导师介绍

田大栓

男,中国科学院地理资源研究所研究员,博士生导师,国家优青。曾入选国家林草局青年拔尖人才(2022)、中国科学院青促会(2021)和可桢-秉维青年人才计划(2019)。现任地理资源所生态系统网络观测与模拟实验室研究员(2024~),于中国科学院植物所获得博士学位(2013)。相关成果发表SCI论文91篇,其中以第一/通讯作在Science AdvancesGlobal Change BiologyNew PhytologistEcologyFunctional Ecology等期刊发表28篇(平均IF=8.2,中国科学院一区21篇)。系列成果被引用4278余次(截止2024.6),其中3篇文章入选ESI高被引论文(全球前1%)最高单篇引用943 次(Tian et al. 2015)。同时成果入选Faculty Opinions2019年联合国气候变化大会专刊(COP25),并被《中国科学报》报道。作为负责人和骨干承担和参与国家自然科学基金优秀青年项目、面上项目、重点研发计划、二次科考等项目10余项。

研究方向:草地过程与功能

研究内容:结合控制实验+样带调查+标准化联网实验+整合分析(meta-analysis) ”多种研究手段的优势和特色,重点研究:1未配对的括号或引号!草地过程和功能对多资源耦合(水、氮、磷、钾)的响应规律及过程机制;2)量化草地生态系统生产力及其组分响应全球变化的突变阈值及形成机制;3)草地生产力维持的跨营养级多样性维持机制。

招生方向:欢迎具有生态学背景或相近学科交叉的同学保研或报考;常年招收博士后和客座研究生。

联系方式:tiands@igsnrr.ac.cnQQ723371306

发表论文情况如下(*通讯作者):

2024

91. J Mao,J Pan,L Song,R Zhang,J Wang,DS Tian,et al. 2024. Aridity threshold for alpine soil nitrogen isotope signature and ecosystem nitrogen cycling,Global Change Biology 30 (6),e17357

90. J Pan,Y Li,R Zhang,DS Tian,et al. 2024. Soil microbial gene abundance rather than diversity and network complexity predominantly determines soil multifunctionality in Tibetan alpine grasslands along a precipitation,Functional Ecology

89. MD Smith,KD Wilkins,MC Holdrege,… D Tian,et al. 2024. Extreme drought impacts have been underestimated in grasslands and shrublands globally,PNAS 121 (4),e2309881120

88. F Ma,Y Yan,JC Svenning,Q Quan,J Peng,R Zhang,J Wang,D Tian,et al. 2024. Opposing effects of warming on the stability of above‐and belowground productivity in facing an extreme drought event,Ecology 105 (1),e4193

87. He Y,Zhang R,Li P,Men L,Xu M,Wang J,...& Tian DS* (2024). Nitrogen enrichment delays the drought threshold responses of leaf photosynthesis in alpine grassland plants. Science of The Total Environment,169560.

86. Li TT,Tian DS*,He YC,Zhang RY,Wang JS,Wang FR,Niu SL (2024) Threshold response of ecosystem water use efficiency to soil water in an alpine meadow. Science of the Total Environment 908. doi:10.1016/j.scitotenv.2023.168345

85. Tang SM, Tian DS*,Wang JS,Zhang RY,Wang S,Song J,Wan SQ,Zhang JX,Zhang S,Li ZL,Niu SL (2024) Synergistic effects of multiple global change drivers on terrestrial ecosystem carbon sink. Science of the Total Environment 906. doi:10.1016/j.scitotenv.2023.167554

84. Wang FR,Li TT,Zhang RY,Wang JS,Xu M,Guo HB,Niu SL,Tian DS* (2024) Extreme precipitation causes divergent responses of root respiration to nitrogen enrichment in an alpine meadow. Science of the Total Environment 912. doi:10.1016/j.scitotenv.2023.168568

2023

83. Fu YW,Wu HH,Wang S,Yu Q,Tian DS,Xu X (2023) First report of Trichoderma atroviride causing rot of Morchella sextelata in Anhui Province,China. Crop Protection 168. doi:10.1016/j.cropro.2023.106206

82. Jin YX,Tian DS*,Li JW,Wu Q,Pan ZL,Han MQ,Wang YH,Zhang J,Han GD (2023) Water causes divergent responses of specific carbon sink to long-term grazing in a desert grassland. Science of the Total Environment 873. doi:10.1016/j.scitotenv.2023.162166

81. Li HY,Zhang JQ,Tian DS,Liu YH,Dong JY (2023) Nitrogen Significantly Affected N Cycling Functional Gene Abundances Compared with Phosphorus and Drought in an Alpine Meadow. Agronomy-Basel 13 (4). doi:10.3390/agronomy13041041

80. Li JP,Tian DS*,Yu KL,Guo HB,Zhang RY,Wang JS,Zhou QP,Niu SL (2023) Seed nutrient is more stable than leaf in response to changing multiple resources in an alpine meadow. Ecological Processes 12 (1). doi:10.1186/s13717-023-00454-9

79. Ma FF,Wang JS,He YL,Luo YQ,Zhang RY,Tian DS,Zhou QP,Niu SL (2023b) Nitrogen enrichment differentially regulates the response of ecosystem stability to extreme dry versus wet events. Science of the Total Environment 887. doi:10.1016/j.scitotenv.2023.164152

78. Ma FF,Yan YJ,Svenning JC,Quan Q,Peng JL,Zhang RY,Wang JS,Tian DS,Zhou QP,Niu SL (2023a) Opposing effects of warming on the stability of above- and belowground productivity in facing an extreme drought event. Ecology. doi:10.1002/ecy.4193

77. Quan Q,Ma FF,Wang JS, Tian DS,Zhou QP,Niu SL (2023) Contextualized response of carbon-use efficiency to warming at the plant and ecosystem levels. Science of the Total Environment 885. doi:10.1016/j.scitotenv.2023.163777

76. Wang BX,Chen WA,Tian DS,Li ZL,Wang JS,Fu Z,Luo YQ,Piao SL,Yu GR,Niu SL (2023) Dryness limits vegetation pace to cope with temperature change in warm regions. Global Change Biology. doi:10.1111/gcb.16842

75. Yang L,Pan JX,Wang JS,Tian DS,Zhang CY,Zhao XH,Hu J,Yang W,Yan YJ,Ma FF,Chen WN,Quan Q,Wang PY,Niu SL (2023) Soil microbial respiration adapts to higher and longer warming experiments at the global scale. Environmental Research Letters 18 (3). doi:10.1088/1748-9326/acbecb

74. Guo HB,Quan Q,Niu SL,Li TT,He YC,Fu YW,Li JP,Wang JS,Zhang RY,Li ZL,Tian DS* (2023) Shifting biomass allocation and light limitation co-regulate the temporal stability of an alpine meadow under eutrophication. Science of the Total Environment 860. doi:10.1016/j.scitotenv.2022.160411

73. Li Y,Tian DS*,Pan JX,Zhou BJM,Zhang RY,Song L,Wang JS,Niu SL (2023) Different patterns and drivers of fungal communities between phyllosphere and rhizosphere in alpine grasslands. Functional Ecology. doi:10.1111/1365-2435.14265

72. Ma FF,Chen WN,Wang JS,Tian DS,Zhou QP,Niu SL (2023) Below-ground net primary productivity stability in response to a nitrogen addition gradient in an alpine meadow. Functional Ecology 37 (2):315-326. doi:10.1111/1365-2435.14236

71. Pan JX,Peng YF,Wang JS,Tian DS,Zhang RY,Li Y,Yang L,Wang S,Chen C,Niu SL (2023a) Controlling factors for soil bacterial and fungal diversity and composition vary with vegetation types in alpine grasslands. Applied Soil Ecology 184. doi:10.1016/j.apsoil.2022.104777

70. Pan JX,Shi JW,Tian DS,Zhang RY,Li Y,He YL,Song L,Wang S,He YC,Yang JM,Wei CX,Niu SL,Wang JS (2023b) Depth-dependent drivers of soil aggregate carbon across Tibetan alpine grasslands. Science of the Total Environment 867. doi:10.1016/j.scitotenv.2023.161428

69. Peng JL,Ma FF,Tian DS,Quan Q,Chen C,Liao JQ,Zhou QP,Niu SL (2023) Plant C:N ratio predicts community composition changes under N addition in an alpine meadow. Journal of Ecology. doi:10.1111/1365-2745.14048

68. Tian DS,Xiang YZ,Seabloom E,Wang JS,Jia XX,Li TT,Li ZL,Yang J,Guo HB,Niu SL (2023) Soil carbon sequestration benefits of active versus natural restoration vary with initial carbon content and soil layer. Communications Earth & Environment 4 (1). doi:10.1038/s43247-023-00737-1

2022

67. Fan XY,He GJ,Zhang WY,Long TF,Zhang XM,Wang GZ,Sun G,Zhou HK,Shang ZH,Tian DS,Li XY,Song XN (2022) Sentinel-2 Images Based Modeling of Grassland Above-Ground Biomass Using Random Forest Algorithm: A Case Study on the Tibetan Plateau. Remote Sensing 14 (21). doi:10.3390/rs14215321

66. He YC,Li TT,Zhang RY,Wang JS,Zhu JT,Li Y,Chen XL,Pan JX,Shen Y,Wang FR,Li JW,Tian DS* (2022) Plant Evolution History Overwhelms Current Environment Gradients in Affecting Leaf Chlorophyll Across the Tibetan Plateau. Frontiers in Plant Science 13. doi:10.3389/fpls.2022.941983

65. Li Y,Pan JX,Zhang RY,Wang JS,Tian DS,Niu SL (2022a) Environmental factors,bacterial interactions and plant traits jointly regulate epiphytic bacterial community composition of two alpine grassland species. Science of the Total Environment 836. doi:10.1016/j.scitotenv.2022.155665

64. Li ZL,Tang Z,Song ZP,Chen WN,Tian DS,Tang SM,Wang XY,Wang JS,Liu WJ,Wang Y,Li J,Jiang LF,Luo YQ,Niu SL (2022b) Variations and controlling factors of soil denitrification rate. Global Change Biology 28 (6):2133-2145. doi:10.1111/gcb.16066

63. Li ZL,Zeng ZQ,Song ZP,Tian DS,Huang XZ,Nie S,Wang J,Jiang LF,Luo YQ,Cui J,Niu SL (2022c) Variance and main drivers of field nitrous oxide emissions: A global synthesis. Journal of Cleaner Production 353. doi:10.1016/j.jclepro.2022.131686

62. Pan JX,Wang JS,Tian DS,Zhang RY,Li Y,Song L,Yang JM,Wei CX,Niu SL (2022a) Biotic factors dominantly determine soil inorganic carbon stock across Tibetan alpine grasslands. Soil 8 (2):687-698. doi:10.5194/soil-8-687-2022

61. Pan QM,Symstad AJ,Bai YF,Huang JH,Wu JG,Naeem S,Chen DM,Tian DS,Wang QB,Han XG (2022b) Biodiversity-productivity relationships in a natural grassland community vary under diversity loss scenarios. Journal of Ecology 110 (1):210-220. doi:10.1111/1365-2745.13797

60. Tian DS,Xiang YZ,Seabloom E,Chen HYH,Wang JS,Yu GR,Deng Y,Li ZL,Niu SL (2022) Ecosystem restoration and belowground multifunctionality: A network view. Ecological Applications 32 (5). doi:10.1002/eap.2575

59. Xing W,Lu XM,Niu SL,Chen DM,Wang JS,Liu Y,Wang BX,Zhang S,Li ZL,Yao XJ,Yu Q,Tian DS* (2022) Global patterns and drivers of soil nematodes in response to nitrogen enrichment. Catena 213. doi:10.1016/j.catena.2022.106235

58. Yan YJ,Wang JS,Tian DS,Luo YQ,Xue X,Peng F,He JS,Liu LL,Jiang LF,Wang X,Wang YH,Song L,Niu SL (2022a) Sustained increases in soil respiration accompany increased carbon input under long-term warming across global grasslands. Geoderma 428. doi:10.1016/j.geoderma.2022.116157

57. Yan YJ,Wang JS,Tian DS,Zhang RY,Song L,Li ZL,Niu SL (2022b) Heterotrophic respiration and its proportion to total soil respiration decrease with warming but increase with clipping. Catena 215. doi:10.1016/j.catena.2022.106321

56. Yang L,Niu SL,Tian DS,Zhang CY,Liu WG,Yu Z,Yan T,Yang W,Zhao XH,Wang JS (2022a) A global synthesis reveals increases in soil greenhouse gas emissions under forest thinning. Science of the Total Environment 804. doi:10.1016/j.scitotenv.2021.150225

55. Yang L,Qin JH,Geng Y,Zhang CY,Pan JX,Niu SL,Tian DS,Zhao XH,Wang JS (2022b) Long-term effects of forest thinning on soil respiration and its components in a pine plantation. Forest Ecology and Management 513. doi:10.1016/j.foreco.2022.120189

54. Yang L,Wang JS,Geng Y,Niu SL,Tian DS,Yan T,Liu WG,Pan JX,Zhao XH,Zhang CY (2022c) Heavy thinning reduces soil organic carbon: Evidence from a 9-year thinning experiment in a pine plantation. Catena 211. doi:10.1016/j.catena.2021.106013

53. Zhang RY,Tian DS,Chen HYH,Seabloom EW,Han GD,Wang SP,Yu GR,Li ZL,Niu SL (2022a) Biodiversity alleviates the decrease of grassland multifunctionality under grazing disturbance: A global meta-analysis. Global Ecology and Biogeography 31 (1):155-167. doi:10.1111/geb.13408

52. Zhang RY,Tian DS*,Wang JS,Pan JX,Zhu JT,Li Y,Yan YJ,Song L,Wang S,Chen C,Niu SL (2022b) Dryness weakens the positive effects of plant and fungal beta diversities on above- and belowground biomass. Global Change Biology 28 (22):6629-6639. doi:10.1111/gcb.16405

2021

51. Li ZL,Zeng ZQ,Song ZP,Wang FQ,Tian DS,Mi WH,Huang X,Wang JS,Song L,Yang ZK,Wang J,Feng HJ,Jiang LF,Chen Y,Luo YQ,Niu SL (2021) Vital roles of soil microbes in driving terrestrial nitrogen immobilization. Global Change Biology 27 (9):1848-1858. doi:10.1111/gcb.15552

50. Liao JQ,Li ZL,Wang JS,Tian DS,Tian D,Niu SL (2021) Nitrogen use efficiency of terrestrial plants in China: geographic patterns,evolution,and determinants. Ecological Processes 10 (1). doi:10.1186/s13717-021-00338-w

49. Pan JX,Wang JS,Zhang RY,Tian DS,Cheng XL,Wang S,Chen C,Yang L,Niu SL (2021) Microaggregates regulated by edaphic properties determine the soil carbon stock in Tibetan alpine grasslands. Catena 206. doi:10.1016/j.catena.2021.105570

48. Shen Y,Tian DS*,Hou JH,Wang JS,Zhang RY,Li ZL,Chen XL,Wei XH,Zhang XY,He YC,Niu SL (2021) Forest soil acidification consistently reduces litter decomposition irrespective of nutrient availability and litter type. Functional Ecology 35 (12):2753-2762. doi:10.1111/1365-2435.13925

47. Wang JS,Defrenne C,McCormack ML,Yang L,Tian DS,Luo YQ,Hou EQ,Yan T,Li ZL,Bu WS,Chen Y,Niu SL (2021a) Fine-root functional trait responses to experimental warming: a global meta-analysis. New Phytologist 230 (5):1856-1867. doi:10.1111/nph.17279

46. Wang JS,Luo YQ,Quan Q,Ma FF,Tian DS,Chen WN,Wang S,Yang L,Meng C,Niu SL (2021b) Effects of warming and clipping on CH4 and N2O fluxes in an alpine meadow. Agricultural and Forest Meteorology 297. doi:10.1016/j.agrformet.2020.108278

45. Wang JS,Quan Q,Chen WN,Tian DS,Ciais P,Crowther TW,Mack MC,Poulter B,Tian HQ,Luo YQ,Wen XF,Yu GR,Niu SL (2021c) Increased CO2 emissions surpass reductions of non-CO2 emissions more under higher experimental warming in an alpine meadow. Science of the Total Environment 769. doi:10.1016/j.scitotenv.2020.144559

44. Wang JS,Tian DS(co-first author),Knapp AK,Chen HYH,Luo YQ,Li ZL,Hou EQ,Huang XZ,Jiang LF,Niu SL (2021d) Precipitation manipulation and terrestrial carbon cycling: The roles of treatment magnitude,experimental duration and local climate. Global Ecology and Biogeography 30 (9):1909-1921. doi:10.1111/geb.13356

43. Yan YJ,Quan Q,Meng C,Wang JS,Tian DS,Wang BX,Zhang RY,Niu SL (2021) Varying soil respiration under long-term warming and clipping due to shifting carbon allocation toward below-ground. Agricultural and Forest Meteorology 304. doi:10.1016/j.agrformet.2021.108408

42. Zhang JJ,Li Y,Wang JS,Chen WN,Tian DS,Niu SL (2021a) Different responses of soil respiration and its components to nitrogen and phosphorus addition in a subtropical secondary forest. Forest Ecosystems 8 (1). doi:10.1186/s40663-021-00313-z

41. Zhang RY,Schellenberg MP,Tian DS,Ma FF,Zhang TY,Wang H,Wu Q,Bai YT,Han GD,Niu SL (2021b) Shifting community composition determines the biodiversity-productivity relationship under increasing precipitation and N deposition. Journal of Vegetation Science 32 (2). doi:10.1111/jvs.12998

40. RY,Wang ZW,Niu SL,Tian DS,Wu Q,Gao XF,Schellenberg MP,Han GD (2021c) Diversity of plant and soil microbes mediates the response of ecosystem multifunctionality to grazing disturbance. Science of the Total Environment 776. doi:10.1016/j.scitotenv.2021.145730

2020

39. Li ZL,Zeng ZQ,Tian DS,Wang JS,Fu Z,Wang BX,Tang Z,Chen WN,Chen HYH,Wang CH,Yi CX,Niu SL (2020a) The stoichiometry of soil microbial biomass determines metabolic quotient of nitrogen mineralization. Environmental Research Letters 15 (3). doi:10.1088/1748-9326/ab6a26

38. Li ZL,Zeng ZQ,Tian DS,Wang JS,Fu Z,Zhang FY,Zhang RY,Chen WN,Luo YQ,Niu SL (2020b) Global patterns and controlling factors of soil nitrification rate. Global Change Biology 26 (7):4147-4157. doi:10.1111/gcb.15119

37. Li ZL,Zeng ZQ,Tian DS,Wang JS,Wang BX,Chen HYH,Quan Q,Chen WN,Yang JL,Meng C,Wang Y,Niu SL (2020c) Global variations and controlling factors of soil nitrogen turnover rate. Earth-Science Reviews 207. doi:10.1016/j.earscirev.2020.103250

36. Meng C,Tian DS(co-first author),Zeng H,Li ZL,Chen HYH,Niu SL (2020) Global meta-analysis on the responses of soil extracellular enzyme activities to warming. Science of the Total Environment 705. doi:10.1016/j.scitotenv.2019.135992

35. Yang L,Wang N,Chen Y,Yang W,Tian DS,Zhang CY,Zhao XH,Wang JS,Niu SL (2020) Carbon management practices regulate soil bacterial communities in response to nitrogen addition in a pine forest. Plant and Soil 452 (1-2):137-151. doi:10.1007/s11104-020-04570-9

2019

34. Chen WN,Zhang FY,Wang BX,Wang JS,Tian DS,Han GX,Wen XF,Yu GR,Niu SL (2019) Diel and Seasonal Dynamics of Ecosystem-Scale Methane Flux and Their Determinants in an Alpine Meadow. Journal of Geophysical Research-Biogeosciences 124 (6):1731-1745. doi:10.1029/2019jg005011

33. Li Y,Tian DS,Wang JS,Niu SL,Tian J,Ha DL,Qu YX,Jing GW,Kang XM,Song B (2019a) Differential mechanisms underlying responses of soil bacterial and fungal communities to nitrogen and phosphorus inputs in a subtropical forest. Peerj 7. doi:10.7717/peerj.7631

32. Li Y,Wu HD,Wang JZ,Cui LJ,Tian DS,Wang JS,Zhang XD,Yan L,Yan ZP,Zhang KR,Kang XM,Song B (2019b) Plant biomass and soil organic carbon are main factors influencing dry-season ecosystem carbon rates in the coastal zone of the Yellow River Delta. Plos One 14 (1). doi:10.1371/journal.pone.0210768

31. Li ZL,Cui J,Mi ZR,Tian DS,Wang JS,Ma ZL,Wang BX,Chen HYH,Niu SL (2019c) Responses of soil enzymatic activities to transgenic Bacillus thuringiensis (Bt) crops - A global meta-analysis. Science of the Total Environment 651:1830-1838. doi:10.1016/j.scitotenv.2018.10.073

30. Li ZL,Tian DS,Wang BX,Wang JS,Wang S,Chen HYH,Xu XF,Wang CH,He NP,Niu SL (2019d) Microbes drive global soil nitrogen mineralization and availability. Global Change Biology 25 (3):1078-1088. doi:10.1111/gcb.14557

29. Meng C,Tian DS (co-first author),Zeng H,Li ZL,Yi CX,Niu SL (2019) Global soil acidification impacts on belowground processes. Environmental Research Letters 14 (7). doi:10.1088/1748-9326/ab239c

28. Quan Q,Tian DS(co-first author),Luo YQ,Zhang FY,Crowthers TW,Zhu K,Chen HYH,Zhou QP,Niu SL (2019) Water scaling of ecosystem carbon cycle feedback to climate warming. Science Advances 5 (8). doi:10.1126/sciadv.aav1131

27. Shen Y,Tian DS*,Jiang LC,Wang JS,Chen XL,Li Y,Wang BX,Li ZL,Fu YW,Hou JH,Niu SL (2019) Different Responses and Links of N:P Ratio Among Ecosystem Components Under Nutrient Addition in a Temperate Forest. Journal of Geophysical Research-Biogeosciences 124 (10):3158-3167. doi:10.1029/2019jg005080

26. Tang SM,Ma L,Wei XT,Tian DS,Wang BJ,Li ZL,Zhang YJ,Shao XQ (2019a) Methane emissions in grazing systems in grassland regions of China: A synthesis. Science of the Total Environment 654:662-670. doi:10.1016/j.scitotenv.2018.11.102

25. Tang SM,Wang K,Xiang YZ,Tian DS*,Wang JS,Liu YS,Cao B,Guo D,Niu SL (2019b) Heavy grazing reduces grassland soil greenhouse gas fluxes: A global meta-analysis. Science of the Total Environment 654:1218-1224. doi:10.1016/j.scitotenv.2018.11.082

24. Tang YG,Yu GR,Zhang XY,Wang QF,Tian DS,Tian J,Niu SL,Ge JP (2019c) Environmental variables better explain changes in potential nitrification and denitrification activities than microbial properties in fertilized forest soils. Science of the Total Environment 647:653-662. doi:10.1016/j.scitotenv.2018.07.437

23. Tang YQ,Yu GR,Zhang XY,Wang QF,Tian J,Niu SL,Tian DS,Ge JP (2019d) Different strategies for regulating free-living N-2 fixation in nutrient-amended subtropical and temperate forest soils. Applied Soil Ecology 136:21-29. doi:10.1016/j.apsoil.2018.12.014

22. Tian DS,Reich PB,Chen HYH,Xiang YZ,Luo YQ,Shen Y,Meng C,Han WX,Niu SL (2019) Global changes alter plant multi-element stoichiometric coupling. New Phytologist 221 (2):807-817. doi:10.1111/nph.15428

21. 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 (2019a) Nitrogen addition reduces soil respiration but increases the relative contribution of heterotrophic component in an alpine meadow. Functional Ecology 33 (11):2239-2253. doi:10.1111/1365-2435.13433

20. Wang JS,Sun J,Yu Z,Li Y,Tian DS,Wang BX,Li ZL,Niu SL (2019b) Vegetation type controls root turnover in global grasslands. Global Ecology and Biogeography 28 (4):442-455. doi:10.1111/geb.12866

19. Zhang FY,Quan Q,Ma FF,Tian DS,Hoover DL,Zhou QP,Niu SL (2019a) When does extreme drought elicit extreme ecological responses?Journal of Ecology 107 (6):2553-2563. doi:10.1111/1365-2745.13226

18. Zhang FY,Quan Q,Ma FF,Tian DS,Zhou QP,Niu SL (2019b) Differential responses of ecosystem carbon flux components to experimental precipitation gradient in an alpine meadow. Functional Ecology 33 (5):889-900. doi:10.1111/1365-2435.13300

17. Zhang JJ,Yang H,Wang JS,Tian DS,Li Y,He NP,Niu SL (2019c) Soil and climate determine differential responses of soil respiration to nitrogen and acid deposition along a forest transect. European Journal of Soil Biology 93. doi:10.1016/j.ejsobi.2019.103097

16. Zhang XM,Johnston ER,Wang YS,Yu Q,Tian DS,Wang ZP,Zhang YQ,Gong DZ,Luo C,Liu W,Yang JJ,Han XG (2019d) Distinct Drivers of Core and Accessory Components of Soil Microbial Community Functional Diversity under Environmental Changes. Msystems 4 (5). doi:10.1128/mSystems.00374-19

2018

15. Hou LY,Li Y,Shi HQ,Tian DS,Wang BX,Li LH,Zhang LH (2018) Moderate grazing has little effect on global warming potential in the temperate steppes of northern China. Atmospheric Environment 190:342-348. doi:10.1016/j.atmosenv.2018.07.055

14. Kang XM,Yan L,Zhang XD,Li Y,Tian DS,Peng CH,Wu HD,Wang JZ,Zhong L (2018) Modeling Gross Primary Production of a Typical Coastal Wetland in China Using MODIS Time Series and CO2 Eddy Flux Tower Data. Remote Sensing 10 (5). doi:10.3390/rs10050708

13. Li Y,Sun J,Tian DS,Wang JS,Ha DL,Qu YX,Jing GW,Niu SL (2018a) Soil acid cations induced reduction in soil respiration under nitrogen enrichment and soil acidification. Science of the Total Environment 615:1535-1546. doi:10.1016/j.scitotenv.2017.09.131

12. Li Y,Tian DS*,Yang H,Niu SL (2018b) Size-dependent nutrient limitation of tree growth from subtropical to cold temperate forests. Functional Ecology 32 (1):95-105. doi:10.1111/1365-2435.12975

11. Li ZL,Wang BX,Tian DS,Wang JS (2018c) Bt rice cultivation does not cause soil biological degradation in terms of C,N,and P cycles. Land Degradation & Development 29 (11):4140-4145. doi:10.1002/ldr.3163

10. Liu YS,Yang XH,Tian DS,Cong RC,Zhang X,Pan QM,Shi ZJ (2018) Resource Reallocation of Two Grass Species During Regrowth After Defoliation. Frontiers in Plant Science 9. doi:10.3389/fpls.2018.01767

9. Quan Q,Zhang FY,Tian DS,Zhou QP,Wang LX,Niu SL (2018) Transpiration Dominates Ecosystem Water-Use Efficiency in Response to Warming in an Alpine Meadow. Journal of Geophysical Research-Biogeosciences 123 (2):453-462. doi:10.1002/2017jg004362

8. Tian DS,Xiang YZ,Wang BX,Li ML,Liu YS,Wang JS,Li ZL,Niu SL (2018) Cropland abandonment enhances soil inorganic nitrogen retention and carbon stock in China: A meta-analysis. Land Degradation & Development 29 (11):3898-3906. doi:10.1002/ldr.3137

7. Zhang XY,Yang Y,Zhang C,Niu SL,Yang H,Yu GR,Wang HM,Blagodatskaya E,Kuzyakov Y,Tian DS,Tang YQ,Liu S,Sun XM (2018) Contrasting responses of phosphatase kinetic parameters to nitrogen and phosphorus additions in forest soils. Functional Ecology 32 (1):106-116. doi:10.1111/1365-2435.12936

2017年及之前

6. Niu SL,Classen AT,Dukes JS,Kardol P,Liu LL,Luo YQ,Rustad L,Sun J,Tang JW,Templer PH,Thomas RQ,Tian DS,Vicca S,Wang YP,Xia JY,Zaehle S (2016) Global patterns and substrate-based mechanisms of the terrestrial nitrogen cycle. Ecology Letters 19 (6):697-709. doi:10.1111/ele.12591

5. Pan QM,Tian DS(co-first author),Naeem S,Auerswald K,Elser JJ,Bai YF,Huang JH,Wang QB,Wang H,Wu JG,Han XG (2016) Effects of functional diversity loss on ecosystem functions are influenced by compensation. Ecology 97 (9):2293-2302. doi:10.1002/ecy.1460

4. Tian DS,Wang H,Sun J,Niu SL (2016a) Global evidence on nitrogen saturation of terrestrial ecosystem net primary productivity. Environmental Research Letters 11 (2). doi:10.1088/1748-9326/11/2/024012

3. Tian DS,Niu SL (2015) A global analysis of soil acidification caused by nitrogen addition. Environmental Research Letters 10 (2). doi:10.1088/1748-9326/10/2/024019

2. Tian DS,Niu SL,Pan QM,Ren TT,Chen SP,Bai YF,Han XG (2016b) Nonlinear responses of ecosystem carbon fluxes and water-use efficiency to nitrogen addition in Inner Mongolia grassland. Functional Ecology 30 (3):490-499. doi:10.1111/1365-2435.12513

1. Tian DS,Pan QM,Simmons M,Chaolu H,Du BH,Bai YF,Wang H,Han XG (2012) Hierarchical Reproductive Allocation and Allometry within a Perennial Bunchgrass after 11 Years of Nutrient Addition. Plos One 7 (9). doi:10.1371/journal.pone.0042833

更新日期:20246