（一）导师简介

栾军伟，男，汉族，理学博士，研究员，博士生导师。

招生专业：生态学、林业

研究方向：全球变化生态学，森（竹）林生态系统结构与功能，地上与地下生物多样性关系及其驱动机制、植物-土壤互馈机制、土壤生物地球化学循环与气候变化、菌根真菌与土壤碳氮过程。

电子邮箱（e-mail）：junweiluan@icbr.ac.cn

国际竹藤中心三亚研究基地热带森林植物研究所副所长, 海南三亚竹藤伴生林生态系统定位观测研究站站长，国际竹藤中心竹林生态站技术总负责人。2010年中国林业科学研究院获生态学博士学位。2010-2013年中国林科院助理研究员，2013-2016年在加拿大Memorial University of Newfoundland自然资源与可持续发展系从事博士后研究。2016年6月入选原国家林业局海外高端人才引进计划领军人才。2018年加拿大University of Alberta可再生资源系、McGill University自然资源系Visiting Professor。兼任国际林联（IUFRO）第八学部副协调员、森林土壤与水相互作用特别委员会委员、中国生态学学会理事、中国林学会森林生态分会常务理事、Forest Ecosystems、CABI Agriculture and Bioscience编委、Soil Biology & Biochemistry客座编委。

（二）科研经历

先后主持国家自然科学基金项目3项，十三五重点研发计划子课题2项，十四五重点研发计划子课题2项，人社部留学人员创新支持子项目（重点）1项，“赤子计划”项目1项等。近年来发表论文60余篇，授权专利2项，参编专著3部, 参与制定行业标准3项。

（三）在研项目

[1]国家自然科学基金面上项目“竹林扩张对根际介导土壤碳氮过程的影响机制”（No.31971461）

[2]国家自然科学基金重点项目子课题“树种配置对土壤有机质形成过程的影响机制—以南亚热带人工林为例”（No.31930078）

[3]国家自然科学基金联合基金项目子课题“海南热带雨林的碳汇稳定性及其调控机制研究”（U23A2002）

[4]十四五重点研发计划项目子课题“典型森林生态系统碳汇提升经营技术与增汇潜力”（2021YFD2200405）和“森林土壤有机碳形成、转化与碳固持稳定性机制”（2021YFD2200403）；

[5]中央公益性科研院所基本科研业务费学科发展项目：“干旱对竹林/竹藤伴生林土壤生态功能影响机制研究”（1632019006，1632021023），“海南热带森林碳汇地上地下协同调控机制”（1630032024002）；

[6]国际竹藤中心三亚基地生态学学科建设项目（YJPY202400103）。

（四）近年发表的主要论文(*通讯作者)

[1]Wang, S., Luan, J.*, Li, S., Ma, J., Chen, L., Wang, Y. et al. (2024). Litter quality and decomposer complexity co-drive effect of drought on decomposition. Forest Ecosystems, 11, 100194.

[2]Pan, J., See, C.R., Wang, R., Luan, J., Wang, J., Liu, F. et al. (2024). Decoupling of nitrogen, phosphorus, and carbon release from fine and coarse roots during 7 years of decomposition. Journal of Ecology, 112, 348-359.

[3]Smith, M.D., Wilkins, K.D., Holdrege, M.C., Wilfahrt, P., Collins, S.L., Knapp, A.K. et al. (2024). Extreme drought impacts have been underestimated in grasslands and shrublands globally. Proc Natl Acad Sci USA, 121, e2309881120.

[4]Junwei Luan*, Siyu Li, Shirong Liu*, Yi Wang, Liping Ding, Haibo Lu, Lin Chen, Junhui Zhang, Wenjun Zhou, Shijie Han, Yiping Zhang, Stephan Hättenschwiler. Biodiversity mitigates drought effects in the decomposer system across biomes, Proc Natl Acad Sci USA, DOI: 10.1073/pnas.2313334121

[5]J. Luan*, S. Li, Y. Wang, L. Ding, C. Cai, S. Liu*, Decomposition of diverse litter mixtures affected by drought depends on nitrogen and soil fauna in a bamboo forest, Soil Biology and Biochemistry 173, 108783 (2022)

[6]J. Luan, S. Liu, A. Schindlbacher, C. Prescott, A. Stokes, J. Whalen, Plant-soil interactions in forests: Effects of management, disturbance and climate. Soil Biology and Biochemistry, 108642 (2022).

[7]Li, S., Xie, D., Ge, X., Dong, W. & Luan, J*. (2022). Altered diversity and functioning of soil and root-associated microbiomes by an invasive native plant. Plant and Soil, 2022, 473(1): 235-249.

[8]Zhai, W., Wang, Y., Luan, J*. & Liu, S*. (2021). Effects of nitrogen addition on clonal integration between mother and daughter ramets of Moso bamboo: a 13C-CO2 pulse labeling study. Journal of Plant Ecology, rtab115.

[9]Luan, J.*, Li, S., Dong, W., Liu Y., Wang, Y., Liu, S.*, (2021). Litter decomposition affected by bamboo expansion is modulated by litter‐mixing and microbial composition. Functional Ecology 35(11): 2562-2574.

[10]Luan, J.*, Liu, S.*, Li, S., Whalen, J.K., Wang, Y., Wang, J. et al. (2021). Functional diversity of decomposers modulates litter decomposition affected by plant invasion along a climate gradient. Journal of Ecology, 109, 1236-1249.

[11]Luan, J., J. Wu, S. Liu, N. Roulet, and M. Wang. 2019. Soil nitrogen determines greenhouse gas emissions from northern peatlands under concurrent warming and vegetation shifting. Communications Biology 2:132.

[12]Luan, J., S. Liu, J. Wu, M. Wang, and Z. Yu. 2018. The transient shift of driving environmental factors of carbon dioxide and methane fluxes in Tibetan peatlands before and after hydrological restoration. Agricultural and Forest Meteorology 250-251:138-146.

[13]Luan, J., S. Liu, J. Wang, S. X. Chang, X. Liu, H. Lu, and Y. Wang. 2018. Tree species diversity promotes soil carbon stability by depressing the temperature sensitivity of soil respiration in temperate forests. Science of The Total Environment 645:623-629.

[14]Luan, J., and J. Wu. 2015. Long-term agricultural drainage stimulates CH4 emissions from ditches through increased substrate availability in a boreal peatland. Agriculture, Ecosystems & Environment 214:68-77.

[15]Luan, J., and J. Wu. 2014. Gross photosynthesis explains the ‘artificial bias’ of methane fluxes by static chamber (opaque versus transparent) at the hummocks in a boreal peatland. Environmental Research Letters 9:105005.

[16]Luan, J., S. Liu, S. X. Chang, J. Wang, X. Zhu, K. Liu, and J. Wu. 2014. Different effects of warming and cooling on the decomposition of soil organic matter in warm–temperate oak forests: a reciprocal translocation experiment. Biogeochemistry 121:551-564.

[17]Luan, J., S. Liu, X. Zhu, J. Wang, and K. Liu. 2012. Roles of biotic and abiotic variables in determining spatial variation of soil respiration in secondary oak and planted pine forests. Soil Biology and Biochemistry 44:143-150.

[18]Luan, J., S. Liu, J. Wang, X. Zhu, and Z. Shi. 2011. Rhizospheric and heterotrophic respiration of a warm-temperate oak chronosequence in China. Soil Biology and Biochemistry 43:503-512.

[19]Luan, J., S. Liu, X. Zhu, and J. Wang. 2011. Soil carbon stocks and fluxes in a warm-temperate oak chronosequence in China. Plant and Soil 347:243-253.

（五）个人主页

Google Scholar:   http://scholar.google.ca/citations?user=qUxbAO0AAAAJ&hl=zh-CN

Research gate:     http://www.researchgate.net/profile/Junwei_Luan