Dr. Guocheng Wang
LAPC, Institute of Atmospheric Physics, Chinese Academy of Sciences
Address: NO.40 Huayanli, Qijiahuozi, Institute of Atmospheric Physics, Chinese Academy of Sciences, LAPC (100029)
Email: wanggc@mail.iap.ac.cn
Research Areas
Modeling terrestrial ecosystem carbon and nitrogen processes
Education
2008/09 – 2013/06, University of the Chinese Academy of Sciences, Ph D.
Thesis title: Dynamics of Soil Organic Carbon in Chinese and Australian Agro-ecosystems
Majored in Atmospheric Physics & Enviornment
2011/10 – 2012/03, Land & Water, CSIRO, Australia, Visiting Student.
Main skills trained: Use of agricultural model (APSIM, an Australian biogeophysical model) to simulate both crop growth and soil nutrient processes from plot to regional scales.
2004/09 – 2008/06, Nanjing Agricultural University, BE.
Majored in Environmental Engineering
Experience
Work Experience
2013/07 – 2016.1, Research Associate, Institute of Atmospheric Physics, Chinese Academy of Sciences (IAP, CAS)
2016/02 – Present , Associate Professor, Institute of Atmospheric Physics, Chinese Academy of Sciences (IAP, CAS)
Publications
Papers
[1]. Wang, G., Luo, Z., Han, P., Chen, H. and Xu, J., 2016. Critical carbon input to maintain current soil organic carbon stocks in global wheat systems. Scientific reports, 6: 19327.
[2]. Wang, G., Huang, Y., Zhang, W., Yu, Y. and Sun, W., 2015. Quantifying carbon input for targeted soil organic carbon sequestration in China’s croplands. Plant Soil, 394(1): 57-71.
[3]. Wang, G., Huang, Y., Wang, E., Yu, Y. and Zhang, W., 2013. Modeling soil organic carbon change across Australian wheat growing areas, 1960–2010. PLoS ONE, 8(5): e63324.
[4]. Wang, G., Li, T., Zhang, W. and Yu, Y., 2014. Impacts of agricultural management and climate change on future soil organic carbon dynamics in North China Plain. PLoS ONE, 9(4): e94827.
[5]. Wang, G., Luo, Z., Wang, E. and Huang, Y., 2013. Contrasting effects of agricultural management on soil organic carbon balance in different agricultural regions of china. Pedosphere, 23(6): 717-728.
[6]. Wang, G., Wang, E., Huang, Y. and Xu, J., 2014. Soil carbon sequestration potential as affected by management practices in northern China: A simulation study. Pedosphere, 24(4): 529-543.
[7]. Wang, G., Xu, J., Li, T. and Zhang, W., 2015. Spatiotemporal changes in agricultural soil organic carbon across the North China Plain during 1980-2010. Climatic and Environmental Research, 20(5): 491-499 (in Chinese).
[8]. Wang, G., Zhang, W. and Huang, Y., 2011. Spatial and temporal variation of net primary productivity in Inner Mongolian grassland from 1981 to 2001. Pratacultural Science, 28(11): 2016-2025 (in Chinese).
[9]. Han, P., Zhang, W., Wang, G., Sun, W. and Huang, Y., 2016. Changes in soil organic carbon in croplands subjected to fertilizer management: a global meta-analysis. Scientific reports, 6: 27199.
[10]. Li, T., Zhang, Q., Cheng, Z., Ma, Z., Liu, J., Luo, Y., Xu, J., Wang, G., Zhang, W., 2016. Modeling CH4 Emissions from Natural Wetlands on the Tibetan Plateau over the Past 60 Years: Influence of Climate Change and Wetland Loss. Atmosphere 7, 90.
[11]. Li, T., Xie, B., Wang, G., Zhang, W., Zhang, Q., Vesala, T., Raivonen, M., 2016. Field-scale simulation of methane emissions from coastal wetlands in China using an improved version of CH4MOD wetland. Sci Total Environ 559, 256-267.
[12]. Li, T., Zhang, W., Zhang, Q., Lu, Y., Wang, G., Niu, Z., Raivonen, M., Vesala, T., 2015. Impacts of climate and reclamation on temporal variations in CH4 emissions from different wetlands in China: from 1950 to 2010. Biogeosciences 12, 6853-6868.