中国科学院地理科学与资源研究所

专家人才

高德才

安徽滁州人，中科院地理科学与资源研究所副研究员，地理资源所“可桢-秉维青年人才”计划获得者。主持国家自然科学基金青年项目，面上项目等。近五年论文成果发表在PNAS、ISME、Global Change Biology、New Phytologist、Soil Biology and Biochemistry等国际顶级SCI期刊上。为Global Change Biology，Soil Biology and Biochemistry，Geoderma，Journal of Soils and Sediments，Biology Fertility of Soils，Biogeoscience等国际期刊的审稿人。发表文章入选“领跑者5000——中国精品科技期刊顶尖学术论文（F5000）”。

研究方向：全球变化生态学，长期从事森林土壤碳、氮循环与全球气候变化研究，通过采用稳定同位素C13、N15、O18标记等多种研究手段（室内培养实验、野外原位控制实验、大数据挖掘），以全球气候变化为背景，探究森林土壤碳、氮循环规律及其微生物驱动机制，以及从全球尺度探究陆地生态系统微生物特性的地理时空变化格局及其环境影响机制。

社会任职：

2024.5-至今，《植物生态学报》期刊编委。

发表论文：

[1] Gao, D., Luster, J., Zürcher, A., Arend, M., Bai, E., Gessler, A., Hagedorn, F. (2024). Drought resistance and resilience of rhizosphere communities in forest soils from the cellular to ecosystem scale – insights from 13C pulse labeling. New Phytologist.

[2] Gao, D., Bai, E., Wasner, D., & Hagedorn, F. (2024). Global prediction of soil microbial growth rates and carbon use efficiency based on the metabolic theory of ecology. Soil Biology and Biochemistry, 190.

[3] Wang, H.#, Gao, D.#, Hu, G., Xu, W., Zhuge, Y., & Bai, E. (2024). Drying-rewetting events enhance the priming effect on soil organic matter mineralization by maize straw addition. Catena, 238.

[4] Yang, Y., Wang, S., Zhao, C., Jiang, X., & Gao, D.* (2024). Responses of non-structural carbohydrates and biomass in plant to heavy metal treatment. Science of The Total Environment, 909.

[5] Liu, B., Fan, X., Meng, D., Liu, Z., Gao, D., Chang, Q., & Bai, E. (2023). Ectomycorrhizal trees rely on nitrogen resorption less than arbuscular mycorrhizal trees globally. Ecology Letters, 27(1).

[6] Gao, D., Bai, E.*, Wang, S., Zong, S., Liu, Z., Fan, X., Zhao, C. and Hagedorn, F. (2022). Three-dimensional mapping of carbon, nitrogen, and phosphorus in soil microbial biomass and their stoichiometry at the global scale. Global Change Biology.

[7] Liu, B., Gao, D., Chang, Q., Liu, Z., Fan, X., Meng, D., Bai, E.* (2022). Leaf enzyme plays a more important role in leaf nitrogen resorption efficiency than soil properties along an elevation gradient. Journal of Ecology.

[8] Liu, Z., Liu, S., Gao, D.*, Li, Y., Tian, Y., Bai, E., 2022. An Optical Sensing Platform for Beta-Glucosidase Activity Using Protein-Inorganic Hybrid Nanoflowers. J Fluoresc.

[9] Fan, X., Gao, D., Zhao, C., Wang, C., Qu, Y., Zhang, J., Bai, E., 2021. Improved model simulation of soil carbon cycling by representing the microbially derived organic carbon pool. ISME J 15, 2248-2263.

[10] Gao, D., Bai, E., Yang, Y., Zong, S., Hagedorn, F., 2021a. A global meta-analysis on freeze-thaw effects on soil carbon and phosphorus cycling. Soil Biology and Biochemistry 159.

[11] Gao, D., Bai, E., 2021. Influencing factors of soil nitrous oxide emission during freeze-thaw cycles. Chinese Journal of Plant Ecology 45, 1006-1023.

[12] Gao, D., Liu, Z., Bai, E., 2021c. Effects of in situ freeze-thaw cycles on winter soil respiration in mid-temperate plantation forests. Science of the Total Environment 793, 148567.

[13] Gao, D., Joseph, J., Werner, R.A., Brunner, I., Zurcher, A., Hug, C., Wang, A., Zhao, C., Bai, E., Meusburger, K., Gessler, A., Hagedorn, F., 2021b. Drought alters the carbon footprint of trees in soils-tracking the spatio-temporal fate of 13C-labelled assimilates in the soil of an old-growth pine forest. Global Change Biology 27, 2491-2506.

[14] Ouyang, S.N., Gessler, A., Saurer, M., Hagedorn, F., Gao, D., Wang, X.Y., Schaub, M., Li, M.H., Shen, W.J., Schonbeck, L., 2021. Root carbon and nutrient homeostasis determines downy oak sapling survival and recovery from drought. Tree Physiology 41, 1400-1412.

[15] Wang, Y., Zhao, C., Liu, Z., Gao, D.*, 2021. Spatiotemporal Analysis of AIDS Incidence and Its Influencing Factors on the Chinese Mainland, 2005-2017. Int J Environ Res Public Health 18.

[16] Gao, D., Bai, E., Li, M., Zhao, C., Yu, K., Hagedorn, F., 2020. Responses of soil nitrogen and phosphorus cycling to drying and rewetting cycles: A meta-analysis. Soil Biology and Biochemistry 148.

[17] Joseph, J.#, Gao, D.#, Backes, B., Bloch, C., Brunner, I., Gleixner, G., Haeni, M., Hartmann, H., Hoch, G., Hug, C., Kahmen, A., Lehmann, M.M., Li, M.H., Luster, J., Peter, M., Poll, C., Rigling, A., Rissanen, K.A., Ruehr, N.K., Saurer, M., Schaub, M., Schonbeck, L., Stern, B., Thomas, F.M., Werner, R.A., Werner, W., Wohlgemuth, T., Hagedorn, F., Gessler, A., 2020. Rhizosphere activity in an old-growth forest reacts rapidly to changes in soil moisture and shapes whole-tree carbon allocation. Proceedings of the National Academy of Sciences (PNAS) 117, 24885-24892.

[18] Wang, C., Wang, X., Pei, G., Xia, Z., Peng, B., Sun, L., Wang, J., Gao, D.， Chen, S., Liu, D., Dai, W., Jiang, P., Fang, Y., Liang, C., Wu, N., Bai, E. * 2020. Stabilization of microbial residues in soil organic matter after two years of decomposition. Soil Biology and Biochemistry. 141:107687.

[19] Pei, G., Liu, J., Peng, B., Gao, D., Wang, C., Dai, W., Jiang, P., Bai, E., 2019. Nitrogen, lignin, C/N as important regulators of gross nitrogen release and immobilization during litter decomposition in a temperate forest ecosystem. Forest Ecology and Management 440, 61-69.

[20] Peng, B., Sun, J., Liu, J., Dai, W., Sun, L., Pei, G., Gao, D., Wang, C., Jiang, P., Bai, E., 2019. N2O emission from a temperate forest soil during the freeze-thaw period: A mesocosm study. Sci Total Environ 648, 350-357.

[21] Gao, D., Hagedorn, F., Zhang, L., Liu, J., Qu, G., Sun, J., Peng, B., Fan, Z., Zheng, J., Jiang, P., Bai, E., 2018a. Small and transient response of winter soil respiration and microbial communities to altered snow depth in a mid-temperate forest. Applied Soil Ecology 130, 40-49.

[22] Gao, D., Peng, B., Fan, Z., Pei, G., Bai, E., 2018b. Different winter soil respiration between two mid-temperate plantation forests. Forest Ecology and Management 409, 390-398.

[23] Gao, D., Zhang, L., Liu, J., Peng, B., Fan, Z., Dai, W., Jiang, P., Bai, E., 2018c. Responses of terrestrial nitrogen pools and dynamics to different patterns of freeze-thaw cycle: A meta-analysis. Global Change Biology 24, 2377-2389.

[24] Liu, J., Peng, B., Xia, Z., Sun, J., Gao, D., Dai, W., Jiang, P., Bai, E., 2017. Different fates of deposited NH4+ and NO3- in a temperate forest in northeast China: a (15) N tracer study. Global Change Biology 23, 2441-2449.

[25] Sun, J., Xia, Z., He, T., Dai, W., Peng, B., Liu, J., Gao, D., Jiang, P., Han, S., Bai, E., 2017. Ten years of elevated CO2 affects soil greenhouse gas fluxes in an open top chamber experiment. Plant and Soil 420, 435-450.

[26] Zhang, L., Gao, D., Li, J., Fang, N., Wang, L., Shi, Y., 2017a. Effects of poly-γ-glutamic acid (γ-PGA) on soil nitrogen and carbon leaching and CO2 fluxes in a sandy clay loam soil. Canadian Journal of Soil Science.

[27] Zhang, L., Yang, X., Gao, D., Wang, L., Li, J., Wei, Z., Shi, Y., 2017b. Effects of poly-gamma-glutamic acid (gamma-PGA) on plant growth and its distribution in a controlled plant-soil system. Scientific Reports 7, 6090.

[28] Xia, Z., Bai, E., Wang, Q., Gao, D., Zhou, J., Jiang, P., Wu, J., 2016. Biogeographic Distribution Patterns of Bacteria in Typical Chinese Forest Soils. Frontier in Microbiology 7, 1106.

[29] 高德才, 刘强, 荣湘民, 张玉平, 张蕾, 田昌, 2015a. 添加生物黑炭对玉米产量、品质、肥料利用率及氮磷径流损失的影响. 中国土壤与肥料 5, 72-76.

[30] 高德才, 张蕾, 刘强, 荣湘民, 张玉平, 田昌, 2015b. 生物黑炭对旱地土壤CO2、CH4、N2O 排放及其环境效益的影响. 生态学报 35, 3615-3624.

[31] 高德才, 张蕾, 刘强, 荣湘民, 张玉平, 田昌, 2014a. 不同施肥模式对旱地土壤氮素径流流失的影响. 水土保持学报 28, 209-213.

[32] 高德才, 张蕾, 刘强, 荣湘民, 张玉平, 田昌, 2014b. 旱地土壤施用生物炭减少土壤氮损失及提高氮素利用率. 农业工程学报 30, 54-61.

[33] 高德才, 张蕾, 刘强, 荣湘民, 张玉平, 2013a. 菜地土壤氮磷污染现状及其防控措施. 湖南农业科学 17, 51~55,61.

[34] 高德才, 张蕾, 刘强, 荣湘民, 张玉平, 田昌, 2013b. 生物黑炭对旱地土壤磷动态变化的影响. 水土保持学报 27, 256-260.

联系方式：gaodecai@igsnrr.ac.cn

更新日期：2024年5月11日