plateau: An example from the Beiluhe Region[J]. Geomorphology, 2019, 341: 79-85.

[18]   Niu F, Gao Z, Lin Z, et al. Vegetation influence on the soil hydrological regime in permafrost regions of the Qinghai-Tibet Plateau, China[J]. Geoderma, 2019, 354: 113892.

[19]   Luo Jing, Niu Fujun*, Liu Minghao, Lin Zhanju, Yin Guoan. Field experimental study on long-term cooling and deformation characteristics of crushed-rock revetment embankment at the Qinghai–Tibet Railway. Applied Thermal Engineering, 2018, 139, 256-263.

[20]   Gao Zeyong, Niu Fujun*, Lin Zhanju, Luo Jing, Yin Guoan, Wang Yibo. Evaluation of thermokarst lake water balance in the Qinghai–Tibet Plateau via isotope tracers. Science of The Total Environment, 2018, 636, 1-11.

[21]   Shi Yaya, Niu Fujun*, Yang Chengsong, Che Tao, Lin Zhanju, Luo Jing. Permafrost Presence/Absence Mapping of the Qinghai-Tibet Plateau Based on Multi-Source Remote Sensing Data. Remote Sensing, 2018, 10(2), 309.

[22]   Lin Zhanju, Niu Fujun*, Li Xiaolong, Li Anyuan, Liu Minhao, Luo Jing, Shao Zhujie. Characteristics and controlling factors of frost heave in high-speed railway subgrade, Northwest China. Cold Regions Science and Technology, 2018, 153, 33-44.

[23]   Liu Minghao, Ma Wei, Niu Fujun*, Luo Jing, Yin Guoan. Thermal performance of a novel crushed-rock embankment structure for expressway in permafrost regions. International Journal of Heat and Mass Transfer, 2018, 127, 1178-1188.

[24]   Luo Jing, Niu Fujun*, Lin Zhanju, Liu Minghao, Yin Guoan. Variations in the northern permafrost boundary over the last four decades in the Xidatan region, Qinghai–Tibet Plateau. Journal of Mountain Science, 2018, 15(4), 765-778.

[25]   Niu, F., Zheng, H., & Li, A. The study of frost heave mechanism of high-speed railway foundation by field-monitored data and indoor verification experiment. Acta Geotechnica, 1-13.

[26]   Gao Z, Niu F*, Wang Y, et al. Impact of a thermokarst lake on the soil hydrological properties in permafrost regions of the Qinghai-Tibet Plateau, China. Science of The Total Environment, 2017, 574: 751-759.

[27]   Liu, M., Niu, F*., Ma, W., Fang, J., Lin, Z., & Luo, J. (2017). Experimental investigation on the enhanced cooling performance of a new crushed-rock revetment embankment in warm permafrost regions. Applied Thermal Engineering, 120, 121-129.

[28]   Niu Fujun*, Li Anyuan, Luo Jing, Lin Zhanju, Yin Guoan, Liu Minghao, Zheng Hao, Liu Hua. Soil moisture, ground temperatures, and deformation of a high-speed railway embankment in Northeast China. Cold Regions Science and Technology, 2017, 133: 7-14.

[29]   Li, A., Niu, F*., Zheng, H., Akagawa, S., Lin, Z., & Luo, J. (2017). Experimental measurement and numerical simulation of frost heave in saturated coarse-grained soil. Cold Regions Science and Technology, 137, 68-74.

[30]   Liu Hua，Niu Fujun,Guan Hui，An engineering evaluation index of thermal asymmetry in subgrade and its optimal design in cold regions，Cold Regions Science and Technology，2017.02.20，137：1~6

[31]   Lin Zhanju, Niu Fujun*, Fang Jianhong, Luo Jing, Yin Guoan. Interannual variations in hydrothermal regime around a thermokarst lake in Beiluhe, Qinghai-Tibet Plateau. Geomorphology, 2017, 276: 16-26.

[32]   Liu, H., Niu, F*., & Guan, H. (2017). An engineering evaluation index of thermal asymmetry in subgrade and its optimal design in cold regions. Cold Regions Science and Technology, 137, 1-6.

[33]   Niu Fujun, Cheng Guodong, Niu Yonghong, Zhang Mingyi, Luo Jing & Lin Zhanju. A naturally-occurring ‘cold earth’ spot in Northern China. Scientific Reports, 2016, 6:34184.

[34]   Dore, Guy, Niu, Fujun，Brooks, Heather，Adaptation Methods for Transportation Infrastructure Built on Degrading Permafrost，Permafrost and Periglacial Processes，2016.12.01，27(4)：352~364

[35]   Niu Fujun, Luo Jing, Lin Zhanju, et al. Thaw-induced slope failures and stability analyses in permafrost regions of the Qinghai-Tibet Plateau, China. Landslides, 2016, 13(1): 55-65.

[36]   NIU FuJun, LIU MingHao, CHENG GuoDong, LIN ZhanJu, LUO Jing, YIN GuoAn. Long-term thermal regimes of the Qinghai-Tibet Railway embankments in plateau permafrost regions. SCIENCE CHINA (Earth Sciences). 2015, 58(9): 1669-1676.)

[37]   Jing Luo, Fujun Niu*, Zhanju Lin, Minghao Liu, Guoan Yin. Thermokarst lake changes between 1969 and 2010 in the Beilu River Basin, Qinghai–Tibet Plateau, China. Science Bulletin. 2015, 60(5):556–564 .

[38]   Niu F, Luo J, Lin Z, et al. Thaw-induced slope failures and susceptibility mapping in permafrost regions of the Qinghai–Tibet Engineering Corridor, China[J]. Natural Hazards, 2014, 74(3): 1667-1682.

[39]   Niu F, Lin Z, Lu J, et al. Assessment of terrain susceptibility to thermokarst lake development along the Qinghai–Tibet engineering corridor, China. Environmental Earth Sciences. 2015, 73(9): 5631-5642.

[40]   Fujun Niu, Jing Luo Zhanju Lin, Minhao Liu, Guoan Yin. Morphological Characteristics of Thermokarst Lakes along the Qinghai-Tibet Transportation Corridor. Arctic, Antarctic, and Alpine research. 2014 46(4): 963-974。

[41]   Hua, L., Fujun, N*., Yonghong, N., & Xifeng, Y. Study on thermal regime of roadbed–culvert transition section along a high speed railway in seasonally frozen regions. Cold Regions Science and Technology, 2014, 106, 216-231.

[42]   Fujun Niu, Jing Luo, Zhanju Lin, Wei Ma, Jiahao Lu. Development and Thermal Regime of a Thaw Slump in the Qinghai-Tibet Plateau. Cold Regions Science and Technology. 2012, (83-84) 131-138.

[43]   Fujun Niu, Guodong Cheng, Wei Ma, Qingbai Wu. Thermal Status of the Main Roadbeds of the Qinghai-Tibet Railway in Permafrost Regions after 5 Years Service. Cold Regions Engineering 2012: Sustainable Infrastructure Development in a Changing Cold Environment, ASCE 2012: 424-433.

[44]   Lin ZJ., Niu FJ*., Luo J., Liu H., Wang JL. Numerical simulation of influence of thermokarst lake on the frozen soil roadbed on Qinghai-Tibet Plateau. Cold Regions Engineering 2012: Sustainable Infrastructure Development in a Changing Cold Environment, ASCE 2012: 542-551.

[45]   LIN Zhanju, NIU Fujun*, LIU Hua, LU Jiahao, LUO Jing. Expansion of a thermokarst lake in Beiluhe Basin, on Qinghai-Tibetan Plateau. Tenth International Conference on Permafrost: Res

[46]   NIU Fujun*, LIN Zhanju, LU Jiahao, LIU Hua, XU Zhi-ying. Characteristics of Roadbed Settlement in Embankment-bridge Transition Section along the Qinghai-Tibet Railway in Permafrost Regions. Cold Regions Science and Technology, 2011, 65:437-445. (SCI)

[47]   Lin Zhan-ju, Niu Fu-jun*, Luo Jing. Changes in permafrost environments caused by construction and maintenance of Qinghai-Tibet Highway . Journal of Central South University of Technology. 2011, 18(5) : 1454-1464.  (SCI)

[48]   Niu Fujun*,Lin Zhanju,Liu Hua. Characteristics of thermokarst lakes and their influence on permafrost in Qinghai-Tibet Plateau. Geomorphology. 2011,132(3-4):222-233. 

[49]   LIN Zhanju, NIU Fujun*, LIU Hua, LU Jiahao. Disturbance-related thawing of a ditch and its influence on roadbeds on permafrost. Cold Regions Science and Technology. 2011,66: 105-114.

[50]   Zhanju Lin, Fujun Niu*, Hua Liu, Jiahao Lu. Hydrothermal Processes of Alpine Tundra Lakes, Beiluhe Basin, Qinghai-Tibet Plateau. Cold Regions Science and Technology. 2011,65(3):446-455. (SCI)

[51]   Lin Zhanju, Niu Fujun*, Xu Zhiying. Thermal Regime of a Thermokarst Lake and its Influence on Permafrost, Beiluhe Basin, Qinghai-Tibet Plateau. PERMAFROST AND PERIGLACIAL PROCESSES  2010, 21(4): 315-324.

[52]    Niu Fujun, Liu Xingfu, Ma Wei. Monitoring study on the boundary thermal conditions of duct-ventilated embankment in permafrost regions. COLD REGIONS SCIENCE AND TECHNOLOGY.  2008,53(3): 305-316.

[53]   Niu Fujun, Xu Jian, Lin Zhanju. Permafrost Characteristics of the Qinghai-Tibet Plateau and Methods of Roadbed Construction of Railway. ACTA GEOLOGICA SINICA-ENGLISH EDITION.2008, 82(5): 949-958.

[54]   Niu Fujun, Cheng Guodong, Xia Huimin. Field experiment study on effects of duct-ventilated railway embankment on protecting the underlying permafrost. COLD REGIONS SCIENCE AND TECHNOLOGY. 2006, 45(3): 178-192.

[55]   Wei Ma, Niu Fujun, Satoshi Akagawa. Slope instability phenomena in permafrost regions of Qinghai-Tibet Plateau, China. LANDSLIDES. 2006, 3(3): 260-264.

[56]   Niu FJ, Cheng GD, Ni WK. Engineering-related slope failure in permafrost regions of the Qinghai-Tibet Plateau. COLD REGIONS SCIENCE AND TECHNOLOGY. 2005, 42(3): 215-225.

[57]   Niu FJ*, Cheng GD, Yu QH. Ground-temperature controlling effects of duct-ventilated railway embankment in permafrost regions. SCIENCE IN CHINA SERIES D-EARTH SCIENCES. 2004, 47(1):  152-160.

[58]   牛富俊, 程国栋, 石亚亚, 等. 泛北极多年冻土及重大线性工程稳定性状况[J]. Journal of Earth Sciences & Environment, 2021, 43(3).

[59]   牛富俊, 王玮, 林战举, & 罗京. (2018). 青藏高原多年冻土区热喀斯特湖环境及水文学效应研究. 地球科学进展, 33(4), 335-342.

[60]   商允虎, 牛富俊, 刘明浩, 吴旭阳, & 罗京. (2017). 多年冻土区桥梁工程桩基础服役期温度场研究. 岩石力学与工程学报, 36(9), 2313-2323.

[61]   刘明浩, 牛富俊, 林战举, & 罗京. (2017). 高温冻土区 U 型块石路基长期降温效果及变形特征研究. 岩土力学, 38(11), 3304-3310.

[62]   牛富俊，林战举，吴旭阳，商允虎，李肖伦，邵珠杰.兰新客运专线浩门区间路基温度、 水分及冻胀变形特征.冰川冻土，2016，38(4):1074-1082

[63]   罗京, 牛富俊*, 林战举, 刘明浩, 尹国安. 青藏工程走廊典型热融灾害现象及其热影响研究.工程地质学报. 2014, 22(2): 326-333.

[64]   牛富俊，刘 华，牛永红，林战举，鲁嘉濠，罗 京. 高速铁路路涵过渡段路基冻结特征试验研究. 岩石力学与工程学报.2014, 33(3)：639-646.

[65]   鲁嘉濠，牛富俊，林战举，刘华，罗京.考虑局地因素坡向影响的青藏高原工程走廊冻土分布与制图研究. 地理与地理信息科学. 2012，28（3）：63-67.

[66]   鲁嘉濠，程花，牛富俊，林战举，刘华. 青藏铁路沿线热喀斯特湖易发程度的区划评价.灾害学. 2012，27（4）：60-64.

[67]   罗京，牛富俊，林战举，鲁嘉濠.青藏高原北麓河地区典型热融湖塘周边多年冻土特征研究.冰川冻土. 2012 , 34 (5): 1110-1117.

[68]   马巍，牛富俊，穆彦虎. 青藏高原重大冻土工程的基础研究. 地球科学进展. 2012, 27(11): 1185-1191.

[69]   牛富俊, 马巍, 吴青柏. 青藏铁路主要冻土路基工程热稳定性及主要冻融灾害. 地球科学与环境学报,2011(2): 196-206.

[70]   牛富俊,程国栋,赖远明,靳德武.青藏高原多年冻土区热融滑塌型斜坡失稳研究.岩土工程学报, 2004, 26(3): 402-406.

先后承担国家自然科学青年基金、面上基金、国际合作与交流项目、重点基金，中科院西部之光人才培养项目、联合学者项目及方向性项目，科技部科技支撑计划项目专题、973前期专项、第二次青藏高原科学考察研究专题等30余项。近期在研项目：

1. 第二次青藏高原综合科学考察研究任务九专题五，2019QZKK0905，冻土冻融灾害及重大工程病害，2019/11-2022/10，3770万元，在研，主持；

2.中国科学院战略性先导科技专项(A类)子课题，三极重大工程决策服务支持，XDA19070504，2018/01-2022/12，473.08万元，在研，主持；

3.国家自然科学重点基金项目，41730640，青藏高原多年冻土区热喀斯特湖环境及水文学效应，2018/01-2022/12，330万元，在研，主持；

4.中国铁路总公司项目，2016G003-D，青藏铁路高原冻土边坡冻害整治技术深化研究，2016/05-2017/12，80万，结题，主持；

5.国家科技支撑计划项目课题5，2014BAG05B05，多年冻土区大尺度桥隧构造物灾变风险与控制技术研究，2014/01-2016/12，308万元，结题，主持；

6.中国科学院西部行动计划项目课题3，KZCX2-XB3-19，高温冻土路基潜在病害机理及处置措施研究，2013/01-2015/12，200万元，结题，主持；

7.国家自然科学基金创新群体项目，41121061，冻土与寒区工程（考虑局地因素的多年冻土模型研究），2012/01-2014/12，60万元，结题，参加；

8.国家自然科学重点基金项目，41030741，气候变化及工程影响下青藏高原多年冻土区热融灾害评估，2011/01-2014/12，185万元，结题，主持；

9.科技部973计划前期研究专项课题，2010CB434813 青藏高原冻土区典型冻融灾害的形成过程及危险性评估，2010/01-2012/12,17万元，结题，主持；

10.中国科学院知识创新工程重要方向性项目，KZCX2-YW-Q03-04，气候变化下冰川冻土灾害的成灾机理及危险性评价，2008/01-2011/12，170万元，结题，主持。