博士生导师简介
闫涛,男,1988.03;山西大同;研究生;研究员,博士生导师;人工林生产/生态功能形成与维持机制及提升途径;《生态学杂志》编委,Journal of Plant Ecology、《植物生态学报》、《林业科学》等期刊青年编委;以第一或通讯作者在Ecology、New Phytologist、Global Change Biology、Soil Biology and Biochemistry、Tree Physiology、Agricultural and Forest Meteorology、Forest Ecology and Management等期刊发表SCI论文22篇。
2014.09-2017.07 中国科学院沈阳应用生态研究所 生态学 博士
2011.09-2014.07 中国科学院沈阳应用生态研究所 生态学 硕士
2007.09-2011.07 黑龙江大学 水土保持与荒漠化防治 学士
2025.04-至今 中国科学院沈阳应用生态研究所 研究员
2024.06-2025.03 兰州大学 教授
2019.06-2024.05 兰州大学 研究员
2017.07-2019.06 北京大学 博士后
2016.12-2017.02 Alberta Agriculture and Forestry, Canada 访问学者
人工林;生产力;碳汇;养分与水分策略;气候变化
辽宁省杰出青年、草地农业生态系统国家重点实验室青年英才
2026-2028:中国科学院项目负责人;
2026-2027:辽宁省杰出青年基金(青A),我国北方典型人工林功能稳定性维持机制,项目负责人
2026-2030:中国科学院B类先导专项课题,三北地区低质低效林形成机制与提质增效,课题负责人
2026-2029:国家自然科学基金面上项目,落叶松人工林生产力形成的全系统物候驱动机制:基于长期氮添加控制实验,项目负责人
2022-2026:国家自然科学基金重大项目专题,人工林生态系统生产力提升与碳汇维持机制,专题负责人
2022-2025:国家自然科学基金面上项目,气候变化背景下落叶松人工林生产力形成与维持的水-氮互作机制,项目负责人
2019-2021:国家自然科学基金青年基金,温度和光周期对华北落叶松秋季物候与养分再吸收的影响机制,项目负责人
2022-2024:甘肃省自然科学基金面上项目,西北半干旱区典型人工林衰退死亡的水碳作用机制,项目负责人
2019-2024:兰州大学人才引进科研启动费,项目负责人
[1]Ning SJ, Yan T*, Wang Z, Zhu JJ. 2026. Root resorption completes the tree nitrogen economy: Evidence from a 15-year nitrogen addition experiment across stand ages. New Phytologist, https://doi.org/10.1111/nph.71019.
[2]Song HH, Zhong TY, Zhu JX, Yan T*. 2025. Higher risk of hydraulic dysfunction and carbohydrate depletion of declining Larix principis-rupprechtii trees. Ecological Processes, 14, https://doi.org/10.1186/s13717-024-00567-9.
[3]Ning SJ, He XR, Ma T, Yan T*. 2024. Attenuated asymmetry of above- versus belowground stoichiometry to a decadal nitrogen addition during stand development. Ecology, 105, e4458.
[4]Ning SJ, Yan T*, Luo WT, Tao SL, Zou XM, Li YJ, Shangguan ZJ, Wu YN, Zhang ZH, He JS*. 2024. Aridity-dependent resistance but strong resilience of grassland aboveground net primary productivity: evidence from long-term naturally occurring extreme precipitation events. Journal of Plant Ecology, rtae084, https://doi.org/10.1093/jpe/rtae084.
[5]Yan T*, Fang YT, Wang JS, Song HH, Zhong TY, Wang PL. 2024. Effects of long-term nitrogen addition on the shift of nitrogen cycle from open to closed along an age gradient of larch plantations in North China. Soil Biology and Biochemistry, 191, 109295.
[6]Yan T*, Wang LY, Wang PL, Zhong TY. 2023. Stability in the leaf functional traits of understory herbaceous species after 12-yr of nitrogen addition in temperate larch plantations. Frontiers in Plant Science, 14:1282884.
[7]Li XF, Wang X, Fang YT, Liu DW, Huang K, Wang PL, Zhang JX, Yan T*. 2023. Phenology advances uniformly in spring but diverges in autumn among three temperate tree species in response to warming. Agricultural and Forest Meteorology, 336, 109475.
[8]Yan T*, Wang LY, Zhong TY, Fu C. 2022. Decadal nitrogen addition increases divergence in intrinsic water-use efficiency between sapling and mature larch plantations. Forest Ecology and Management, 523, 120494.
[9]Wang PL, Fu C, Wang LY, Yan T*. 2022. Delayed autumnal leaf senescence following nutrient fertilization results in altered nitrogen resorption. Tree Physiology, 42, 1549-1559.
[10]Yan T, Fu YS, Campioli M, Peñuelas J, Wang XH*. 2021. Divergent responses of phenology and growth to summer and autumnal warming. Global Change Biology, 27, 2905-2913.
[11]Yan T*, Song HH, Zeng H. 2020. Spring phenophases of larch are more sensitive to spring warming than to year-round warming: Results of a seasonally asymmetric warming experiment. Forest Ecology and Management, 474, https://doi.org/10.1016/j.foreco.2020.118368.
[12]Song HH, Yan T*, Wang JS, Sun ZZ. 2020. Precipitation variability drives the reduction of total soil respiration and heterotrophic respiration in response to nitrogen addition in a temperate forest plantation. Biology and Fertility of Soils, 56, 273-279.
[13]Yan T#, Song HH#, Wang ZQ, Teramoto M, Wang JS, Liang NS, Ma C, Sun ZZ, Xi Y, Li LL, Peng SS*. 2019. Temperature sensitivity of soil respiration across multiple time scales in a temperate plantation forest. Science of the Total Environment, 688, 479-485.
[14]Yan T, Qu TT, Song HH, Sun ZZ, Zeng H*, Peng SS*. 2019. Ectomycorrhizal fungi respiration quantification and drivers in three differently aged larch plantations. Agricultural and Forest Meteorology, 265, 245-251.
[15]Yan T, Zhu JJ*, Song HH, Yang K. 2019. Resorption-related nitrogen changes in the leaves and roots of Larix kaempferi seedlings under nutrient-sufficient and nutrient-starvation conditions. Journal of Plant Ecology, 12, 615-623.
[16]Yan T, Qu TT, Sun ZZ, Dbyzinski R, Chen AP, Yao XC, Zeng H, Piao SL*. 2018. Negative effect of nitrogen addition on soil respiration dependent on stand age: Evidence from a 7-year field study of larch plantations in northern China. Agricultural and Forest Meteorology, 262, 24-33.
[17]Yan T, Lü XT, Zhu JJ*, Yang K, Yu LZ, Gao T. 2018. Changes in nitrogen and phosphorus cycling suggest a transition to phosphorus limitation with the stand development of larch plantations. Plant and Soil, 422, 385-396.
[18]Yan T, Zhu JJ*, Fang YT, Yang K, Li MC. 2018. Effects of thinning on nitrogen status of a larch plantation, illustrated by 15N natural abundance and N resorption. Scandinavian Journal of Forest Research, 33, 357-364.
[19]Yan T, Zhu JJ*, Yang K. 2018. Leaf nitrogen and phosphorus resorption of woody species in response to climatic conditions and soil nutrients: a meta-analysis. Journal of Forestry Research, 29, 905-913.
[20]Yan T, Qu TT, Song HH, Ciais P, Piao SL, Sun ZZ, Zeng H*. 2018. Contrasting effects of N addition on the N and P status of understory vegetation in plantations of sapling and mature Larix principis-rupprechtii. Journal of Plant Ecology, 11, 843-852.
[21]Yan T, Zhu JJ*, Yang K*, Yu LZ, Zhang JX. 2017. Nutrient removal under different harvesting scenarios for larch plantations in northeast China: Implications for nutrient conservation and management. Forest Ecology and Management, 400, 150-158.
[22]Yan T, Lü XT, Yang K, Zhu JJ*. 2016. Leaf nutrient dynamics and nutrient resorption: a comparison between larch plantations and adjacent secondary forests in Northeast China. Journal of Plant Ecology, 9, 165-173.
[23]Yan ZJ, Chen C, Liu Y, Li YJ, Liu HY, Wang H, Yan T, Jing X, Ren S, Zi HB, Shi Y, Wang T, He JS*. 2026. Quantifying the trade-off between spring phenology and lethal frost risk: a meta-analysis. Nature Communications, https://doi.org/10.1038/s41467-026-70187-8.
[24]Ding GG, Zeng WJ, Yan T, Sun LJ, Chen WL, Lu MZ, Ma ZQ*. 2025. Root-mycorrhizal foraging strategies shift with forest age more than with nitrogen manipulation. Ecological Monographs, 95, e70039.
[25]Chen HZ, Zhang B, Potapov A, Hong PB, Meng B, Yan T, Yang Q, Wang SP*. 2025. Long-term nitrogen addition enhances the energy fluxes of soil macro-food webs in young but not mature forest plantations. Soil Ecology Letters, 7, 250338.
[26]Lu CY, van Groenigen KJ, Gillespie MAK, Hollister RD, Post E, Cooper EJ, Welker JM, Huang YX, Min XT, Chen JH, Jónsdóttir IS, Mauritz M, Cannone N, Natali SM, Schuur E, Molau U, Yan T, Wang H, He JS, Liu HY*. 2024. Diminishing warming effects on plant phenology over time. New Phytologist, https://doi.org/10.1111/nph.20019.
[27]Ding GG, Zeng WJ, Sun LJ, Chen FS, Lyu Y, Xu J, Yan T, Wang HM, Ma ZQ*. 2024. Root acquisitive traits mirror the functional modules of root-associated fungi. Soil Biology and Biochemistry, 190, 109317.
[28]Wang X, Zi HB, Wang JB, Guo XW, Zhang ZH, Yan T, Wang Q*, He JS*. 2023. Grazing-induced changes in soil microclimate and aboveground biomass modulate freeze–thaw processes in a Tibetan alpine meadow. Agriculture, Ecosystems, and Environment, 357, 108659.
[29]Lu CY, Zhang JJ, Min XT, Chen JH, Huang YX, Zhao HF, Yan T, Liu X, Wang H, Liu HY*. 2023. Contrasting responses of early- and late-season plant phenophases to altered precipitation. Oikos, https://onlinelibrary.wiley.com/doi/full/10.1111/oik.09829.
[30]Yang L, Wang JS, Geng Y, Niu SL, Tian DS, Yan T, Liu WG, Pan JX, Zhao XH, Zhang CY. 2022. Heavy thinning reduces soil organic carbon: Evidence from a 9-year thinning experiment in a pine plantation. Catena, https://doi.org/10.1016/j.catena.2021.106013.
[31]Yang L, Niu SL, Tian DS, Zhang CY, Liu WG, Yu Z, Yan T, Yang W, Zhao XH*, Wang JS*. 2022. A global synthesis reveals increases in soil greenhouse gas emissions under forest thinning. Science of the Total Environment, 804, 150225.
[32]Wang K*, Wang, G, Song LN, Zhang RS, Yan T, Li YH. 2021. Linkages between nutrient resorption and ecological stoichiometry and homeostasis along a chronosequence of Mongolian pine plantations. Frontiers in Plant Science, https://doi.org/10.3389/fpls.2021.692683.
[33]Wang K*, Zhang RS, Song LN, Yan T, Na EH. 2021. Comparison of C:N:P stoichiometry in the plant–litter–soil system between poplar and elm plantations in the Horqin Sandy Land, China. Frontiers in Plant Science, https://doi.org/10.3389/fpls.2021.655517.
[34]Wang JS*, Defrenne C, McCormack LM, Yang L, Tian DS, Luo YQ, Hou EQ, Yan T, Li ZL, Bu WS, Chen Y, Niu SL*. 2021. Fine-root functional trait responses to experimental warming: a global meta-analysis. New Phytologist, 230, 1856-1867.
[35]Wang JS, Song B, Ma FF, Tian DS, Li Y, Yan T, Quan Q, Zhang FY, Li ZL, Wang BX, Gao Q, Chen WN, Niu SL*. 2019. Nitrogen addition reduces soil respiration but increases the relative contribution of heterotrophic component in an alpine meadow. Functional Ecology, 33, 2239-2253.
[36]Song HH, Yan T, Zeng DH*. 2019. Establishment of mixed plantations of Pinus sylvestris var. mongolica and Populus x xiaozhuanica may not be appropriate: evidence from litter decomposition. Journal of Plant Ecology, 12, 857-870.
[37]Wang J, Yan QL*, Lu DL, Diao MM, Yan T, Sun YR, Yu LZ, Zhu JJ. 2019. Effects of microhabitat on rodent-mediated seed dispersal in monocultures with thinning treatment. Agricultural and Forest Meteorology, 275, 91-99.
[38]Song J, Liu Z, Zhang Y, Yan T, Shen ZH, Piao SL*. 2019. Effects of wildfire on soil respiration and its heterotrophic and autotrophic components in a montane coniferous forest. Journal of Plant Ecology, 12, 336-345.
[39]Piao SL*, Huang MT, Liu Z, Wang XH, Ciais P, Canadell J, Wang K, Bastos A, Friedlingstein P, Houghton R, Le Quéré C, Liu YW, Myneni RB, Peng SS, Pongratz J, Sitch S, Yan T, Wang YL, Zhu ZC, Wu DH, Wang T. 2018. Lower land use emissions increased net land carbon sink during the slow warming period. Nature Geoscience, 11, 739-743.
[40]Zhu ZC, Piao SL*, Yan T, Ciais P, Bastos A, Zhang XZ, Wang ZQ. 2018. The Accelerating land carbon sink of the 2000s may not be driven predominantly by the warming hiatus. Geophysical Research Letters, 45, 1402-1409.
[41]Wang J, Yan QL*, Yan T, Song Y, Sun YR, Zhu JJ. 2017. Rodent-mediated seed dispersal of Juglans mandshurica regulated by gap size and within-gap position in larch plantations: Implication for converting pure larch plantations into larch-walnut mixed forests. Forest Ecology and Management, 404, 205-213.
[42]Li XF, Wen YJ, Zhang JX, Liu LM*, Jin L, Yan T, Wang Y. 2017. The effect of low-temperature event on the survival and growth of Juglans mandshurica seedlings within forest gaps. Journal of Forestry Research, 29, 943-951.
[43]曲恬甜, 闫涛*, 张文, 曾辉. 2019. 落叶松人工林草本植物群落特征和生物量对氮添加的响应. 北京大学学报, 55, 587-596.
[44]闫涛, 朱教君*, 杨凯, 于立忠. 2014. 辽东山区落叶松人工林地上生物量和养分元素分配格局. 应用生态学报, 25, 2772-2778.
[45]闫涛, 杨凯, 朱教君*. 2014. 辽东山区主要树种叶片氮、磷、钾再吸收. 生态学杂志, 33, 2005-2011.
[46]申奥, 朱教君*, 闫涛, 卢德亮, 杨凯. 2018. 辽东山区主要阔叶树种叶片养分含量和再吸收对落叶时间的影响. 植物生态学报, 42, 573-584.
[47]张文, 闫涛, 常文静*, 曾辉. 2018. 氮添加对不同林龄华北落叶松叶片氮重吸收过程的影响. 生态学杂志, 37, 3525-3532.
[48]丛俊霞, 郑晓*, 朱教君, 宋立宁, 高西宁, 李秀芬, 闫涛. 2017. 沙地樟子松天然林地上碳储量估算及其空间分布特征. 生态学杂志, 11, 2997-3007.
[49]王静, 徐爽, 闫涛, 马维娟, 闫巧玲*. 2017. 土壤养分对辽东山区主要阔叶树种幼苗生长的影响. 生态学杂志, 36, 3148-3159.
[50]宋立宁, 朱教君*, 李明财, 闫涛, 张金鑫. 2012. 不同降水条件下科尔沁沙地南缘疏林草地樟子松针叶δ13C和叶性状特征. 应用生态学报, 23, 1435-1440.
