基本介绍

张海成，副教授，博士生导师，国家级青年人才项目获得者，中山大学 “百人计划”引进人才，逸仙学者计划“优秀学者”。主要从事全球变化和陆地生态系统碳循环研究，具体研究内容集中于：1）土壤侵蚀、淋溶、风化驱动的陆地-河流-海洋间碳、水、养分元素迁移及其环境效应；2）植物凋落物和土壤有机质分解转化；3）植物物候、生产力等对气候变化的响应。主持国家级青年人才项目、国家自然科学青年基金项目、广东省面上项目、广州市基础与应用基础项目、比利时国家科学基金青年项目各一项，并参与多项国家基金委项目和欧盟重大科研项目。研究成果以第一作者身份发表在Nature Climate Change、 Communications Earth & Environment、Global Change Biology等国际知名期刊。

加入我们 【BGMM-lab】BioGeochemical Monitoring & Modelling

欢迎对气候变化和生物地球化学循环研究感兴趣的同学加入本课题组攻读硕、博研究生。

诚邀有志于从事气候变化和碳、水、养分循环等相关研究的博士毕业生加入本团队从事博士后研究。

联系人：张海成                      联系邮箱：zhanghch59@mail.sysu.edu.cn

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本课题组氛围轻松活泼，秉持勤奋务实、探索创新的理念，勇攀科研高峰！

本课题组正在承担多个国家和省部级项目，可为研究生与博后提供良好的学习与科研环境。同时，本课题组与国内外顶尖研究团队有长期密切合作，可提供国际交流和学习访问机会。

研究方向

全球变化与陆地生态系统碳循环；生物地球化学循环；地表过程模型开发与应用；植物物候

学历背景

2015.9–2016.9：公派留学，比利时布鲁塞尔(法语)自由大学 (ULB), 地球环境科学系 （合作导师：Pierre Regnier教授）

2012.9–2017.7：博士，北京师范大学，全球环境变化专业 （导师：袁文平教授）

2008.9–2012.7：本科，中山大学，地理科学专业

工作经历

2019.10–2022.11：博士后研究员/助教，比利时布鲁塞尔(法语)自由大学 (ULB), 地球环境科学系 

                             （合作导师：Pierre Regnier教授，ULB地球环境科学系副主任，生物地球化学模拟实验室主任）

2017.10–2019.09：博士后研究员，法国气候与环境科学实验室(LSCE) 

                             （合作导师：Philippe Ciais教授，法国科学院院士、中国科学院外籍院士）

主讲课程

本科生课程：海岸带地理与环境、地球科学概论

研究生课程：全球变化与区域响应

科研项目

2025.01-2029.12：高寒草地碳通量对气候变暖的非线性响应机制及碳源汇反转风险，国家重点研发计划青年科学家项目，课题负责人

2024.12-2028.11：南岭山地生态系统恢复与生态安全保障技术，国家重点研发计划项目，课题负责人

2024.01-2026.12：国家级青年人才项目（海外），主持

2024.01-2026.12：华南典型陆地生态系统土壤有机碳组分及各组分的水热敏感性，国家自然科学基金青年项目，主持

2024.01-2026.12：珠江流域陆地-河流-海洋间碳迁移对流域碳平衡的影响，广东省自然科学基金面上项目，主持

2024.01-2025.12：气候变化背景下广州市陆地碳储量的时空变化及其驱动机制，广州市科技局基础与应用基础研究项目，主持

2024.01-2025.12：亚热带典型陆地生态系统土壤有机碳组分及其对气候变化的响应，广东省应用植物学重点实验室开放课题，主持

2019.10-2022.9：CNP-Lateral，比利时国家科学基金(FNRS)青年项目，主题：碳氮磷横向迁移对全球碳循环的影响 (24.5万欧元) ，主持

代表性论文

1.       Zhang, H*, Lauerwald, R., Ciais, P., Van Oost, K., Guenet, B., & Regnier, P. (2022). Global changes alter the amount and composition of land carbon deliveries to European rivers and seas. Communications Earth & Environment, 3(1), 245. (IF: 8.1)

2.       Zhang, H*, Chuine, I., Regnier, P., Ciais, P., & Yuan, W. (2022). Deciphering the multiple effects of climate warming on the temporal shift of leaf unfolding. Nature Climate Change, 12(2), 193-199. (IF: 29.6, Nature子刊)

3.       Zhang, H*, Lauerwald, R., Regnier, P., Ciais, P., Van Oost, K., Naipal, V., ... & Yuan, W. (2022). Estimating the lateral transfer of organic carbon through the European river network using a land surface model. Earth System Dynamics, 2022, 1-46.

4.       Zhang, H*, Lauerwald, R., Regnier, P., Ciais, P., Yuan, W., Naipal, V., ... & Camino‐Serrano, M. (2020). Simulating erosion‐induced soil and carbon delivery from uplands to rivers in a global land surface model. Journal of Advances in Modeling Earth Systems, 12(11), e2020MS002121.

5.       Zhang, H*, Goll, D. S., Wang, Y. P., Ciais, P., Wieder, W. R., Abramoff, R., ... & Tang, X. (2020). Microbial dynamics and soil physicochemical properties explain large‐scale variations in soil organic carbon. Global Change Biology, 26(4), 2668-2685.

6.       Zhang, H*, Goll, D. S., Manzoni, S., Ciais, P., Guenet, B., & Huang, Y. (2018). Modeling the effects of litter stoichiometry and soil mineral N availability on soil organic matter formation using CENTURY-CUE (v1. 0). Geoscientific Model Development, 11(12), 4779-4796.

7.       Zhang, H., Liu, S., Regnier, P., & Yuan, W. (2018). New insights on plant phenological response to temperature revealed from long‐term widespread observations in China. Global Change Biology, 24(5), 2066-2078.

8.       Zhang, H., Liu, D., Dong, W., Cai, W., & Yuan, W. (2016). Accurate representation of leaf longevity is important for simulating ecosystem carbon cycle. Basic and Applied Ecology, 17(5), 396-407.

9.       Zhang, H., Liu, S., Yuan, W., Dong, W., Xia, J., Cao, Y., & Jia, Y. (2016). Loess Plateau check dams can potentially sequester eroded soil organic carbon. Journal of Geophysical Research: Biogeosciences, 121(6), 1449-1455.

10.    Zhang, H., Yuan, W., Liu, S., & Dong, W. (2015). Divergent responses of leaf phenology to changing temperature among plant species and geographical regions. Ecosphere, 6(12), 1-8.

11.    Zhang, H., Yuan, W., Liu, S., Dong, W., & Fu, Y. (2015). Sensitivity of flowering phenology to changing temperature in China. Journal of Geophysical Research: Biogeosciences, 120(8), 1658-1665.

12.    Zhang, H., Yuan, W., Dong, W., & Liu, S. (2014). Seasonal patterns of litterfall in forest ecosystem worldwide. Ecological Complexity, 20, 240-247.

13.    Zhang, H., Liu, S., Yuan, W., Dong, W., Ye, A., Xie, X., ... & Mao, Y. (2014). Inclusion of soil carbon lateral movement alters terrestrial carbon budget in China. Scientific Reports, 4(1), 7247.

主要合作论文：

1.       He X, Abramoff RZ, Abs E, Georgiou K, Zhang H, Goll DS. Model uncertainty obscures major driver of soil carbon. Nature. 2024 Mar;627(8002):E1-E3. doi: 10.1038/s41586-023-06999-1. Epub 2024 Mar 6. PMID: 38448702.

2.       Mingkai Jiang … Zhang H. … et al. Carbon-phosphorus cycle models overestimate CO2 enrichment response in a mature Eucalyptus forest. Science Advances, 10,eadl5822(2024). DOI:10.1126/sciadv.adl5822

3.       Lu, H., Wang, X., Zhang, H., Xie, X., Nakhavali, M., Quine, T. A., et al. (2024). Soil organic carbon lateral movement processes integrated into a terrestrial ecosystem model. Journal of Advances in Modeling Earth Systems, 16, e2023MS003916.

4.       Han, M., Zhao, Q., Wang, X., Wang, Y. P., Ciais, P., Zhang, H., ... & Li, W. (2023). Modeling biochar effects on soil organic carbon on croplands in the MIMICS (MIcrobial-MIneral Carbon Stabilization) model. Geoscientific Model Development Discussions, 2023, 1-24.

5.       Goll, D. S., Bauters, M., Zhang, H., Ciais, P., Balkanski, Y., Wang, R., & Verbeeck, H. (2023). Atmospheric phosphorus deposition amplifies carbon sinks in simulations of a tropical forest in Central Africa. New Phytologist, 237(6), 2054-2068.

6.       Gommet, C., Lauerwald, R., Ciais, P., Guenet, B., Zhang, H., & Regnier, P. (2022). Spatiotemporal patterns and drivers of terrestrial dissolved organic carbon (DOC) leaching into the European river network. Earth System Dynamics, 13(1), 393-418.

7.       Abramoff, R. Z., Guenet, B., Zhang, H., Georgiou, K., Xu, X., Rossel, R. A. V., ... & Ciais, P. (2022). Improved global-scale predictions of soil carbon stocks with Millennial Version 2. Soil Biology and Biochemistry, 164, 108466.

8.       Yang, X., Wu, J., Chen, X., Ciais, P., Maignan, F., Yuan, W., Piao, S., Yang, S., Gong, F., Su, Y., Dai, Y., Liu, L., Zhang, H., ... & Wright, S. J. (2021). A comprehensive framework for seasonal controls of leaf abscission and productivity in evergreen broadleaved tropical and subtropical forests. The Innovation, 2(4).

9.       Chu, X., Man, R., Zhang, H., Yuan, W., Tao, J., & Dang, Q. L. (2021). Does climate warming favour early season species?. Frontiers in Plant Science, 12, 765351.

10.    Xu, Y., Ciais, P., Yu, L., Li, W., Chen, X., Zhang, H., ... & Gong, P. (2021). Oil palm modelling in the global land surface model ORCHIDEE-MICT. Geoscientific Model Development, 14(7), 4573-4592.

11.    Sun, Y., Goll, D. S., Chang, J., Ciais, P., Guenet, B., Helfenstein, J., ... & Zhang, H. (2021). Global evaluation of the nutrient-enabled version of the land surface model ORCHIDEE-CNP v1. 2 (r5986). Geoscientific Model Development, 14(4), 1987-2010.

12.    Wang, Y. P., Zhang, H., Ciais, P., Goll, D., Huang, Y., Wood, J. D., ... & Prescher, A. K. (2021). Microbial activity and root carbon inputs are more important than soil carbon diffusion in simulating soil carbon profiles. Journal of Geophysical Research: Biogeosciences, 126(4), e2020JG006205.

13.    Abramoff, R. Z., Georgiou, K., Guenet, B., Torn, M. S., Huang, Y., Zhang, H., ... & Ciais, P. (2021). How much carbon can be added to soil by sorption?. Biogeochemistry, 152(2), 127-142.

14.    Wu, D., Xu, X., & Zhang, H. (2021). Plant input does not exert stronger control on topsoil carbon persistence than climate in alpine grasslands. Ecology Letters, 24(11), 2526-2528.

15.    Huang, Y., Ciais, P., Goll, D. S., Sardans, J., Peñuelas, J., Cresto-Aleina, F., & Zhang, H. (2020). The shift of phosphorus transfers in global fisheries and aquaculture. Nature communications, 11(1), 355.

16.    Li, T., Zhang, H., Wang, X., Cheng, S., Fang, H., Liu, G., & Yuan, W. (2019). Soil erosion affects variations of soil organic carbon and soil respiration along a slope in Northeast China. Ecological Processes, 8, 1-10.

17.    Wang, X., Quine, T. A., Zhang, H., Tian, G., & Yuan, W. (2019). Redistribution of soil organic carbon induced by soil erosion in the nine river basins of China. Journal of Geophysical Research: Biogeosciences, 124(4), 1018-1031.