曾思博，2021年7月毕业于柏林自由大学地球科学学院，获自然科学博士学位，现担任中国科学院地球化学研究所特聘研究员、博导。主要从事岩溶（喀斯特）动力学与碳循环、岩溶（喀斯特）生物地球化学、岩溶（喀斯特）水文生态学等方面的研究工作。在Nature Communications、Earth-Science Reviews、Geochimica et Cosmochimica Acta、Water Research、Water Resource Research、Global Biogeochemical Cycles、Global and Planetary Change、Journal of Hydrology、科学通报等国内外核心期刊上发表学术论文30余篇。研究主要揭示了全球碳酸盐风化（岩溶作用）行为的环境驱动机制，评估了岩溶（喀斯特）区生物泵的碳限制与富营养化缓解效应，提出了基于土地利用的碳酸盐风化碳汇调控有效方式。

1. 中国科学院地球化学研究所所内BR计划, 主持.

2. 国家自然科学基金青年基金项目, 42307070,岩溶区不同土地利用下生物泵稳碳-固碳效应对比研究, 2024/01-2026/12, 主持.

3. 重庆市留学人员回国创业创新支持计划（优秀类），基于生物碳泵效应的喀斯特地区城市河流富营养化缓解技术研究，2023/01-2024/12，主持.

[1] Zeng, S., Jiang, Y*., Liu, Z., Pu, J., Nerantzis, K., He, Q., Wu, Z., Tian, X., 2025. Revegetation Reduces Soil Moisture and Groundwater but Not Water Yield in Humid Karst Areas. Water Resources Research 61, e2024WR038758.

[2] Zeng, S., Jiang, Y*., Liu, Z., He, Q., Wu, Z., Tian, X., 2025. Shallow soil depth and low soil moisture constrain soil pCO2 on hillslopes: Insights from field experiments and model comparisons. Catena 255, 109019.

[3] Shi, L., Zhao, Y., Zeng, S*., Liu, Z*., Shao, M., Zhao, M., He, H., Zeng, C., Han, Y., Hao, P., Tang, L., 2025. Land-use management and climate change can enhance the autotrophic capacity and reduce the CO2 emissions of karst aquatic ecosystems. Water Research 284, 124031.

[4] Shi, L., Zeng, S*., Liu, Z*., He, H., Shao, M., Zhao, M., Zhao, Y., 2025. Carbon capture and storage via enhanced carbonate weathering coupled with aquatic photosynthesis: Potential, cost, and advantages. Earth-Science Reviews 266, 105149.

[5] Zeng, S*., Liu, Z*., Jiang, Y., Goldscheider, N., Yang, Y., Zhao, M., Sun, H., He, H., Shao, M., Shi, L., 2025. A greening Earth has reversed the trend of decreasing carbonate weathering under a warming climate. Nature Communications 16, 2583.

[6] Zeng, S., Sun, H., Liu, Z*., Goldscheider, N., Frank, S., Goeppert, N., Zhao, M., Zeng, H., Han, C., 2024. Changes in the limiting nutrients and dominant phytoplankton communities of three major European rivers: Response to catchment lithologies and human activities. Journal of Hydrology 637, 131362.

[7] Chai, Q., Zeng, S*., Liu, Z*., Sun, H., He, H., Chen, B., Zhao, M., Zeng, C., 2024. High stability of carbonate weathering relevant carbon sink under biological pump effect in inland waters: Insight from Shawan Karst Experimental Site, Southwest China. Applied Geochemistry 169, 106059.

[8] Zeng, S., Jiang, Y*., Wu, Z., Zhang, C., Lv, T., 2023. Declining trees growth and vegetation productivity resulting from decreasing soil water contents induced by tunnels excavation in karst mountain areas. Ecological Indicators 154, 110555.

[9] 曾思博, 刘再华*. 我国岩溶碳汇和在非岩溶区播散碳酸盐粉的碳中和潜力研究. 科学通报 2022, 67: 1-14.

[10] Zeng, S*., Kaufmann, G., Liu, Z., 2022. Natural and anthropogenic driving forces of carbonate weathering and the related carbon sink flux: a model comparison study at global scale. Global Biogeochemical Cycles 36, e2021GB007096. 

[11] Zeng, S., Liu, Z*., Chris, G., 2022. Large-scale CO₂ removal by enhanced carbonate weathering from changes in land-use practices. Earth-Science Reviews 225, 103915.

[12] Zeng, S*., Liu, Z*., Goldscheider, N*., Frank, S., Goeppert, N., Kaufmann, G., Zeng, C., Zeng, Q., Sun, H., 2021. Comparisons on the effects of temperature, runoff, and land-cover on carbonate weathering in different karst catchments: insights into the future global carbon cycle. Hydrogeology Journal 29, 331-345.

[13] Zeng, S., Liu, Z*., Kaufmann, G*., 2019. Sensitivity of the global carbonate weathering carbon-sink flux to climate and land-use changes. Nature Communications 10, 5749. 

[14] Zeng, S., Liu, H., Liu, Z*., Kaufamnn, G., Zeng, Q., Chen, B., 2019. Seasonal and diurnal variations in DIC, NO3- and TOC concentrations in spring-pond ecosystems under different land-uses at the Shawan Karst Test Site, SW China: Carbon limitation of aquatic photosynthesis. Journal of Hydrology 574, 811-821.

[15] Zeng, S., Jiang, Y*., Liu, Z*., 2016. Assessment of climate impacts on the karst-related carbon sink in SW China using MPD and GIS. Global and Planetary Change 144, 171-181.