张甘霖
张甘霖 男,1966年生,研究员,博士生导师 电 话:025-86882002 E-mail:glzhang@niglas.ac.cn 传 真:025-57714759 |
研究领域及方向:土壤与环境变化、数字土壤制图、关键带科学
简历:
张甘霖,男,1966年生,博士,研究员,博士生导师。 1987年毕业于华中农业大学土化系,获农学学士学位;1990年和1993年在中国科学院土壤研究所分别获得理学硕士和博士学位。1994-1995年在德国基尔大学从事土壤空间变异和土壤地理信息系统研究,1998年和2000年在德国埃森大学生态研究所从事城市土壤研究。2001年晋升为研究员,2006年获国家自然科学杰出青年基金资助。入选江苏省“333”人才第二层次培养对象,江苏省有突出贡献中青年专家,享受国务院政府特殊津贴,国家自然科学基金学科评审组专家。曾任中国土壤学会常务理事、秘书长,国际土壤科学联合会土壤发生委员会主席,FAO“政府间土壤专家小组”(ITPS)成员。是《Geoderma》、《中国科学-地球科学》、《National Science Review》等杂志编委。曾获国家自然科学二等奖和多个省部级科技奖。 长期从事土壤发生、土壤系统分类、数字土壤制图和土壤资源评价研究,近年来致力于地球关键带科学研究。近年来主持了国家自然科学基金重大国际合作项目“红壤关键带过程与水土资源可持续利用”、国家重点研发计划项目(中欧国际Horizon2020)“土壤综合观测与智能服务平台研发与应用”、科技部基础性工作专项“我国土系调查与《中国土系志》编制”、科技部国际科技合作专项“全球数字土壤制图东亚区合作研究”等多个重大和重点项目。已发表论文300余篇,其中SCI论文150多篇,出版专著多部。 招收具有土壤学、环境科学、地球化学、自然地理、遥感与地理信息系统等专业背景的硕士和博士研究生。
代表性论著:
一、期刊论文 [1]Wu, Huayong, Adams, Jonathan M., Shi, Yu, Li, Yuntao, Song, Xiaodong, Zhao, Xiaorui, Chu, Haiyan, Zhang, Gan-Lin. 2020. Depth-Dependent Patterns of Bacterial Communities and Assembly Processes in a Typical Red Soil Critical Zone. Geomicrobiology Journal, 37: 201-212. [2]Song XD, Liu F, Wu HY, Cao Q, Zhong C, Yang JL, Li DC, Zhao YG, Zhang GL. 2020. Effects of long-term K fertilization on soil available potassium in East China. Catena, 188: 104412. [3]Song XD, Wu HY, Ju B, Liu F, Yang F, Li DC, Zhao YG, Yang JL, Zhang GL, 2020. Pedoclimatic zone-based three-dimensional soil organic carbon mapping in China. Geoderma, 363: 114145. [4]Cao Q, Song XD, Wu HY, Gao L, Liu F, Yang SH, Zhang, GL, 2020. Mapping the response of volumetric soil water content to 1 an intense rainfall event at the field scale using GPR. Journal of Hydrology, 583: 124605. [5]Song XD, Wu HY, Hallett PD, Pan XC, Hu XF, Cao Q, Zhao XR, Zhang GL, 2020. Paleotopography continues to drive surface to deep-layer interactions in a subtropical Critical Zone Observatory. Journal of Applied Geophysics, 175: 103987. [6]Liu Feng, Rossiter David G., Song Xiaodong, Zhang Gan-Lin, Wu Huayong, Zhao Yuguo, 2020. An approach for broad-scale predictive soil properties mapping in low-relief areas based on responses to solar radiation. Soil Sci. Soc. Am. J., 84: 144-162. [7]Chen, Songchao, Liang, Zongzheng, Webster, Richard, Zhang, Ganlin, Zhou, Yin, Teng, Hongfen, Hu, Bifeng, Arrouays, Dominique, Shi, Zhou. 2019. A high-resolution map of soil pH in China made by hybrid modelling of sparse soil data and environmental covariates and its implications for pollution. Science of the Total Environment, 655: 273-283. [8]Wu, Huayong, Song, Xiaodong, Zhao, Xiaorui, Peng, Xinhua, Zhou, Hu, Hallett, Paul D., Hodson, Mark E., Zhang, Gan-Lin. 2019. Accumulation of nitrate and dissolved organic nitrogen at depth in a red soil Critical Zone. Geoderma, 337: 1175-1185. [9]Zhao, Xiao-Rui, Wu, Hua-Yong, Song, Xiao-Dong, Yang, Shun-Hua, Dong, Yue, Yang, Jin-Ling, Zhang, Gan-Lin. 2019. Intra-horizon differentiation of the bacterial community and its co-occurrence network in a typical Plinthic horizon. Science of the Total Environment, 678: 692-701. [10]Lu Yuan-Yuan, Liu Feng, Zhao Yu-Guo, Song Xiao-Dong, Zhang Gan-Lin. 2019. An integrated method of selecting environmental covariates for predictive soil depth mapping. Journal of Integrative Agriculture, 18: 301-315. [11]Yang, Shun-Hua, Liu, Feng, Song, Xiao-Dong, Lu, Yuan-Yuan, Li, De-Cheng, Zhao, Yu-Guo, Zhang, Gan-Lin. 2019. Mapping topsoil electrical conductivity by a mixed geographically weighted regression kriging: A case study in the Heihe River Basin, northwest China. Ecological Indicators, 102: 252-264. [12]Song, Xiao-Dong, Wu, Hua-Yong, Liu, Feng, Tian, Jian, Cao, Qi, Yang, Shun-Hua, Peng, Xin-Hua, Zhang, Gan-Lin. 2019. Three-Dimensional Mapping of Organic Carbon using Piecewise Depth Functions in the Red Soil Critical Zone Observatory. Soil Science Society of America Journal, 83: 687-696. [13]Yang, Jin-Ling, Zhang, Gan-Lin. 2019. Si cycling and isotope fractionation: Implications on weathering and soil formation processes in a typical subtropical area. Geoderma, 337: 479-490. [14]Liu, S., Zhang, Z. B., Li, D. M., Hallett, P. D., Zhang, G. L., Peng, X. H. 2019. Temporal dynamics and vertical distribution of newly-derived carbon from a C-3/C-4 conversion in an Ultisol after 30-yr fertilization. Geoderma, 337: 1077-1085. [15]Zeng, R., Rossiter, D. G., Zhang, G. L. 2019. How compatible are numerical classifications based on whole-profile vis-NIR spectra and the Chinese Soil Taxonomy? European Journal of Soil Science, 70: 54-65. [16]Zhang, Ganlin, Zhu, Yongguan, Shao, Ming'an. 2019. Understanding sustainability of soil and water resources in a critical zone perspective. Science China-Earth Sciences, 62: 1716-1718. [17]Wu, Huayong, Song, Xiaodong, Zhao, Xiaorui, Zhang, Gan-Lin. 2019. Conversion from Upland to Paddy Field Intensifies Human Impacts on Element Behavior through Regolith. Vadose Zone Journal, 18. [18]Hu, Xue-Feng, Zhao, Jing-Long, Zhang, Pei-Feng, Xue, Yong, An, Bo-Nian, Huang, Fang, Yu, Hui-Min, Zhang, Gan-Lin, Liu, Xiang-Jun. 2019. Fe isotopic composition of the Quaternary Red Clay in subtropical Southeast China: Redoxic Fe mobility and its paleoenvironmental implications. Chemical Geology, 524: 356-367. [19] Song, Xiao-Dong, Yang, Jian-Yi, Zhao, Ming-Song, Zhang, Gan-Lin, Liu, Feng, Wu, Hua-Yong. 2019. Heuristic cellular automaton model for simulating soil organic carbon under land use and climate change: A case study in eastern China. Agriculture Ecosystems & Environment, 269: 156-166. [20] Song, Xiao-Dong, Yang, Fan, Ju, Bing, Li, De-Cheng, Zhao, Yu-Guo, Yang, Jin-Ling, Zhang, Gan-Lin. 2018. The influence of the conversion of grassland to cropland on changes in soil organic carbon and total nitrogen stocks in the Songnen Plain of Northeast China. Catena, 171: 588-601. [21]Yang, Jin-Ling, Zhang, Gan-Lin. 2018. Silicon cycling by plant and its effects on soil Si translocation in a typical subtropical area. Geoderma, 310: 89-98. [22]Huang, Lai-Ming, Jia, Xiao-Xu, Zhang, Gan-Lin, Thompson, Aaron, Huang, Fang, Shao, Min-An, Chen, Liu-Mei. 2018. Variations and controls of iron oxides and isotope compositions during paddy soil evolution over a millennial time scale. Chemical Geology, 476: 340-351. [23] Huang, Lai-Ming, Shao, Min-An, Huang, Fang, Zhang, Gan-Lin. 2018. Effects of human activities on pedogenesis and iron dynamics in paddy soils developed on Quaternary red clays. Catena, 166: 78-88. [24] Zhao, Yongcun, Wang, Meiyan, Hu, Shuijin, Zhang, Xudong, Ouyang, Zhu, Zhang, Ganlin, Huang, Biao, Zhao, Shiwei, Wu, Jinshui, Xie, Deti, Zhu, Bo, Yu, Dongsheng, Pan, Xianzhang, Xu, Shengxiang, Shi, Xuezheng. 2018. Economics- and policy-driven organic carbon input enhancement dominates soil organic carbon accumulation in Chinese croplands. PNAS, 115: 4045-4050. [25]Zhang Gan-lin, Liu Feng, Song Xiao-dong. 2017. Recent progress and future prospect of digital soil mapping: A review. Journal of Integrative Agriculture, 16: 2871-2885. [26]Huang, Lai-Ming, Jia, Xiao-Xu, Zhang, Gan-Lin, Shao, Min-An. 2017. Soil organic phosphorus transformation during ecosystem development: A review. Plant and Soil, 417: 17-42. [27]Rossiter, David G., Zeng, Rong, Zhang, Gan-Lin. 2017. Accounting for taxonomic distance in accuracy assessment of soil class predictions. Geoderma, 292: 118-127. [28]Sun, Xiao-Lin, Wang, Hui-Li, Zhao, Yu-Guo, Zhang, Chaosheng, Zhang, Gan-Lin. 2017. Digital soil mapping based on wavelet decomposed components of environmental covariates. Geoderma, 303: 118-132. [29]Yang, Ren-Min, Yang, Fan, Yang, Fei, Huang, Lai-Ming, Liu, Feng, Yang, Jin-Ling, Zhao, Yu-Guo, Li, De-Cheng, Zhang, Gan-Lin. 2017. Pedogenic knowledge-aided modelling of soil inorganic carbon stocks in an alpine environment. Science of the Total Environment, 599: 1445-1453. [30]Zeng, Rong, Rossiter, David G., Yang, Fan, Li, De-Cheng, Zhao, Yu-Guo, Zhang, Gan-Lin. 2017. How accurately can soil classes be allocated based on spectrally predicted physio-chemical properties? Geoderma, 303: 78-84. 二.专著 张甘霖(总主编),中国土系志,2017,2020,科学出版社