何念鹏-tyc5997太阳集团

何念鹏

时间：2024-08-29点击数：

个人简介：

何念鹏，男，理学博士，教授，硕士/博士生导师，2023年入选国家级高层次人才，2024年入选国家自然资源部科技领军人才，2022年入选中国科学院稳定支持基础研究领域青年团队计划；兼任中国生态学会长期生态专业委员会秘书长、中国植物学会植物生态学专业委员会委员、《Journal of Plant Ecology》、《Journal of Forestry Research》、《植物生态学报》、《生物多样性》等编委。科技部重大基础调查专项项目首席科学家、中国科协生态系统碳汇提升决策咨询专家团队首席科学家、黑龙江省林业碳汇专家组组长。

主要研究领域为植物功能生态学、生物地理生态学、生态系统生态学；发表科研论文180余篇，部分论文发表在国内外著名学术期刊，如Nature, Trends in Ecology and Evolution, Trends in Plant Science, Nature Ecology and Evolution, Nature Geoscience, Nature Plants, Natural Communications, Science Bulletin, One Earth, Global Change Biology, Ecological Monographs, Ecology Letters, Ecology, New Phytologist, Global Ecology & Biogeography, Renewable & Sustainable Energy Reviews, Journal of Ecology, Functional Ecology, Soil Biology and Biochemistry, Geoderma, Journal of Geophysical Research等。基于Web of Science论文引用21000多次，H指数75；

主讲《生态学》、《植物功能生态学》、《生态系统控制实验设计原理与方法》、《生物多样性与保护生物学》等课程。截至目前指导毕业博士11人，硕士14人；已毕业博士生先后获得中国科学院百篇优秀博士论文（2人次）、中国科学院院长特别奖（1人次）、中国科学院院长优秀奖（5人次）、全国生态学优秀博士论文（1人次）；所指导博士研究生3人次入选中国科协（生态）青年托举工程，1人次入选中国科协青年人才托举工程博士生专项计划。

学习经历：

先后在东北师范大学获得生态学学士和硕士学位、在中国科学院植物研究所获得生态学博士学位

工作经历：

先后在中国科学院植物研究所工作，任内蒙古草原生态系统定位研究站执行站长（高级工程师）；中国科学院地理科学与资源研究所副研究员、研究员；tyc5997太阳集团林学院和tyc5997太阳集团教授。

主要研究成果和研究内容：

1. 构建了植物功能生态学研究从器官到生态系统的新研究体系，拓展了植物功能性状在群落和生态系统应用的新领域，为揭示生态系统结构和功能预测及其对全球变化响应提供了新思路

以中国东北样带（Northeast China Transect, NECT）、中国东部南北样带（North-South Transect of Eastern China, NSTEC）、中国东西样带（West-East Transect of China, WETC）和亚洲东部南北样带”（North-South Transect of Eastern Asia, NSTEA）为基础，基于“系统性和匹配性”新型性状数据库建设标准，带队对120多个典型生态系统开展了系统性的野外调查，初步构建了由112多种功能性状参数组成的中国生态系统性状数据库（Functional Trait database of China’s ecosystems, China_Traits）。在器官、物种、功能群和群落水平上，较系统地探讨了（多种）植物功能性状的空间变异规律及其影响因素，拓展了“基于植物功能性状的适应机制”的认识，发现了植物叶-枝-干-根间功能元素的协同进化及优化配置规律。发展了植物性状网络（Plant trait networks）、植物群落性状（Plant community traits）、生态系统性状（Ecosystem traits）、基于植物群落性状的预测生产力理论框架（Traits-based Productivity）等概念、方法、参数和系列应用案例，在样地-区域-全国-全球多个尺度开展了其科学性和普适性验证。相关研究工作拓展了植物功能性状的多维度（单性状-多性状-多维空间）、多尺度（器官-物种-群落-生态系统）新研究领域，为推动大尺度的植物功能性状对群落构建机制、植物群落性状对生态系统碳氮循环调控机制、植物群落性状对生态系统功能的影响等奠定了理论基础和技术方法。出版了《植物功能生态学：从器官到生态系统》的中英文专著，构建了植物功能生态学研究从器官到生态系统的新研究体系，目前已经成为10多所国内高校开设《植物功能生态学》课程的主要教材；为传统性状研究、生态系统生态学、宏观生态学的整合生态学研究构建了新桥梁，也为生态系统功能科学预测和生态过程模型奠定了基础。

2. 揭示了大气氮沉降和气候变暖对中国森林生态系统土壤温室气体排放、土壤有机质分解过程及其温度敏感性的影响过程与机制，为科学评估生态系统对全球变化的响应机制提供了新视角

创建了中国典型生态系统大气湿沉降监测网络（China_WD，52个台站组成），开展大气氮沉降、磷沉降、酸沉降和重金属沉降等长期监测，较系统地揭示了中国大气氮、磷和酸沉降的时空格局及其影响因素；首次发现中国大气氮沉降已呈现明显转折趋势：“沉降总量整体趋稳、湿沉降占比下降和干沉降占比上升、NO₃^-和NH₄⁺沉降的贡献趋于持平”，为科学评估中国大气沉降生态效应及准确模拟氮沉降野外控制实验设计等提供了新的启示和研究思路。创新发展了基于“土壤N2O排放对氮沉降的敏感性”来确定了森林氮饱和状态的新框架，结合控制实验数据首次给出了全球氮饱和森林空间图，并以此为基础探索了全球森林土壤三种温室气体（CO_2,CH_4,N2O）对氮沉降的响应规律，评估了氮沉降对森林土壤温室气体通量的影响及其空间格局，揭示了氮沉降对氮限制、氮饱和森林土壤温室气体收支的差异性影响。

自主发展了Q₁₀研究的“自动变温培养+连续自动测试”培养和测定模式（VDM模式），已成为被广泛接受的三种Q₁₀培养与测定模式之一，其配套设备PRI-8800也已在国内外商业化销售。在新模式和新设备支持下，率先阐明了中国和全球尺度的土壤碳矿化和氮矿化对温度变化的响应特性（R₂₅、Q₁₀和T_opt）及其调控机制，发现它们均随纬度升高呈逐步升高的整体变化趋势、并受SOM质量和pH共同影响，为探讨土壤碳氮循环耦合过程的温度响应提供了理论基础。通过联网实验方式揭示了中国森林和草地土壤SOM分解对升温-降温的非对称响应（降温过程的Q₁₀显著高于升温过程），忽略该过程将显著降低模型预测精度；同时，发现蚯蚓和跳虫等土壤小型动物对SOM分解过程及其Q₁₀具有重要影响，拓展了土壤有机质分解过程对温度响应的新研究方向，为科学揭示全球变化情景的土壤碳库温度稳定性提供科技支撑。

3. 系统评估了中国陆地生态系统全组分碳氮磷储量，自主开发了中国森林生态系统碳固持模型（FCS）并评估了中国森林（现存林和新造林）2010~2060碳汇时空动态，为国家碳中和战略提供了科技

支撑以生态系统碳储量计量方法的改进为突破口，构建了中国不同区域关键参数的数据集（不同区域、植物不同器官C、N、P、S、K等含量、土壤容重、土壤C、N、P垂直剖面分布特征函数等），并以此为基础精细评估了中国陆地生态系统全组分（地上生物量、根系、凋落物和0~100 cm土壤）碳氮储量、认识了其时空变异规律及其影响因素，为中国陆地生态系统碳蓄储功能的现状、变化速率、增汇潜力奠定了基础。以自主发展了森林生态系统碳固持模型（FCS模型）为基础、结合随机森林模型等，科学预测了2010~2060年中国森林生态系统碳汇（含现有林、新造林和城市森林）和2010~2060年中国陆地生态系统碳汇的时空变异规律；发现中国森林生态系统碳汇不能持续增长，并首次提出2035-2040年间可能达到其碳汇峰值，亟须通过森林抚育或森林精准质量提升来延续其碳汇高峰期以满足国家碳中和需求；建立了省-市-县造林和再造林固碳速率动态及其空间图，为快速评估中国区域造林或再造林碳汇提供了科学、准确、快速的评估方法学。

4. 以森林碳汇项目评估方法学创新为抓手，创建了全国首个省级林业碳汇交易体系并支撑“龙江绿碳”林业碳汇项目批量开发，拓展了生态价值转化路径，助力地区绿色新质生产力

发展作为黑龙江省林业碳汇专家组组长，牵头完成了全国首个省级林业碳汇交易体系建设，助力地方生态产品价值实现。基于自主发展的FCS模型，融合了1990~2020年间黑龙江省大量实测调查数据，具体包括不同树种的区域生长特征、生长过程函数、地位级指数，优化了生态过程模型的核心参数v0和Bmax, 发展了可针对当地主要造林树种的FCS-造林模型（FCS-杨树、FCS-落叶松、FCS-红松，FCS-混植）；开发了“天然林碳汇方法学”、“森林抚育碳汇方法学”、“营林废弃物封存碳汇方法学”等，初步实现黑龙江省森林碳汇项目开发的全情景覆盖。制定了《黑龙江省造林碳汇项目设计文件（模板）》，完成了黑龙江省造林碳汇评估方法学构建。2024年完成了成果鉴定，是全国首个通过成果鉴定的林业碳汇方法学。中国林业会组织以张守攻院士牵头专家组对FCS-造林模型进行了成功鉴定，认为“黑龙江省造林碳汇项目评估方法学”整体达到国际先进水平，其中，FCS 模型的核心框架“林龄驱动的生物量逻辑斯蒂生长方程结合土壤有机质分解双库模型”达到国际领先水平”（中国林学会（评价）字〔2024〕53号）。同时，牵头创新构建了省级林业碳汇一张图体系和交易平台建设，建成了黑龙江省林业碳汇交易体系，创建了“龙江绿碳”品牌，支撑了13个黑龙江省林业碳汇项目开发、开发可交易碳汇2100多万吨；相关研究通过科技创新拓展生态价值实现路径，促进地区绿色新质生产力发展。

主持项目：

1. 2025-2029, 寒温带森林生态系统多功能时空变异规律及其生物调控机制：基于通量观测塔群系统（自然科学基金委重点项目，32430067，主持人）

2. 2022-2027，陆地生态系统立体观测技术示范及典型生态过程对环境变化的响应（科技部基础研发项目子课题，2022YFF080210102）

3. 2022-2026年，中国植被碳储量与固碳速率时空动态（中国科学院稳定支持基础研究领域青年团队计划，YSBR-037，课题负责人）

4. 2022-2026年，中国陆地生态系统碳库现存量及其不确定性（自然科学基金委重点专项项目，42141004，主持人）

5. 2020-2022，中国生态系统通量数据整编和性状调查项目（科技部基础调查专项重大项目，2019FY101300，负责人）

6. 2019-2023，青藏高原地表功能元素耦合作用的植物性状响应（科技部第二次青藏科考专项子课题，2019QZKK060602）

7. 2018-2021年，中国东部不同气候带森林土壤有机质分解温度敏感性的垂直变异规律与机制：联网研究（自然科学基金项目， 31770655，主持人）

8. 2015-2018年，气候变暖对青藏高寒草地土壤碳组分及其稳定性的影响（自然科学基金项目，31470506，主持人）

9. 2013-2016年，模拟氮沉降对内蒙古草地碳固持效应及其稳定性的影响（自然科学基金项目，31270519，主持人）

10. 2011-2013年，土地利用变化对内蒙古温带草地碳效应的影响及其稳定性的关键指标评价（自然科学基金项目，31070431，主持人）

11. 2009-2011年，不同土地利用方式对羊草草地土壤碳固存效应和稳定性的影响（自然科学基金项目，40803024，主持人）

主要论文：

近五年的10篇代表作（*为通讯作者， #为共同第一作者）

1. Cen XY, Vitousek P, He NP*, Bond-Lamberty B, Niu SL, Du EZ, Yu KL, Zheng MH, van Sundert K, Paulus EL, He LY, Xu L, Li MX, Butterbach-Bahl C. 2026. A general framework for nitrogen deposition effects on soil respiration in global forests. Nature Communications, 17: 506.

2. Yan P, He NP*, Yu KL, Sack L, Jiang L, Fernández-Martínez M. 2026. Plant elemental diversity increases ecosystem productivity and temporal stability. Ecological Monographs, In press.

3. Cai WX, He NP*, Xu L*, Guo HB, Zhou ZH, Wen D, Bai XY, Yu GR. 2025. Rapid increase in carbon sink from China’s urban forests. Science Bulletin, 70: 3333-3336.

4. Cen XY, He NP*, Van Sundert K, Terrer C, Yu KL, Li MX, Xu L, He LY, Butterbach-Bahl K. 2025. Global patterns of nitrogen saturation in forests. One Earth, 8:1-13.

5. He NP*#, Yan P#, Liu CC, Xu L, Li MX, Van Meerbeek K, Zhou GS, Zhou GY, Liu SR, Zhou XH, Li SG, Niu SL, Han XG, Buckley TN, Sack L*, Yu GR*. 2023. Predicting ecosystem productivity based on plant community traits. Trends in Plant Science, 28: 43-52.

6. Liu CC, Sack L, Li Y, Zhang JY, Yu KL, Zhang QY, He NP*, Yu GR. 2023. Relationships of stomatal morphology to the environment across plant communities. Nature Communications, 14: 6629.

7. Cai WX, He NP*, Li MX, Xu L, Wang LZ, Zhu JX, Zeng N, Yan P, Si GX, Zhang XQ, Cen XY, Yu GR, Sun JX. 2022. Carbon sequestration of Chinese forests from 2010–2060: spatiotemporal dynamics and its regulatory strategies. Science Bulletin, 67: 836-843.

8. He NP*#, Li Y#, Liu CC, Xu L, Li MX, Zhang JH, He JS, Tang ZY, Han XG, Ye Q, Xiao CW, Yu Q, Liu SR, Sun W, Niu SL, Li SG, Sack L*, Yu GR* (2020) Plant trait networks: Improved resolution of the dimensionality of adaptation. Trends in Ecology and Evolution, 35: 908-918.

9. He NP*, Liu CC, Piao SL, Sack L, Xu L, Luo YQ, He JS, Han XG, Zhou GS, Zhou XH, Lin Y, Yu Q, Liu SR, Sun W, Niu SL, Li SG, Zhang JH, Yu GR*. 2019. Ecosystem traits linking functional traits to macroecology. Trends in Ecology & Evolution, 34, 200-210.

10. Yu GR#*, Jia YL#, He NP#, Zhu JX, Chen Z, Wang QF, Piao SL, Liu XJ, He HL, Guo XB, Wen Z, Li P, Ding GA, Goulding K. 2019. Stabilization of atmospheric nitrogen deposition in China over the past decade. Nature Geoscience, 12, 12, 424-429.

其它论文 (按年代排序, *通讯作者)

1. Deng YB, Li MX*, Kang XY, Xu L, Liang BM, Chen JK, Yu LL, Wang XB, Zhang XY, Qin MZ, Peng CH, He NP*. 2026. Climate warming and forest expansion significantly enhance China’s forest methane sink. Agricultural and Forest Meteorology, 377: 110935.

2. Liu C, Li J*, Parr CL, it Guénard B, Cen XY, Chai H, Li MX, Zhong ZW, Zhao SL, He NP. 2026. Soil invertebrate body size groups and effect magnitude jointly influence global soil CO₂ emissions. Global Change Biology, In press.

3. Peng B, Zhou ZY*, Xu L, He NP*. 2026. Assessing spatial variation in carbon stocks across China’s wetland ecosystems. Resource, Conservation & Recycling, 227: 108763.

4. Tang JY, Ma HB, Li CL, Zhang JJ*, He NP*. 2026. Microbial- rather than plant-derived carbon contrigutes more to organic carbon accumulation in grassland soils of northern China. Soil Ecology Letters, 8: 250366.

5. Wang RL, Kong DL*, Han MX, Sack L, Lambers H, Cornelissen HC, Li Q, Zhang SX, Wang X, Wang ZB, Sun TY, He NP*, Yu GR*. 2026. Root quantity traits: a leading dimension in root trait space. New Phytologist, doi: 10. 1111/nph. 71073.

6. Zhang JH, Yu KL, Markus Reichstein, Wright IJ, Migliavacca M, Gomarasca U, Laughlin DC, Cen XY, Liu CC, He HL, He NP*. 2026. Trait space and compactness: A new perspective on explaining variations in primary productivity. Ecology, 107: e70278.

7. Cai WX, Xu L*, Wen D, Zhou ZY, Li MX, Wang T, He NP*. 2025. The carbon sequestration potential of vegetation over the Tibetan Plateau. Renewable and Sustainable Energy Reviews, 207: 114937.

8. Cao ZY, Liu Z, Li XT, Li CL, Zong N, Zhang JJ*, He NP*. 2025. Distribution of phosphorus forms along the altitude gradient in the soil of the Qinghai-Tibetan Plateau and the influencing factors. Agronomy, 15: 2474.

9. Gou HB, Zhang JH*, Kang XY, Yu C, He NP* 2025. Aridity-driven non-linear shift of plant sodium allocation strategy at regional and global scales. Global Ecology and Biogeography, 34: e70025.

10. Li MX, He NP*, Xu L, Kang XY, Peng CH, Zhu QA, Zhang KR, Liang BM, Chen JK, Yu LL, Deng YB, Wang XB, Zhang XY, Chen H*. 2025. Ambitious hydropower plans will accelerate greenhouse gases emissions from the Hindu-Kush Himalaya region. Renewable and Sustainable Energy Reviews, 215: 115616.

11. Liu CC, Sack L, Baird AS, Li Y, Zhang JH, Yu KL, Yu GR, He NP*. 2025. Reply to: Differences between dumbbell and kindney-bean stomatal types may influence relationships between stomatal traits and the environment. Nature Communications, 16: 6337.

12. Liu CC, Huang KX, Li Y, Wang JM, He NP*. 2025. Phylogeny override environmental effects in explaining leaf and root nutrient concentrations in Fabaceae. Journal of Ecology, 113: 3177-3190.

13. Liu CC, Muir DC*, Sack L, Li Y, Xu L, Li MX, Zhang JH, de Boer HJ, Han XG, Yu GR, He NP*. 2025. Bounds on stomatal size can explain scaling with stomatal density in forest plants. New Photologist, 248: 2910-2926.

14. Shi MY, Zhang JH, Yu HL*, Mu Q, He NP*. 2025. Changes in plant community traits and relationship to productivity during temperate forest restoration. Journal of Forestry Research, 36: 88.

15. Wang FY, Xue MM, Zhou LM, Doughty CE, Ciais P, Reich PB, Shang JL, Chen JM, Liu J, Green JK, Hao DL, Tao SL, Su YJ, Liu LL, Xia JY, Wang H, Yu KL, Zhu ZC, Zhu P, Li X, Liu H, Zeng YL, Yan K, Liu LY, Lafortezza R, Su YX, Meng YQ, Pan YX, Yang XQ, Fu YH, He NP, Yuan WP, Chen XZ. 2025. Contrasting age-dependent leaf acclimation strategies drive vegetation greening across deciduous broadleaf forests in mid- to high latitudes. Nature Plants, doi.org/10.1038/s41477-025-02096-5.

16. Yan P, He NP, Fernandez-Martinez M, Yang X, Zuo YP, Zhang H, Wang J, Chen SP, Song J, Li GY, Valencia E, Wan SQ, Jiang L. 2025. Plant acquisitive strategies promote resistance and temporal stability of semiarid grasslands. Ecology Letters, 28: e70110.

17. Yang QP, Guo BL, Lu MZ, Liu YJ, Kardol P, Reich PB, Bardgett R, Cornelissen JHC, Kraft NJB, Diaz S, Wright IJ, He NP, Hogan JA, PeiYX, Han QW, Li ZJ, Wang Z, Yang WQ, Ding JX, Yang ZL, Wu HF, Carmona CP, Valverde-Barrantes O, Li DZ, Cai J, Zeng H, Zhang Y, Ren WZ, Zhao Y, Yang XT, Fan GQ, Wang JJ, Li GY, Kong DL. 2025. Arbuscular mycorrhizal association regulates global root-seed coordination. Nature Plants,https://doi.org/10.1038/s41477-025-02089-4.

18. Yu LL，Li MX*, Kang XY, Xu L, Liang BM, Cheng JK, Deng YB, Wang XB, Zhang XY, Qin MZ, Peng CH, He NP*. 2025. Climate warming plays an important role in dissolved organic carbon loss in deep soil layers across China. Catena, 259: 109404.

19. Yu LL, Li MX, Kang XY, Xu L, Liang BM, Chen JK, Deng YB, Chen H, He NP. 2025. Climate warming and soil drying lead to a reduction of reverine dissolved organic carbon in China. Global Biogeochemical Cycles, doi: 10.1029/2025GB008665.

20. Yu Q, Xu C, Wu HH, Ke YG, Zuo XA, Luo WT, Ren HY, Gu Q, Wang HQ, Ma W, Knapp AK, Collins SL, Rudgers JA, Luo YQ, Hautier Y, Wang CJ, Wang ZW, Jiang Y, Hang GD, Gao YZ, He NP, Zhu JT, Dong SK, Xin XP, Yu GR, Smith MD, Li LH, Han XF. 2025. Contrasting drought sensitivity of Eurasian and North American grasslands. Nature, 639: 114-118.

21. Zhang S, Liu Y, He NP. 2025. Leaf size variation in four ground-floor bryophytes and their envirnomental drivers across the forests of the eastern Qinghai-Tibet Plateau. Ecological Indicators, 173: 113347.

22. Zhu JX, Jia YL, Yu GR, Wang QF, He NP, Chen Z, He HL, Zhu XJ, Li P, Zhang FS, Liu XJ, Goulding K, Fowler D, Vitousek. 2025. Changing patterns of global nitrogen deposition driven by socio-economic development. Nature Communications, 16: 46.

23. Zhao SL, Chai H, Liu Y, Wang XC, Jiao CL, Liu C, Xu L, Li J, He NP. 2025. Earthworms significantly enhance the temperature sensitivity of soil organic matter decomposition: Insights into future soil carbon budgeting. Agricultural and Forest Meteorology, 362:110384.

24. Cai WX, He NP*, Xu L. 2024. Spatial distribution of vegetation carbon stock among different organs over the Tibetan Plateau: on an intensive field survey. Journal of Forestry Research. 2024, 35: 143.

25. Cen XY, He NP*, Li MX, Xu L, Yu XY, Cai WX, Li X, Butterbach-Bahl K. 2024. Suppression of Nitrogen deposition on global forest soil CH₄ uptake depends on nitrogen status. Global Biogeochemical Cycles, 38: e2024GB008098.

26. Cen XY, Muller C, Kang XY*, Zhou XH, Zhang JB, Yu GR, He NP*. 2024. Nitrogen deposition contributed to a global increase in nitrous oxide emission from forest soils. Communications Earth & Environment, 5: 532.

27. Cheng CJ, Zhang JH*, Li MX, Liu CC, Xu L, He NP*. 2024. Vertical structural complexity of plant communities represents the combined effect of resource acquisition and environmental stress on the Tibetan Plateau. Communications Biology, 7: 395.

28. Jiao CL, Zhang JH, Yu HL, He NP. 2024. Variation of magnesium drives plant adaptation to heterogeneous environments by regulating efficiency in photosynthesis on a large scale. Journal of Ecology, doi: 10.1111/1365-2745.14411.

29. Li Y, He NP*. 2024. Innovations and prospectives of multidimensional trait integration. New Phytologist, doi: 10.1111/nph.19909

30. Liu CC*, Huang KX, Zhao YF, Li Y, He NP*. 2024. A continental-scale analysis reveals the latitudinal gradient of stomatal density across amphistomatous species: Evolutionary history vs. present-day environment. Annals of Botany, doi.org/10.1093/aob/mcae135

31. Pan J, Liu Y, He NP*, Li C, Li MX, Xu L, Sun JX*. 2024. The influence of forest-to-cropland conversion on temperature sensitivity of soil microbial respiration across tropical to temperate zones. Soil Biology and Biochemistry, 191: 109322.

32. Quan Q, He NP, Zhang RY, Wang JS, Luo YQ, Ma FF, Pan JX, Wang RM, Liu CC, Zhang JH, Wang YH, Song B, Li ZL, Zhou QP, Yu GR, Niu SL. 2024. Plant heights as an indicators for alpine carbon sequestration and ecosystem response to warming. Nature Plants, doi.org/10.1038/s41477-024-01705-z.

33. Wang XC, Chen S, Yang X, Zhu R, Liu M, Wang RL*, He NP*. 2024. Adaptation mechanisms of leaf vein traits to drought in grassland plants. Science of the Total Environment, 917: 170224.

34. Wang YJ, Xiao CW*, Liu CC, He NP*. 2024. The response of grassland productivity to atmospheric nitrogen deposition in northern China. Agriculture, Ecosystems and Environment, 359: 108764.

35. Xu L*, He NP*, Li MX, Cai WX, Yu GR. 2024. Spatiotemperal dynamics of carbon sinks in China’s terrestrial ecosystems from 2010 to 2060. Resources, Conservation & Recycling, 203: 107457.

36. Yu C, Xu L, He NP, Li MX, Kang XY. 2024. Optimization of vegetation carbon content parameters and their application in carbon storage estimation in China. Science of the Total Environment, 955: 176912.

37. Zhao WZ, Xiao CW*, Li MX, Xu L, Li X, He NP*. 2024. Spatial variation of sulfur in terrestrial ecosystems in China: Content, density, and storage. Science of the Total Environment, 906: 167848.

38. Zhang JH, Wang XM, Hou JH*, Li X, LI MX, Zhao WZ, He NP*. 2024. High-resolution community-level sodium variation on the Tibetan Plateau: Content, density, and storage. Science of the Total Environment, https://doi.org/10.1016/j.scitotenv.2024.173766

11. Cheng CJ, He NP*, Li MX, Xu L, Osbert Sun JX*. 2023. Spatial assembly of grassland communities and interrelationships with productivity. Functional Ecology, doi: 10.1111/1365-2435.14306.

12. Cheng CJ, Osbert Sun JX, Li MX, Xu L, Cai WX, Li X, Zhao WZ, Li C, Wang JM, He NP*. 2023. Plant species richness on the Tibetan Plateau: Patterns and determinants. Ecography, 2023: e06265.

13. Li MX, He NP*, Xu L, Peng CH, Chen H, Yu GR. 2023. Eco-CCUS: A cost-effective pathway towards carbon neutrality in China. Renewable and Sustainable Energy Reviews, 183:113512.

14. Liu ZG#, Zhao M#, Zhang HX, Ren TT, Liu CC, He NP*. 2023. Divergent response and adaptation of specific leaf area to environmental change at different spatio-temporal scales jointly improve plant survival. Global Change Biology, 29:1144-1159.

15. Yan P, Zhang JH*, He NP*, Zhang WK, Liu CC, Fernandez-Martinez M. 2023. Functional diversity and soil nutrients regulate the interannual variability in gross primary productivity. Journal of Ecology, 111: 1094-1106.

16. Yan P, Fernández-Martínez M, Van Meerbeek K, Yu GR, Migliavacca M, He NP*. 2023. The essential role of biodiversity in the key axes of ecosystem function. Global Change Biology, 29: doi 10.1111/gcb.16666.

17. Zhang QY, Zhu JX, Mulder J, Wang QF, Liu CQ, He NP*. 2023. High environmental costs behand rapid economic development: Evidence from economic loss caused by atmospheric acid deposition. Journal of Environmental Management, 334: 117511.

18. Zhang QY; Zhu JX; Wang QF; Mulder J; Liu CQ, He NP*. 2023. Transformation from NHx to NOy deposition aggravated China’s forest soil acidification. Global Biogeochemical Cycles, doi.org/10.1029/2023GB007736.

19. Zhao WZ, Xiao CW*, Li MX, Xu L, Li X, Zhu XY, Cheng CJ, He NP*. 2023. Biogeographic patterns of sulfur in the vegetation of the Tibetan Plateau. Journal of Geophysical Research: Biogeosciences, 128: e2022JG007051.

20. Zhu XY, Hou JH*, Li MX, Xu L, Li X, Li Y, Cheng CJ, Zhao WZ, He NP*. 2023. High-resolution spatial distribution of vegetation biomass and its environmental response on Qinghai-Tibet Plateau: Intensive grid-field survey. Ecological Indicators, 149: 110167.

21. Cen XY, Li MX*, Xu L, Zhu JX, He NP*. 2022. Atmospheric N deposition significantly enhanced soil N2O emission from eastern China forests. Global Biogeochemical Cycles, 36: e2021GB007289.

22. Li MX, He NP*. 2022. Carbon intensity of global existing and future hydropower reservoirs. Renewable and Sustainable Energy Reviews, 162: 112433.

23. Li C, Xiao CW*, Guenet B, Li MX, Xu L, He NP*. 2022. Short-term effects of labile organic C addition on soil microbial response to temperature in a temperature steppe. Soil Biology & Biochemistry, 167: 108589.

24. Li CN, Liao HJ, Xu L, Wang CT, He NP*, Wang JM, Li XZ*. 2022. The adjustment of life history strategies drives the ecological adaptations of soil microbiota to aridity. Molecular Ecology, doi: 10.1111/mec.16445

25. Li X, Li MX, Xu L, Liu CC, Zhao WZ, Cheng CJ, He NP*. 2022. Allometry and distribution of nitrogen in natural plant communities of the Tibetan Plateau. Frontiers in Plant Science, 13: 845813.

26. Li Y, Liu CC*, Sack L, Xu L, Li MX, Zhang JH, He NP*. 2022. Leaf trait network architecture shifts with species-richness and climate across forests at continental scale. Ecology Letters, 25: 1442-1457.

27. Li Y, Hou JH*, Xu L, Li MX, Chen Z, Zhang ZH, He NP*. 2022. Variation in functional trait diversity from tropical to cold-temperature forests and linkage to productivity. Ecological Indicators, 138: 108864.

28. Liu CC, Li Y, He NP*. 2022. Differential adaptation of lianas and trees in wet and dry forests revealed by trait correlation networks. Ecological Indicators, 135: 108564.

29. Liu CC, Sack L, Li Y, He NP*. 2022. Contrasting adaptation and optimization of stomatal traits across communities at continental-scale. Journal of Experimental Botany, doi: erac266.

30. Wang RM, Li MX, Xu L, Li SG*, He NP*. 2022. Scaling-up methods influence on the spatial variation in plant community traits: Evidence based on leaf nitrogen content. Journal of Geophysical Research: Biogeoscience: 127, e2021/2021/

31. Yan P, Li MX, Yu GR, Qi Y, He NP*. 2022. Plant community traits associated with nitrogen can predict spatial variability in productivity. Ecological Indicators, 140: 109001.

32. Zhang QY, Zhu JX*, Wang QF, Xu L, Li MX, Dai GH, Mulder J, Xi Y, He NP*. 2022. Soil acidification in China’s forests due to atmospheric acid deposition from 1989 to 2050. Science Bulletin, 67: 914-917.

33. Zhang JH, Hedin L, Li MX, Xu L, Yan P, Dai GH, He NP*. 2022. Leaf N:P ratio does not predict productivity trends across natural terrestrial ecosystems. Ecology, doi: 10.1002/ecy.3789.

34. Zhao WZ, Xiao CW*, Li MX, Xu L, He NP*. Variation and adaptation in leaf sulfur content across China.

2022. Journal of Plant Ecology, doi: 10.1093/jpe/rtac021.

35. Zhao WZ, Xiao CW*, Li MX, Xu L, Li X, He NP*. 2022. Spatial variation and allocation of sulfur among major plant organs in China. Science of the Total Environment, 844: 157155.

36. Li Y, Liu CC, Xu L, Li MX, Zhang JH, He NP*. 2021. Leaf trait networks based on global data: Representing variation and adaptation in plants. Frontiers in Plant Science, 12: 710530.

37. Li Y, Li Q, Xu L, Li MX, Chen Z, Song ZP, Hou JH*, He NP*. 2021. Plant community traits can explain variation in productivity of selective logging forests after different restoration times. Ecological Indicators, 131: 108181.

38. Liu ZG, Dong N, Zhang HX*, Zhao M, Ren TT, Liu CC, Westerband A, He NP*. 2021. Divergent long- and short-term responses to environmental gradients in specific leaf area of grassland species. Ecological Indicators, 130: 108058.

39. Liu CC, Li Y, Yan P, He NP*. 2021. How to improve the predictions of plant functional traits on ecosystem functioning? Frontiers in Plant Sciences, 12: 622260.

40. Liu CC, Li Y, Xu L, Li MX, Wang JM, Yan P, He NP*. 2021. Stomatal arrangement pattern: A new direction to explore plant adaptation and evolution. Frontiers in Plant Sciences, 12: 655255.

41. Ren TT, He NP*, Liu ZG, Li MX, Zhang JH, Li Y, Wei CZ, Lv XT, Han XG*. 2021. Environmental filtering rather than phylogeny determines plant leaf size in three floristically distinctive plateaus. Ecological Indicators, 130: 108049.

42. Sun JG, Liu CC, Hou JH*, He NP*. 2021. Spatial variation of stomatal morphological traits in grassland plants of the Loess Plateau. Ecological Indicators, 128: 107857.

43. Wang RM, He NP*, Li SG, Xu L, Li MX. 2021. Variation and adaptation of leaf water content among species, communities, and biomes. Environmental Research Letters, 16:124038.

44. Wang RL, He NP*, Yu GR*. 2021. Root community traits: scaling-up and incorporating roots into ecosystem functional analyses. Frontiers in Plant Science, 12: 690235.

45. Xu L#, He NP#, Li XZ, Cao HL, Li CN, Wang RL, Wang CH, Yao MJ, Zhou SG, Wang JM. 2021. Local community assembly processes shape β-diversity of soil phoD-harbouring communities in the Northern Hemisphere steppes. Global Ecology and Biogeography, 30: 2273-2285

46. Zhang JH, Li MX, Xu L, Zhu JX, Dai GH, He NP*. 2021. C:N:P stoichiometry in terrestrial ecosystems in China. Science of the Total Environment, 795: 148849.

47. Zhang Y, He NP*, Li MX, Yan P, Yu GR. 2021. Community chlorophyll quantity determines the spatial variation of grassland productivity. Science of the Total Environment, 801: 149567

48. Zhang JH, Ren TT, Yang JJ, Xu L, Li MX, Zhang YH, Han XG, He NP*. 2021. Leaf multi-element network reveals the change of species dominance under nitrogen deposition. Frontier in Plant Science, 12: 580340.

49. Liu CC, Li Y, Zhang JH, Bird AS, He NP*. 2020. Optimal community assembly related to leaf economic-hydraulic-anatomical traits. Frontiers in Plant Science, 11, 341.

50. Wang S, Xu L, Zhuang QL, He NP*. 2020. Investigating the spatio-temporal variability of soil organic carbon stocks in different ecosystems of China. Science of the Total Environment, 758: 143644.

51. Xu L, He NP*, Yu GR. 2020. Nitrogen storage in China’s terrestrial ecosystems. Science of the Total Environment, 709, 136201.

52. Xu L, He NP*. 2020. Nitrogen storage and allocation in China’s forest ecosystems. Science China-EarthSciences, 63, 1475-1484.

53. Yan P#, Xiao CW#, Xu L, Li A, Yu GR, Piao SL, He NP*. 2020. Biomass energy in China's terrestrial ecosystems: Insights into the nation’s sustainable energy supply. Renewable & Sustainable Energy Reviews, 127, 109857.

54. Zhang QY, Wang QF, Zhu JX, Xu L, Li MX, Rengel Z, Xiao JF, Hobbie EA, Piao SL, Luo WT, He NP*. 2020. Higher soil acidification risk in southerastern Tibetan Plateau. Science of Total Environment, 755: 143372.

55. Zhang JH, He NP*, Liu CC, Xu L, Chen Z, Li Y, Wang RM, Yu GR, Sun W, Xiao CW, Chen HYH, Reich PB. 2020. Variation and evolution of C:N ratio among different organs enable plants to adapt to N-limited environments. Global Change Biology, 26, 2534-2543.

56. He HL, Wang SQ, Zhang L, Wang JB, Ren XL, Zhou L, Piao SL, Yan H, Ju WM, Gu FX, Yu SY, Yang, YH, Wang MM, Niu ZG, Ge R, Yan HM, Huang M, Zhou GY, Bai YF, Xie ZQ, Tang ZY, Wu BF, Zhang LM, He NP, Wang QF, Yu GR. 2019a. Altered trends in carbon uptake in China's terrestrial ecosystems under the enhanced summer monsoon and warming hiatus. National Science Review, 6, 505-514.

57. Liu Y, He NP*, Xu L, Tian J, Gao Y, Zheng S, Wang Q, Wen XF, Xu XL, Yakov K. 2019. A new incubation and measurement approach to estimate the temperature response of soil organic matter decomposition. Soil Biology & Biochemistry, 138, 107596.

58. Wu HH, Lu LY, Zhang YL, Xu C, Yang H, Zhou W, Wang WQ, Zhao LR, He NP*, Smith MD, Han XG, Hartley IP, Yu Q*. 2019.Sediment addition and legume cultivation result in sustainable, long-term increases in ecosystem functions of sandy grasslands. Land Degradation & Development, 30, 1667-1676.

59. Zhao N, Yu GR*, Wang QF, Wang RL, Zhang JH, Liu, CC, He NP*. 2019b. Conservative allocation strategy of multiple nutrients among major plant organs: From species to community. Journal of Ecology, 10.1111/1365-2745.13256.

60. Guan S, An N, Zong N, He YT, Shi P, Zhang JJ*, He NP*. 2018b. Climate warming impacts on soil organic carbon fractions and aggregate stability in a Tibetan alpine meadow. Soil Biology & Biochemistry, 116, 224-236.

61. He NP#*, Liu CC#, Tian M#, Li ML, Yang H, Yu GR, Guo DL, Smith MD, Yu Q, Hou JH*. 2018. Variation in leaf anatomical traits from tropical to cold-temperate forests and linkage to ecosystem functions. Functional Ecology, 32, 10-19.

62. Liu CC, He NP*, Zhang JH, Li Y, Wang QF, Sack L, Yu GR. 2018a. Variation of stomatal traits from cold temperate to tropical forests and association with water use efficiency. Functional Ecology, 32, 20-28.

63. Liu Y, He NP*, Wen XF, Xu L, Sun XM, Yu GR, Liang LY, Schipper LA. 2018b. The optimum temperature of soil microbial respiration: Patterns and controls. Soil Biology & Biochemistry, 121, 35-42.

64. Liu Y, Wen XF, Zhang YH, Tian J, Gao Y, Ostle AJ, Niu SL, Chen SP, Sun XM, He NP*. 2018c. Widespread asymmetric response of soil heterotrophic respiration to warming and cooling. Science of the Total Environment, 635, 423-431.

65. Lu F, Hu HF, Sun WJ, Zhu JJ, Liu GB, Zhou WM, Zhang QF, Shi PL, Liu XP, Wu X, Zhang L, Wei XH, Dai LM, Zhang KR, Sun YR, Xue S, Zhang WJ, Xiong DP, Deng L, Liu BJ, Zhou L, Zhang C, Zheng X, Cao JS, Huang Y, He NP, Zhou GY, Bai YF, Xie ZQ, Tang ZY, Wu BF, Fang JY, Liu GH, Yu GR. 2018. Effects of national ecological restoration projects on carbon sequestration in China from 2001 to 2010. PNAS, 115, 4039-4044.

66. Tang XL, Zhao X, Bai YF, Tang ZY, Wang WT, Zhao YC, Wan HW, Xie ZQ, Shi XZ, Wu BF, Wang GX, Yan JH, Ma KP, Du S, Li SG, Han SJ, Ma YX, Hu HF, He NP, Yang YH, Han WX, He HL, Yu GR, Fang JY, Zhou GY. 2018a. Carbon pools in China's terrestrial ecosystems: New estimates based on an intensive field survey. PNAS, 115: 4021-4026.

67. Tang ZY, Xu WT, Zhou GY, Bai YF, Li JX, Tang XL, Chen DM, Liu Q, Ma WH, Xiong GM, He HL, He NP, Guo YP, Guo Q, Zhu JL, Han WX, Hu HF, Fang JY, Xie ZQ. 2018c. Patterns of plant carbon, nitrogen, and phosphorus concentration in relation to productivity in China's terrestrial ecosystems. PNAS, 115, 6095-6096.

68. Tian J, He NP#, Hale L, Niu SL, Yu GR, Liu Y, Blagodatskaya E, Kuzyakov Y, Gao Q, Zhou JZ. 2018a. Soil organic matter availability and climate drive latitudinal patterns in bacterial diversity from tropical to cold temperate forests. Functional Ecology, 32, 61-70.

69. Wang CH, Wang NN, Zhu JX, Liu Y, Xu XF, Niu SL, Yu GR, Han XG, He NP*. 2018a. Soil gross N ammonification and nitrification from tropical to temperate forests in eastern China. Functional Ecology, 32, 83-94.

70. Wang Q, He NP*, Xu L, Zhou XH. 2018b. Microbial properties regulate spatial variation in the differences in heterotrophic respiration and its temperature sensitivity between primary and secondary forests from tropical to cold-temperate zones. Agricultural and Forest Meteorology, 262, 81-88.

71. Wang Q, He NP*, Liu Y, Li ML, Xu L, Zhou XH. 2018c. Important interaction of chemicals, microbial biomass and dissolved substrates in the diel hysteresis loop of soil heterotrophic respiration. Plant and Soil, 428, 279-290.

72. Wang RL, Wang QF, Zhao N, Xu ZW, Zhu XJ, Jiao CC, Yu GR*, He NP*. 2018e. Different phylogenetic and environmental controls of first-order root morphological and nutrient traits: Evidence ofmultidimensional root traits. Functional Ecology, 32, 29-39.

73. Zhang JH, Zhao N, Liu CC, Yang H, Li ML, Yu GR, Wilcox K, Yu Q*, He NP*. 2018a. C:N:P stoichiometry in China's forests: From organs to ecosystems. Functional Ecology, 32, 50-60.

74. Zhang JH, He NP*, Liu CC, Xu L, Yu Q, Yu GR. 2018b. Allocation strategies for nitrogen and phosphorus in forest plants. Oikos, 127, 1506-1514.

75. Zhang YH*, He NP*, Loreau M, Pan QM, Han XG*. 2018e. Scale dependence of the diversity-stability relationship in a temperate grassland. Journal of Ecology, 106, 1277-1285.

76. Zhao N, Liu HM, Wang QF, Wang RL, Xu ZW, Jiao CC, Zhu JX, Yu GR*, He NP*. 2018b. Root elemental composition in Chinese forests: Implications for biogeochemical niche differentiation. Functional Ecology, 32, 40-49.

77. Zheng S, Bian HF*, Quan Q, Xu L, Chen Z, He NP*. 2018. Effect of nitrogen and acid deposition on soil respiration in a temperate forest in China. Geoderma, 329, 82-90.

78. He NP*#, Wen D#, Zhu JX, Tang XL, Xu L, Zhang L, Hu HF, Huang M, Yu GR*. 2017. Vegetation carbon sequestration in Chinese forests from 2010 to 2050. Global Change Biology, 23, 1575-1584.

79. Li CL, Cao ZY, Chang JJ, Zhang Y, Zhu GL, Zong N, He YT, Zhang JJ*, He NP*. 2017a. Elevational gradient affect functional fractions of soil organic carbon and aggregates stability in a Tibetan alpine meadow. Catena, 156, 139-148.

80. Li J, He NP*, Xu L*, Chai H, Liu Y, Wang DL, Wang L, Wei XH, Xue JY, Wen XF, Sun XM. 2017c. Asymmetric responses of soil heterotrophic respiration to rising and decreasing temperatures. Soil Biology & Biochemistry, 106, 18-27.

81. Liu Y, He NP*, Zh, JX, X, L, Y, GR, Ni, SL, Su, XM, We, XF*. 2017a. Regional variation in the temperature sensitivity of soil organic matter decomposition in China's forests and grasslands. Global Change Biology, 23, 3393-3402.

82. Liu Y#, Wang CH#, He NP*, Wen XF, Gao Y, Li SG, Niu SL, Butterbach-Bahl K, Luo YQ, Yu GR*. 2017b. A global synthesis of the rate and temperature sensitivity of soil nitrogen mineralization: latitudinal patterns and mechanisms. Global Change Biology, 23, 455-464.

83. Yu HL, He NP#, Wang QF*, Zhu JX, Gao Y, Zhang YH, Jia YL, Yu GR. 2017. Development of atmospheric acid deposition in China from the 1990s to the 2010s. Environmental Pollution, 231, 182-190.

84. Zhang YH*, Loreau M, He NP*, Zhang GM, Han XG*. 2017. Mowing exacerbates the loss of ecosystem stability under nitrogen enrichment in a temperate grassland. Functional Ecology, 31, 1637-1646.

85. Zhu JX, He NP*, Zhang JH, Wang QF, Zhao N, Jia YL, Ge JP, Yu GR*. 2017. Estimation of carbon sequestration in China's forests induced by atmospheric wet nitrogen deposition using the principles of ecological stoichiometry. Environmental Research Letters, 12, 10.1088/1748-9326/aa1094a1084.

86. Li N, He NP*, Yu GR*, Wang QF, Sun J. 2016. Leaf non-structural carbohydrates regulated by plant functional groups and climate: Evidences from a tropical to cold-temperate forest transect. Ecological Indicators, 62, 22-31.

87. Liu Y, He NP*, Wen XF, Yu GR, Gao Y, Jia YL. 2016. Patterns and regulating mechanisms of soil nitrogen mineralization and temperature sensitivity in Chinese terrestrial ecosystems. Agriculture Ecosystems & Environment, 215, 40-46.

88. Wang Q, He NP*, Liu Y, Li ML, Xu L. 2016a. Strong pulse effects of precipitation events on soil microbial respiration in temperate forests. Geoderma, 275, 67-73.

89. Wang Q, He NP*, Yu GR, Gao Y, Wen XF, Wang RF, Koerner SE, Yu Q*. 2016b. Soil microbial respiration rate and temperature sensitivity along a north-south forest transect in eastern China: Patterns and influencing factors. Journal of Geophysical Research-Biogeosciences, 121, 399-410.

90. Wen D, He NP*. 2016. Forest carbon storage along the north-south transect of eastern China: Spatial patterns, allocation, and influencing factors. Ecological Indicators, 61, 960-967.

91. Yu HL, He NP*, Wang QF*, Zhu JX, Xu L, Zhu ZL, Yu GR. 2016b. Wet acid deposition in Chinese natural and agricultural ecosystems: Evidence from national-scale monitoring. Journal of Geophysical Research-Atmospheres, 121, 10995-11005.

92. Zhao N, Yu GR*, He NP*, Wang QF, Guo DL, Zhang XY, Wang RL, Xu ZW, Jiao CC, Li NN, Jia YL. 2016. Coordinated pattern of multi-element variability in leaves and roots across Chinese forest biomes. Global Ecology and Biogeography, 25, 359-367.

93. Zhu JX, Wang QF*, Yu HL, Li ML, He NP*. 2016a. Heavy metal deposition through rainfall in Chinese natural terrestrial ecosystems: Evidences from national-scale network monitoring. Chemosphere, 164, 128-133.

94. Zhu JX, Wang QF, He NP*, Smith MD, Elser JJ, Du JQ, Yuan GF, Yu GR, Yu Q*. 2016b. Imbalanced atmospheric nitrogen and phosphorus depositions in China: Implications for nutrient limitation. Journal of Geophysical Research-Biogeosciences, 121, 1605-1616.

95. He NP*, Zhu JX, Wang QF. 2015. Uncertainty and perspectives in studies of atmospheric nitrogen deposition in China: A response to Liu et al. 2015. Science of the Total Environment, 520: 302-304.

96. Xu L, He NP*, Yu GR*, Wen D, Gao Y, He HL. 2015.. Differences in pedotransfer functions of bulk density lead to high uncertainty in soil organic carbon estimation at regional scales: Evidence from Chinese terrestrial ecosystems. Journal of Geophysical Research-Biogeosciences, 120: 1567-1575.

97. Zhu JX, He NP*, Wang QF,* Yuan GF, Wen D, Yu GR, Jia YL. 2015. The composition, spatial patterns, and influencing factors of atmospheric wet nitrogen deposition in Chinese terrestrial ecosystems. Science of the Total Environment, 511:777-785.

98. He NP, Wang RM, Zhang YH, Chen QS. 2014. Carbon and nitrogen storage in inner mongolian grasslands: relationships with climate and soil texture. Pedosphere, 24:391-398.

99. Gao Y*, He NP*, Wang QF, Miao CY. 2013. Increase of external nutrient input impact on carbon sinks in Chinese coastal seas. Environmental Science & Technology, 47: 13215-13216.

100. He NP, Wang RM, Gao Y, Dai JZ, Wen XF*, Yu GR*. 2013. Changes in the temperature sensitivity of SOM decomposition with grassland succession: implications for soil C sequestration. Ecology and Evolution, 3:5045-5054.

101. He NP, Chen QS*, Han XG, Yu GR, Li LH. 2012a. Warming and increased precipitation individually influence soil carbon sequestration of Inner Mongolian grasslands, China. Agriculture Ecosystems, Environment, 158: 184-191

102. He NP*, Zhang YH, Dai JZ, Han XG, Yu GR. 2012b. Losses in carbon and nitrogen stocks in soil particle-size fractions along cultivation chronosequences in inner mongolian grasslands. Journal of Environmental Quality, 41: 1507-1516.

103. He NP, Zhang YH, Dai JZ, Han XG, Baoyin TGT, Yu GR*. 2012c. Land-use impact on soil carbon and nitrogen sequestration in typical steppe ecosystems, Inner Mongolia. Journal of Geographical Sciences, 22: 859-873.

104. He NP, Zhang YH, Yu Q, Chen QS, Pan QM, Zhang GM, Han XG*. 2011b. Grazing intensity impacts soil carbon and nitrogen storage of continental steppe. Ecosphere, 2(1): art8.

105. Jiang SC, He NP*, Wu L, Zhou DW*. 2010. Vegetation restoration of secondary bare saline-alkali patches in the Songnen plain. China Applied Vegetation Science, 13: 47-55.

106. He NP*, Wu L, Wang YS, Han XG. 2009. Changes in carbon and nitrogen in soil particle-size fractions along a grassland restoration chronosequence in northern China. Geoderma, 150: 302-308.

107. He NP*, Yu Q, Wu L, Wang YS, Han XG. 2008. Carbon and nitrogen store and storage potential as affected by land-use in a Leymus chinensis grassland of northern China. Soil Biology, Biochemistry, 40: 2952-2959.

108. Wu L, He, N*, Wang Y, Han X. 2008. Storage and dynamics of carbon and nitrogen in soil after grazing exclusion in Leymus chinensis grasslands of northern China. Journal of Environmental Quality, 37: 663-668.

109. He NP, Han XG*, Pan QM. 2005. Variations in the volatile organic compound emission potential of plant functional groups in the temperate grassland vegetation of Inner Mongolia, China. Journal of Integrative Plant Biology, 47: 13-19.

110. He NP, Han XG*, Sun W, Pan QM. 2004. Biogenic VOCs emission inventory development of temperate grassland vegetation in Xilin River Basin, Inner Mongolia, China. Journal of Environmental Sciences, 16:1024-1032.

111. 刘聪聪, 何念鹏*, 李颖, 张佳慧, 闫镤, 王若梦, 王瑞丽. 2024. 宏观生态学中的植物功能性状研究：历史与发展趋势. 植物生态学报, 48(1): 21-40.

112. 李颖*, 刘聪聪, 何念鹏*. 2024. 植物功能性状网络：概念体系发展与应用进展. 生态学报, 44(18): stxb202401090083。

39. 温丁, 徐丽, 王春燕, 曾嘉霁, 何念鹏*. 2024. 京津冀城区森林植被碳汇遥感评估与预测. 地理科学进展, 43(12): 2520-2529.

113. 蔡伟祥，徐丽，李明旭，孙建新，何念鹏*. 2022. 2010-2060年中国森林生态系统固碳速率省际不平衡性及调控策略. 地理学报, 77(7): 1808-182

114. 于贵瑞, 朱剑兴, 徐丽, 何念鹏. 2022. 中国生态系统碳汇功能提升的技术途径: 基于自然解决方案. 中国科学院院刊, 37(4): 490-501.

115. 何念鹏, 刘聪聪, 徐丽, 于贵瑞*. 2020. 生态系统性状对宏生态研究的启示与挑战. 生态学报, 40(8): 2507-2522.

116. 何念鹏, 徐丽, 何洪林*. 2020. 生态系统质量评估方法的再思考—理想参照系和关键指标. 生态学报, 40(6): 1877-1886.

117. 何念鹏*, 刘远, 徐丽, 温学发, 于贵瑞, 孙晓敏. 2018. 土壤有机质分解温度敏感性研究：培养与测定模式. 生态学报, 38: 4045-4051.

118. 何念鹏*, 刘聪聪, 徐丽, 张佳慧, 于贵瑞. 2018. 植物性状研究之机遇与挑战: 从器官到群落. 生态学报, 38: 6787-6796.

119. 何念鹏, 张佳慧, 刘聪聪, 徐丽, 陈智, 刘远, 王瑞丽, 赵宁, 徐志伟, 田静, 王情, 朱剑兴, 李颖, 侯继华, 于贵瑞*. 2018. 森林生态系统之性状的空间格局与影响因素: 基于中国东部样带整合分析. 生态学报, 38: 6359-6382.

120. 徐丽, 何念鹏*. 2020. 中国森林生态系统氮含量分配特征及其影响因素. 中国科学：地球科学, 50(10), 1374-1385.

121. 李娜妮, 何念鹏*, 于贵瑞, 王若梦, 王瑞丽, 赵宁, 徐志伟. 2016. 中国东北典型森林生态系统植物叶片的非结构性碳水化合物研究. 生态学报, 36: 430-438 .

122. 温丁, 何念鹏*. 2016. 中国森林和草地凋落物现存量的空间分布格局及其控制因素. 生态学报, 36: 2876-2884

123. 柴华, 何念鹏*. 2016. 中国土壤容重特征及其对区域碳贮量估算的意义. 生态学报, 36: 3903-3920.

124. 王瑞丽, 于贵瑞, 何念鹏*, 王秋凤, 赵宁, 徐志伟．2016. 气孔特征与叶片功能性状之间关联性沿海拔梯度的变化规律: 以长白山为例. 生态学报, 36: 2175-2184.

125. 赵宁, 张洪轩, 王若梦, 杨满业, 张艳, 赵小宁, 于贵瑞, 何念鹏*. 2014. 放牧对若尔盖高寒草甸土壤氮矿化及其温度敏感性的影响. 生态学报, 33(15): 4234-4241.

126. 徐丽, 于书霞, 何念鹏*, 温学发, 石培礼, 张扬建, 代景忠, 王若梦. 2013. 青藏高原高寒草地土壤碳矿化及其温度敏感性. 植物生态学报, 37(11): 988-997.

127. 朱剑兴, 王秋凤, 何念鹏*, 王若梦, 代景忠. 2013. 内蒙古不同类型草地土壤氮矿化及其温度敏感性. 生态学报, 33(19): 6320-6327.

128. 王丹, 吕瑜良, 徐丽, 何秀, 徐志伟, 赵宁, 王瑞丽, 何念鹏*. 2013. 植被类型变化对长白山森林土壤碳矿化及其温度敏感性的影响. 生态学报, 33(19): 6373-6381

129. 王若梦, 董宽虎, 何念鹏*, 朱剑兴, 代景忠, 施侃侃. 2013. 围封对内蒙古大针茅草地土壤碳矿化及其激发效应的影响. 生态学报, 33(12): 3622-3629.

130. 王丹, 吕瑜良*, 徐丽, 张洪轩, 王若梦, 何念鹏*. 2013. 水分和温度对若尔盖湿地和草甸土壤碳矿化的影响. 生态学报, 33(20): 6436-6443.

131. 何念鹏*, 韩兴国, 于贵瑞, 代景忠. 2012. 火烧对长期封育草地土壤碳固持效应的影响. 生态学报, 32(14): 4388-4395.

132. 代景忠, 卫智军, 何念鹏*, 王若梦, 温学华, 张云海, 赵小宁, 于贵瑞. 2012. 封育对羊草草地土壤碳矿化激发效应和温度敏感性的影响. 植物生态学报, 36(12): 1226-1236.

133. 何念鹏*, 韩兴国, 于贵瑞. 2012. 内蒙古放牧草地土壤碳固持速率和潜力. 生态学报, 32(3): 844-851.

134. 何念鹏*, 韩兴国, 于贵瑞. 2011. 长期封育对不同类型草地碳贮量及其固持速率的影响生态学报, 31(15): 4270-4276

135. 何念鹏, 王秋凤, 刘颖慧, 任伟, 于贵瑞*. 2011. 区域尺度陆地生态系统碳增汇途径及其可行性分析地理科学进展, 30(7): 788-794

136. 何念鹏, 吴泠, 姜世成, 周道玮*. 2005. 播种虎尾草对松嫩草地次生光碱斑治理的初步研究草业学报, 14(6): 79-81

137. 何念鹏, 韩兴国*, 潘庆民. 2005. 植物源VOCs及其对陆地生态系统碳循环的贡献生态学报, 25(8): 2041-2048

138. 何念鹏, 吴泠, 周道玮. 2004. 扦插玉米秸秆对光碱斑地虎尾草和角碱蓬存活率的影响植物生态学报, 28(2): 258–263

139. 何念鹏, 吴泠, 姜世成, 周道玮*. 2004. 扦插玉米秸秆改良松嫩平原次生光碱斑的研究应用生态学报, 15(6): 969-972

140. 何念鹏, 吴泠, 周道玮. 2004. 松嫩草地次生光碱斑种子流及其生态恢复意义生态学报, 24(6): 843-847

141. 何念鹏, 吴泠, 周道玮. 2004. 放牧对松嫩平原农牧交错区防护林下草地的影响应用生态学报, 15(5): 795-798

142. 何念鹏, 吴泠, 周道玮. 2004. 松嫩草地两种趋异型羊草克隆构型特征比较应用生态学报, 15(10): 2393-2395

143. 何念鹏, 周道玮, 吴泠, 张玉芬. 2001. 人为干扰强度对村级景观破碎度的影响应用生态学报, 12(6): 897-899

144. 何念鹏, 周道玮, 孙刚, 吴泠. 2001. 人为干扰强度对村级景观结构特征的影响农村生态环境, 17(2): 9-12

145. 何念鹏, 周道玮, 孙刚, 吴泠. 2001. 乡村生态学的研究体系与研究趋向探讨东北师大学报 (自然科学版), 33(3): 80-86

专著：

1. 于贵瑞, 何念鹏, 王秋风（编）. 2013.《中国生态系统碳收支及其碳汇功能-理论基础与综合评估》, 科学出版社, 北京.

2. 何念鹏, 于贵瑞, 刘聪聪, 李颖, 王瑞丽（著）. 2024.《植物功能生态学: 从器官到生态系统》, 科学出版社, 北京。

3. He NP, Yu GR, Liu CC, Li Y, Wang RL. 2025. Plant Functional Ecology: From Organ to Ecosystem. Springer Nature.

奖励：

1. 植物群落功能性状及其对生态系统生产力调控机制研究，获2023年度中国生态环境十大进展，排名第1（1/9）

2. “陆地生态系统碳-氮-水循环研究集体”，获2022年度中国科学院杰出科技成就奖（排名4/8）

3. “生态有机碳汇的时空分布规律与驱动机制”，获2022年贵州省自然科学一等奖（排名2/7）

4. “吉林省西部受损草地祼碱斑改造新技术”，获2028年吉林省科技进步二等奖（排名4/11）

其他（专利/软著/标准）：

1. 一种室内土壤微生物呼吸连续测定装置 (201210007361.X)

2. 森林生态系统固碳模型 (Forest carbon sequestration model based on the secondary succession theory [FCS Model], 2016SR110832）

3. 基于次生演替理论的森林碳汇模型（人工林版）软件 [简称：FCS.SS.PF.Model] (2025SR

0083034)4. 内陆水体中温室气体浓度自动监测系统和分布预测方法. (202510441045.0)

5. 水-气界面温室气体通量自动监测系统和分布预测方法. (2025 1 0441066.2)

6. 造林碳汇评估技术规程. 团体标准. 黑龙江林学会. (T/HLJSLXH 035-2024)

7. 农业秸秆废弃物生态碳汇封存技术规范. 团体标准. 中国国际经济技术合作促进会. (T/CIET 1777-2025)

其他（公益工作）：

1. 创建了中国科学院兴安岭地球关键带与地表通量观测研究站（简称兴安岭关键带站），任兴安岭关键带站创始站长（2023年-至今）

2. 带领兴安岭关键带站申请成为第一批国家生态质量综合监测站“黑龙江大兴安岭站（森林）”，任其创始站长（2024年-至今）

3. 牵头重组tyc5997太阳集团碳中和技术创新研究院，担任其院长（2025年-至今）

4. 牵头申报“国家林业与草原局寒温带森林生态系统保护修复重点实验室”，任首任实验室主任（2026年-至今）

5. 牵头建立黑龙江省重点野外台站“黑龙江省大兴安岭生物多样性定位观测研究站”，任其创始站长（2026年-至今）

6. 牵头建立“全球最大森林生物多样性与功能实验样带（400公顷)（2025年-至今）

7. 牵头建立“亚洲东部南北样带”（North-South Transect of Eastern Asia, NSTEA）并完成首次野外调查（2025年-至今）

联系方式：

黑龙江哈尔滨市南岗区林兴街4号林学科研楼 150450

tyc5997太阳集团

tyc5997太阳集团邮箱：henp@nefu.edu.cn

Resume

Dr. Nianpeng He is a professor at Northeast Forestry University, China. His research focuses on plant functional trait ecology, biogeography, and carbon sink of terrestrial ecosystems. In past decades, his group has conducted a series of innovative works on plant functional traits, and their research helps inform the mechanism of community assembly, biodiversity maintenance, and ecosystem function optimization at large scales. In addition, they have systematically evaluated the carbon stocks, carbon sequestration rate, and carbon sequestration potential under different future scenarios for forest ecosystems in China. Dr. He has successfully obtained more than 20 project grants as PI from highly competitive research funding such as the National Science and Technology Basic Resources Survey Program of China and the National Natural Science Foundation of China and published more than 180 peer-reviewed papers as the first or corresponding author.

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国家高层次人才

院士（兼聘）

国家高层次人才

专任教师

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博士后

师资队伍

国家高层次人才

何念鹏