张甘霖
个人信息
姓名:张甘霖
职称:研究员
通讯地址:南京市北京东路73号
电话:025-86882005
传真:025-57714759
邮箱:glzhang@niglas.ac.cn
教育经历
1990年08月至1993年12月 中国科学院南京土壤研究所,土壤学专业,博士
1987年09月至1990年07月 中国科学院南京土壤研究所,土壤学专业,硕士
1983年09月至1987年07月 华中农业大学,土壤与农业化学专业,学士
工作经历
2019年05月至今: 中国科学南京地理与湖泊研究所,研究员
2001年05月至2019年05月 中国科学院南京土壤研究所,研究员
研究领域
土壤发生、土壤分类、土壤制图和资源评价、城市土壤
荣誉及奖项
[1] 2004年:海南省土壤—地体数字化数据库系统建立及其在海南土地资源持续管理中的应用:科技进步(省部二等奖),海南省人民政府,排名:2
[2] 2005年:香港土壤及其环境研究:科技进步奖,中华人民共和国环境保护部,排名:4
[3] 2005年:中国土壤系统分类研究:自然科学-国家二等奖,中华人民共和国国务院,排名:6
[4] 2008年:海南省土壤—地体数字化数据库系统建立及其在海南土地资源可持续管理中的应用:科技进步奖,中华人民共和国农业部,排名:2
[5] 2018年:《寂静的土壤》:2017年中国科学院优秀科普图书,中国科学院科学传播局,排名:2
[6] 2018年:《土壤与邮文化:土壤与环境》:第九届江苏省优秀科普作品-三等奖,江苏省科学技术协会,排名:2
[7] 2018年:《寂静的土壤》:2018年度江苏省科学技术奖(科普类),江苏省人民政府,排名:3
科研项目
[1] 国家自然科学基金重点项目:黑河流域关键土壤属性数字制图研究,2012.01-2016.12,项目编号:41130530(主持)
[2] 国家自然科学基金-重大研究计划-集成项目,黑河流域土壤数据集成与土壤信息产品生成,2014.01-2017.12,项目编号:91325301(主持)
[3] 科技基础性工作专项,我国土系调查与《中国土系志(中西部卷)》编制,2014.05-2018.12,项目编号:2014FY110200(主持)
[4] 国家自然科学基金项目-英国牛顿基金会重大国际合作项目,红壤关键带土壤风化与形成的关键过程、速率及其驱动机制,2016.01-2019.12,项目编号:41571130051(主持)
[5] 中国科学院科技服务网络计划(STS),土壤污染风险评价与场地污染修复,2018.01-2019.06,项目编号:KFJ-STS-ZDTP-039(主持)
[6] 中国工程院咨询研究项目,长三角农用地土壤污染风险及防治对策研究(课题四:长三角农用地土壤污染数据库),2019.03-2021.03,项目编号:2019-XZ-24(参与)
[7] 国家重点研发计划政府间国际科技创新合作重点专项项目,土壤综合观测与智能服务平台研发与应用,2019.08-2022.06,项目编号:2018YFE0107000(主持)
[8] 第二次青藏高原综合科学考察研究,土壤质量变化及其对生态系统的影响(课题一:土壤类型调查与制图),2019.11-2022.10,项目编号:2019QZKK0306(参与)
[9] 中国科学院科技创新重点部署项目,法庭土壤物证精准溯源技术与应用,2019.01-2021.12,项目编号:KGFZD-135-19-10(主持)
代表论著
一、期刊论文
1.1 英文论文
[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]Ding, Jinzhi, Wang, Tao, Piao, Shilong, Smith, Pete, Zhang, Ganlin, Yan, Zhengjie, Ren, Shuai, Liu, Dan, Wang, Shiping, Chen, Shengyun, Dai, Fuqiang, He, Jinsheng, Li, Yingnian, Liu, Yongwen, Mao, Jiafu, Arain, Altaf, Tian, Hanqin, Shi, Xiaoying, Yang, Yuanhe, Zeng, Ning, Zhao, Lin. 2019. The paleoclimatic footprint in the soil carbon stock of the Tibetan permafrost region. Nature Communications, 10.
[20]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.
[21]Tian, Liming, Zhao, Lin, Wu, Xiaodong, Fang, Hongbing, Zhao, Yonghua, Hu, Guojie, Yu, Guangyang, Sheng, Yu, Wu, Jichun, Chen, Ji, Wang, Zhiwei, Li, Wangping, Zou, Defu, Ping, Chien-Lu, Shang, Wen, Zhao, Yuguo, Zhang, Ganlin. 2018. Soil moisture and texture primarily control the soil nutrient stoichiometry across the Tibetan grassland. Science of the Total Environment, 622: 192-202.
[22]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.
[23]Richter, Daniel D., Billings, Sharon A., Groffman, Peter M., Kelly, Eugene F., Lohse, Kathleen A., McDowell, William H., White, Timothy S., Anderson, Suzanne, Baldocchi, Dennis D., Banwart, Steve, Brantley, Susan, Braun, Jean J., Brecheisen, Zachary S., Cook, Charles W., Hartnett, Hilairy E., Hobbie, Sarah E., Gaillardet, Jerome, Jobbagy, Esteban, Jungkunst, Hermann F., Kazanski, Clare E., Krishnaswamy, Jagdish, Markewitz, Daniel, O'Neill, Katherine, Riebe, Clifford S., Schroeder, Paul, Siebe, Christina, Silver, Whendee L., Thompson, Aaron, Verhoef, Anne, Zhang, Ganlin. 2018. Ideas and perspectives: Strengthening the biogeosciences in environmental research networks. Biogeosciences, 15: 4815-4832.
[24]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.
[25]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.
[26]Liu, Yi, Shi, Zhou, Zhang, Ganlin, Chen, Yiyun, Li, Shuo, Hong, Yongshen, Shi, Tiezhu, Wang, Junjie, Liu, Yaolin. 2018. Application of Spectrally Derived Soil Type as Ancillary Data to Improve the Estimation of Soil Organic Carbon by Using the Chinese Soil Vis-NIR Spectral Library. Remote sensing, 10.
[27]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.
[28]Huang, Laiming, Jia, Xiaoxu, Shao, Ming'an, Chen, Liumei, Han, Guangzhong, Zhang, Ganlin. 2018. Phases and rates of iron and magnetism changes during paddy soil development on calcareous marine sediment and acid Quaternary red-clay. Scientific Reports.
[29]Zhi Junjun, Zhang Ganlin, Yang Renmin, Yang Fei, Jin Chengwei, Liu Feng, Song Xiaodong, Zhao Yuguo, Li Decheng. 2018. An Insight into Machine Learning Algorithms to Map the Occurrence of the Soil Mattic Horizon in the Northeastern Qinghai-Tibetan Plateau. Pedosphere, 28: 739-750.
[30]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.
[31]Yang Fan, Huang Laiming, Yang Renmin, Yang Fei, Li Decheng, Zhao Yuguo, Yang Jinling, Liu Feng, Zhang Ganlin. 2018. Vertical distribution and storage of soil organic and inorganic carbon in a typical inland river basin, Northwest China. Journal of Arid Land, 10: 183-201.
[32]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.
[33]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.
[34]Rossiter, David G., Zeng, Rong, Zhang, Gan-Lin. 2017. Accounting for taxonomic distance in accuracy assessment of soil class predictions. Geoderma, 292: 118-127.
[35]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.
[36]Zhi, Junjun, Zhang, Ganlin, Yang, Fei, Yang, Renmin, Liu, Feng, Song, Xiaodong, Zhao, Yuguo, Li, Decheng. 2017. Predicting mattic epipedons in the northeastern Qinghai-Tibetan Plateau using Random Forest. Geoderma Regional, 10: 1-10.
[37]Yang Lin, Zhu, A-Xing, Zhao Yuguo, Li Decheng, Zhang Ganlin, Zhang Shujie, Band, Lawrence E. 2017. Regional Soil Mapping Using Multi-Grade Representative Sampling and a Fuzzy Membership-Based Mapping Approach. Pedosphere, 27: 344-357.
[38]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.
[39]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.
[40]Song Xiaodong, Liu Feng, Zhang Ganlin, Li Decheng, Zhao Yuguo, Yang Jinling. 2017. Mapping Soil Organic Carbon Using Local Terrain Attributes: A Comparison of Different Polynomial Models. Pedosphere, 27: 681-693.
[41]Yang, F., Huang, L. M., Rossirter, D. G., Yang, F., Yang, R. M., Zhang, G. L. 2017. Evolution of loess-derived soil along a climatic toposequence in the Qilian Mountains, NE Tibetan Plateau. European Journal of Soil Science, 68: 270-280.
[42]Guo Naijia, Shi Xuezheng, Zhao Yongcun, Xu Shengxiang, Wang Meiyan, Zhang Ganlin, Wu Jinshui, Huang Biao, Kong Chao. 2017. Environmental and Anthropogenic Factors Driving Changes in Paddy Soil Organic Matter: A Case Study in the Middle and Lower Yangtze River Plain of China. Pedosphere, 27: 926-937.
[43]Ju Bing, Wu Kening, Zhang Ganlin, Rossiter, David G., Li Ling. 2017. Characterization of Some Calcareous Soils from Henan and Their Proposed Classification in Chinese Soil Taxonomy. Pedosphere, 27: 758-768.
[44]Feng, Youzhi, Dolfing, Jan, Guo, Zhiying, Zhang, Jianwei, Zhang, Ganlin, Li, Shijie, Lin, Xiangui. 2017. Chronosequencing methanogenic archaea in ancient Longji rice Terraces in China. Science Bulletin, 62: 879-887.
[45]Song Xiaodong, Liu Feng, Ju Bing, Zhi Junjun, Li Decheng, Zhao Yuguo, Zhang Ganlin. 2017. Mapping soil organic carbon stocks of northeastern China using expert knowledge and GIS-based methods. Chinese Geographical Science, 27: 516-528.
[46]Yang, Ren-Min, Zhang, Gan-Lin, Liu, Feng, Lu, Yuan-Yuan, Yang, Fan, Yang, Fei, Yang, Min, Zhao, Yu-Guo, Li, De-Cheng. 2016. Comparison of boosted regression tree and random forest models for mapping topsoil organic carbon concentration in an alpine ecosystem. Ecological Indicators, 60: 870-878.
[47]Montanarella, Luca, Pennock, Daniel Jon, McKenzie, Neil, Badraoui, Mohamed, Chude, Victor, Baptista, Isaurinda, Mamo, Tekalign, Yemefack, Martin, Aulakh, Mikha Singh, Yagi, Kazuyuki, Hong, Suk Young, Vijarnsorn, Pisoot, Zhang, Gan-Lin, Arrouays, Dominique, Black, Helaina, Krasilnikov, Pavel, Sobocka, Jaroslava, Alegre, Julio, Henriquez, Carlos Roberto, Mendonca-Santos, Maria de Lourdes, Taboada, Miguel, Espinosa-Victoria, David, AlShankiti, Abdullah, AlaviPanah, Sayed Kazem, Elsheikh, Elsiddig Ahmed El Mustafa, Hempel, Jon, Arbestain, Marta Camps, Nachtergaele, Freddy, Vargas, Ronald. 2016. World's soils are under threat. Soil, 2: 79-82.
[48]Song, Xiao-Dong, Brus, Dick J., Liu, Feng, Li, De-Cheng, Zhao, Yu-Guo, Yang, Jin-Ling, Zhang, Gan-Lin. 2016. Mapping soil organic carbon content by geographically weighted regression: A case study in the Heihe River Basin, China. Geoderma, 261: 11-22.
[49]Wu, Xiaodong, Zhao, Lin, Fang, Hongbing, Zhao, Yuguo, Smoak, Joseph M., Pang, Qiangqiang, Ding, Yongjian. 2016. Environmental controls on soil organic carbon and nitrogen stocks in the high-altitude arid western Qinghai-Tibetan Plateau permafrost region. Journal of Geophysical Research-Biogeosciences, 121: 176-187.
[50]Yang, Ren-Min, Zhang, Gan-Lin, Yang, Fei, Zhi, Jun-Jun, Yang, Fan, Liu, Feng, Zhao, Yu-Guo, Li, De-Cheng. 2016. Precise estimation of soil organic carbon stocks in the northeast Tibetan Plateau. Scientific Reports, 6.
[51]Song Xiaodong, Zhang Ganlin, Liu Feng, Li Decheng, Zhao Yuguo, Yang Jinling. 2016. Modeling spatio-temporal distribution of soil moisture by deep learning-based cellular automata model. Journal of Arid Land, 8: 734-748.
[52]Brus, D. J., Yang, Ren-Min, Zhang, Gan-Lin. 2016. Three-dimensional geostatistical modeling of soil organic carbon: A case study in the Qilian Mountains, China. Catena, 141: 46-55.
[53]Zeng, Rong, Zhang, Gan-Lin, Li, De-Cheng, Rossiter, David G., Zhao, Yu-Guo. 2016. How well can VNIR spectroscopy distinguish soil classes? Biosystems Engineering, 152: 117-125.
[54]Zeng, Rong, Zhao, Yu-Guo, Li, De-Cheng, Wu, Deng-Wei, Wei, Chang-Long, Zhang, Gan-Lin. 2016. Selection of Local Models for Prediction of Soil Organic Matter Using a Regional Soil Vis-NIR Spectral Library. Soil Science, 181: 13-19.
[55]Liu, Feng, Rossiter, David G., Song, Xiao-Dong, Zhang, Gan-Lin, Yang, Ren-Min, Zhao, Yu-Guo, Li, De-Cheng, Ju, Bing. 2016. A similarity-based method for three-dimensional prediction of soil organic matter concentration. Geoderma, 263: 254-263.
[56]Yang, Fei, Zhang, Gan-Lin, Yang, Fan, Yang, Ren-Min. 2016. Pedogenetic interpretations of particle-size distribution curves for an alpine environment. Geoderma, 282: 9-15.
[57]Lehndorff, E., Houtermans, M., Winkler, P., Kaiser, K., Koelbl, A., Romani, M., Said-Pullicino, D., Utami, S. R., Zhang, G. L., Cao, Z. H., Mikutta, R., Guggenberger, G., Amelung, W. 2016. Black carbon and black nitrogen storage under long-term paddy and non-paddy management in major reference soil groups. Geoderma, 284: 214-225.
[58]Yang, Jin-Ling, Zhang, Gan-Lin, Yang, Fei, Yang, Ren-Min, Yi, Chen, Li, De-Cheng, Zhao, Yu-Guo, Liu, Feng. 2016. Controlling effects of surface crusts on water infiltration in an arid desert area of Northwest China. Journal of Soils and Sediments, 16: 2408-2418.
[59]Lu, Ying, Jia, Chongjian, Zhang, Ganlin, Zhao, Yuguo, Wilson, Michael A. 2016. Spatial distribution and source of potential toxic elements (PTEs) in urban soils of Guangzhou, China. Environmental Earth Sciences, 75.
[60]Song, Xiao-Dong, Liu, Feng, Zhang, Gan-Lin, Li, De-Cheng, Zhao, Yu-Guo. 2016. Estimation of Soil Texture at a Regional Scale Using Local Soil-Landscape Models. Soil Science, 181: 435-445.
[61]Li, Jianwu, Zhang, Ganlin, Ruan, Li, Yang, Jinlin, Wang, Hailong. 2016. Sr-Nd elements and isotopes as tracers of dust input in a tropical soil chronosequence. Geoderma, 262: 227-234.
[62]Liu Feng, Geng Xiaoyuan, Zhu A-xing, Fraser, Walter, Song Xiaodong, Zhang Ganlin. 2016. Soil polygon disaggregation through similarity-based prediction with legacy pedons. Journal of Arid Land, 8: 760-772.
[63]Huang, Lai-Ming, Zhang, Xin-Hui, Shao, Ming-An, Rossiter, David, Zhang, Gan-Lin. 2016. Pedogenesis significantly decreases the stability of water-dispersible soil colloids in a humid tropical region. Geoderma, 274: 45-53.
[64]Li Shanquan, Zhang Ganlin, Yang Jinling, Jia Nan. 2016. Multi-Source Characteristics of Atmospheric Deposition in Nanjing, China, as Controlled by East Asia Monsoons and Urban Activities. Pedosphere, 26: 374-385.
[65]Wang, De-Cai, Zhang, Gan-Lin, Rossiter, David G., Zhang, Jun-Hui. 2016. The Prediction of Soil Texture from Visible-Near-Infrared Spectra under Varying Moisture Conditions. Soil Science Society of America Journal, 80: 420-427.
[66]Song, Xiao-Dong, Zhang, Gan-Lin, Liu, Feng, Li, De-Cheng, Zhao, Yu-Guo. 2016. Characterization of the spatial variability of soil available zinc at various sampling densities using grouped soil type information. Environmental Monitoring and Assessment, 188.
[67]Zuo Shuangmiao, Yang Jinling, Huang Laiming, Rossiter, David G., Zhang Ganlin. 2016. Assessment of Plant-Driven Mineral Weathering in an Aggrading Forested Watershed in Subtropical China. Pedosphere, 26: 817-828.
[68]Yang Renmin, Liu Feng, Zhang Ganlin, Zhao Yuguo, Li Decheng, Yang Jinling, Yang Fei, Yang Fan. 2016. Mapping Soil Texture Based on Field Soil Moisture Observations at a High Temporal Resolution in an Oasis Agricultural Area. Pedosphere, 26: 699-708.
[69]Huang, Lai-Ming, Thompson, Aaron, Zhang, Gan-Lin, Chen, Liu-Mei, Han, Guang-Zhong, Gong, Zi-Tong. 2015. The use of chronosequences in studies of paddy soil evolution: A review. Geoderma, 237: 199-210.
[70]Burghardt, Wolfgang, Morel, Jean Louis, Zhang, Gan-Lin. 2015. Development of the soil research about urban, industrial, traffic, mining and military areas (SUITMA). Soil Science and Plant Nutrition, 61: 3-21.
[71]Yang, Jin-Ling, Zhang, Gan-Lin. 2015. Formation, characteristics and eco-environmental implications of urban soils - A review. Soil Science and Plant Nutrition, 61: 30-46.
[72]Yang, Renmin, Rossiter, David G., Liu, Feng, Lu, Yuanyuan, Yang, Fan, Yang, Fei, Zhao, Yuguo, Li, Decheng, Zhang, Ganlin. 2015. Predictive Mapping of Topsoil Organic Carbon in an Alpine Environment Aided by Landsat TM. Plos One, 10.
[73]Wang, De-Cai, Zhang, Gan-Lin, Zhao, Ming-Song, Pan, Xian-Zhang, Zhao, Yu-Guo, Li, De-Cheng, Macmillan, Bob. 2015. Retrieval and Mapping of Soil Texture Based on Land Surface Diurnal Temperature Range Data from MODIS. Plos One, 10.
[74]Hu, Xue-Feng, Du, Yan, Liu, Xiang-Jun, Zhang, Gan-Lin, Jiang, Ying, Xue, Yong. 2015. Polypedogenic case of loess overlying red clay as a response to the Last Glacial-Interglacial cycle in mid-subtropical Southeast China. Aeolian Research, 16: 125-142.
[75]Chen, L. M., Zhang, G. L., Rossiter, D. G., Cao, Z. H. 2015. Magnetic depletion and enhancement in the evolution of paddy and non-paddy soil chronosequences. European Journal of Soil Science, 66: 886-897.
[76]Han, Guang-Zhong, Zhang, Gan-Lin, Li, De-Cheng, Yang, Jin-Ling. 2015. Pedogenetic evolution of clay minerals and agricultural implications in three paddy soil chronosequences of south China derived from different parent materials. Journal of Soils and Sediments, 15: 423-435.
[77]Zhao, M.S., Zhang, G.L., Wu, Y.J., Li, D.C., Zhao, Y.G. 2015. Driving forces of soil organic matter change in Jiangsu Province of China. Soil Use and Management, 31: 440-449.
[78]Sun, X.L., Wu, Y.J., Lou, Y.L., Wang, H.L., Zhang, C., Zhao, Y.G., Zhang, G.L. 2015. Updating digital soil maps with new data: a case study of soil organic matter in Jiangsu, China. European Journal of Soil Science, 66: 1012-1022.
[79]Huang, Lai-Ming, Yang, Jin-Ling, Thompson, Aaron, Rossiter, David G., Zuo, Shuang-Miao, Zhang, Gan-Lin. 2015. Proton production from nitrogen transformation drives stream export of base cations in acid-sensitive forested watersheds. Ecological Indicators, 48: 348-357. [80]Wu Deng-Wei, Zhang Gan-Lin. 2015. Study on Paddy Soil Chronosequences Based on Visiblc-Near Infrared Diffuse Reflectance Spectra. Spectroscopy and Spectral Analysis, 35: 3375-3381.
1.2 中文论文
[1]张甘霖, 王秋兵, 我国土壤资源特点与土壤安全利用, 2015, 中国科学院院刊, 30卷: 53-60
[2]张甘霖, 吴华勇.从问题到解决方案: 土壤与可持续发展目标的实现.中国科学院院刊, 2018, (02), 124-134.
[3]张甘霖, 朱阿兴, 史舟, 王秋兵, 刘宝元, 张兴昌, 史志华, 杨金玲, 刘峰, 宋效东, 吴华勇, 曾荣.土壤地理学的进展与展望.地理科学进展, 2018, 37, 57-65.
二、专著
[1]Zhang Gan-Lin, Brus Dick, Liu Feng, Song Xiao-Dong, Lagacherie Philippe. Digital Soil Mapping Across Paradigms, Scales and Boundaries. Springer, 2016.2.16
[2]张甘霖(总主编),中国土系志,2017,2020,科学出版社
[3]龚子同, 陈鸿昭, 张甘霖. 寂静的土壤. 科学出版社. 北京. 2017