唐庄生

2020年06月05日 17:34 点击：[]

姓　　名：唐庄生
性　　别：男
学　　位：博士研究生

职　　务：副教授

学术兼职：
甘肃省生态学会理事，甘肃省草业科学学会理事
人才称号：
甘肃省“陇原青年英才”，甘肃农业大学“伏羲青年英才”。

教育访学经历

2013-2018年，西北农林科技大学，生态学专业，理学博士
2009-2013年，甘肃农业大学，草业科学专业，农学学士

研究方向

主要从事草地生态学研究，建设了全球生态联网实验天祝高山草原实验点，聚焦三个核心方向：(1) 生物互作网络：通过BugNet平台研究昆虫-植物-病原体互作及其对群落构建的影响；(2) 干扰-资源耦合：基于DRAGNet探讨物理干扰与养分动态对生态系统恢复力的调控；(3) 水肥协同效应：依托NutNet/Drought-Net揭示降水变化与养分富集的交互作用。

教学工作

主要承担本科生草地调查规划学》《草地调查规划学教学实习》等课程；承担研究生《草业信息处理技术与应用》等课程。

科研项目

（1）国家自然科学基金委青年基金项目“高原鼢鼠鼠丘斑块维持高寒草甸物种多样性的过程及机制研究” 2021 至 2023, 24万元, 结题, 主持；
（2）国家自然科学基金委地区基金项目“植物—土壤反馈在高原鼢鼠鼠丘次生演替群落构建中的作用机制” 2024 至 2027, 33万元, 在研, 主持；
（3）甘肃省科技厅杰出青年基金项目“高原鼢鼠干扰对高寒草甸土壤有机碳循环的驱动机制”2024至2027，35万元，在研，主持；
（4）甘肃省教育厅青年博士基金项目“青藏高原草地鼠害无人机监测技术及防控设备研发”2021至2023，8万元，结题，主持；
（5）甘肃省科技厅自然科学基金项目“基于高光谱数据的高寒草甸主要毒草分类技术研究”2021至2023，6万元，结题，主持；
（6）甘肃农业大学伏羲青年英才项目“草地鼠害无人机监测技术研发” 2021年-2025，15万元，在研，主持；
（7）甘肃农业大学公招博士启动基金“高寒草甸物种多样性及空间布对高原鼢鼠干扰的响应”2019至2022，20万元，结题，主持。

代表性成果

[1]Wang, X., Tang, Z*., Kang, X., He, N., & Li, M*. (2025). Climate Warming and Soil Drying Significantly Enhance the Methane Uptake in China’s Grasslands. Global Change Biology, 31(6).
[2]Zhang, X., Wang, Y., Chen, G., Yue, L., Wang, Z., Chen, X., Liao, K., Herath, S., & Tang, Z*. (2024). Plateau zokor disturbance enhances soil bacterial diversity and reduces network complexity. CATENA, 245, 108328.
[3]Zhang, X., Tang, Z*., Yang, J., Herath, S., Wang, Z., Wang, Y., Chen, G., & Yue, L. (2025). Plateau zokor disturbances transform the stability and functional characteristics of soil fungal communities. Geoderma, 455, 117232.
[4]An, H., Wu, X., Zhang, Y., & Tang, Z*. (2019). Effects of land-use change on soil inorganic carbon: A meta-analysis. Geoderma, 353, 273–282.
[5]Chen, J., Tang, Z*., Kang, X., He, N., & Li, M. (2025). Rise in wetland carbon uptake linked to increased potential evapotranspiration. Environmental Research, 279, 121778.
[6]Liang, B., Hao, Y*., Tang, Z*., He, N., & Li, M*. (2025). The significant role of vegetation activity in regulating wetland methane emission in China. Environmental Research, 268, 120773.
[7]Zhou, J., Yang, J*., Tang, Z*., Xue, L., Zhang, W., & Zhang, J. (2025). Driving mechanisms of ecosystem services and their trade-offs and synergies in the transition zone between the Qinghai-Tibet Plateau and the Loess Plateau. Ecological Indicators, 171, 113148.
[8]Tang, Z., An, H., Deng, L., Wang, Y., Zhu, G., & Shangguan, Z. (2016). Effect of desertification on productivity in a desert steppe. Scientific Reports, 6(1). https://doi.org/10.1038/srep27839
[9]Tang, Z., An, H., Zhu, G., & Shangguan, Z. (2018). Beta diversity diminishes in a chronosequence of desertification in a desert steppe. Land Degradation & Development, 29(3), 543–550.
[10]Tang, Z., Deng, L., An, H., & Shangguan, Z. (2017). Bayesian method predicts belowground biomass of natural grasslands. Écoscience, 1–10.
[11]Tang, Z., Deng, L., An, H., Yan, W., & Shangguan, Z. (2017). The effect of nitrogen addition on community structure and productivity in grasslands: A meta-analysis. Ecological Engineering, 99, 31–38.
[12]Tang, Z., Deng, L., Shangguan, Z., Wang, B., & An, H. (2019). Desertification and nitrogen addition cause species homogenization in a desert steppe ecosystem. Ecological Engineering, 138, 54–60.
[13]Tang, Z., Jiang, Y., Hua, R., Zhou, J., Chu, B., Ye, G., Hua, L., & Tian, Y. (2021). Study on Greenhouse Gas Emissions from the Mounds Produced by Plateau Zokor (Eospalax Baileyi) on Qinghai–Tibet Plateau. Rangeland Ecology & Management, 78, 36–45. https://doi.org/10.1016/j.rama.2021.05.002
[14]Tang, Z.-S., An, H., & Shangguan, Z.-P. (2015). The impact of desertification on carbon and nitrogen storage in the desert steppe ecosystem. Ecological Engineering, 84, 92–99.
[15]Deng, L., Shangguan, Z., Bell, S. M., Soromotin, A. V., Peng, C., An, S., Wu, X., Xu, X., Wang, K., Li, J., Tang, Z., Yan, W., Zhang, F., Li, J., Wu, J., & Kuzyakov, Y. (2023). Carbon in Chinese grasslands: Meta-analysis and theory of grazing effects. Carbon Research, 2(1).
[16]Fan, M., Li, J., Tang, Z., & Shangguan, Z. (2020). Soil bacterial community succession during desertification in a desert steppe ecosystem. Land Degradation & Development, 31(13), 1662–1674.
[17]Hua, R., Hua, L., Tang, Z., Dong, R., Bao, D., Ye, G., La, M., Sun, W., Zhang, Z., Wang, L., Dong, L., Cai, B., Chu, B., & Hao, Y. (2023). Maxent Modeling for Predicting Habitat Suitability and Potential Distribution of Plateau Pika (Ochotona curzoniae) on the Qinghai-Tibet Plateau, China. Rangeland Ecology & Management, 87, 34–43. https://doi.org/10.1016/j.rama.2022.11.010
[18]Niu, Y., Zhou, J., Yang, S., Chu, B., Zhu, H., Zhang, B., Fang, Q., Tang, Z., & Hua, L. (2019). Plant diversity is closely related to the density of zokor mounds in three alpine rangelands on the Tibetan Plateau. PeerJ, 7,e6921.https://doi.org/10.7717/peerj.6921
[19]Wang, K., Zhang, Y., Tang, Z., Shangguan, Z., Chang, F., Jia, F., Chen, Y., He, X., Shi, W., & Deng, L. (2019). Effects of grassland afforestation on structure and function of soil bacterial and fungal communities. Science of The Total Environment, 676, 396–406.
[20]Ye, G., Chu, B., Tang, Z., Alongi, F., Bao, D., Hua, R., Hua, L., & Niu, Y. (2022). Disturbance of plateau zokor (Eospalax baileyi) mounds increase plant and soil macroinvertebrate richness by offering a diversified microenvironment. Ecological Engineering, 183, 106754.
[21]Ye, G., Chu, B., Tang, Z., Hu, G., Bao, D., Hua, R., Pfeiffer, M., Hua, L., & Niu, Y. (2023). Soil microbial and macroinvertebrate functional diversity in response to Zokor disturbance in Tibetan alpine meadow. CATENA, 225, 107014.
[22]Zhu, G., Tang, Z., Shangguan, Z., Peng, C., & Deng, L. (2019). Factors Affecting the Spatial and Temporal Variations in Soil Erodibility of China. Journal of Geophysical Research: Earth Surface, 124(3), 737–749.

联系方式

通讯地址：甘肃省兰州市安宁区营门村1号甘肃农业大学草业学院
邮政编码：730070
联系电话：0931-7634659（办）
E-mail：tangzs@gsau.edu.cn

上一条：郝媛媛

下一条：康文娟