王猛(東北師範大學地理科學學院教授)

2009/09～2014/10，加拿大McGill大學地理系，自然地理學

2006/09～2009/07，浙江大學生命科學學院，生態學

2002/09～2006/07，青島科技大學化工學院，生物工程

2019/07，加拿大McGill大學地理系，訪問教授

2018/10～今，東北師範大學地理科學學院，教授

2014/11～2018/09，西北農林科技大學林學院，副教授

所在學科：濕地科學

研究方向：主要研究泥炭地植被與土壤的相互關係以及全球變化背景下，泥炭地生態系統的生物地球化學循環和化學計量學特徵。

在Soil Biology and Biochemistry、Global Biogeochemical Cycles、Geoderma、Plant and Soil、Frontiers in Microbiology、Environmental Research Letters、Ecosystems、Science of the Total Environment、Atmospheric Environment、Oecologia、Catena等期刊上發表SCI論文70余篇。

博士生招生專業：濕地科學

碩士生招生專業：濕地科學、自然地理學

主持和參與科研項目10餘項，其中，主持國家自然科學基金2項，省部級項目1項：

典型沼澤生境功能穩定性與生物多樣性耦合機制（子課題：沼澤濕地生境功能穩定性的環境調控與閾值），國家重點研發計畫子課題

中國長白山與英國雪墩山地區泥炭地土壤酶化學計量比的生物調控機制，國家自然科學基金國際（地區）合作與交流項目

長白山哈泥泥炭地土壤胞外酶活性的化學計量特徵的生物調控機制，國家自然科學基金面上項目

氮磷輸入對長白山泥炭地土壤有機碳影響的酶學機理研究，國家自然科學基金青年項目

銳齒櫟和油松的凋落物-土壤-微生物的生態化學計量學級聯特徵，陝西省自然科學基金青年項目

[73] Ge, L. M., Chen, C., Li, T., Bu, Z.J., Wang, M*. 2023. Contrasting effects of nitrogen and phosphorus additions on fine root production and morphological traits of different plant functional types in an ombrotrophic peatland. Plant and Soil, DOI:10.1007/s11104-023-06087-3

[72] Liu, L.,Tian, J., Wang, H., Xue, D., Huang, X., Ning, W., Wang, M., Xu, X., Peng, C., Wang,Y., Chen, H. 2023. Stable oxic-anoxic transitional interface is beneficial toretard soil carbon loss in drained peatland. Soil Biology and Biochemistry, 181:109024. DOI:10.1016/j.soilbio.2023.109024

[71] Yusup, S., Sundberg, S., Ooi, M.K.J., Zhang, M., Sun, Z., Rydin, H., Wang, M., Feng, L., Chen, X., Bu, Z.J. 2023. Smoke promotes germination of peatland bryophyte spores. Journal of Experimental Botany,1;74(1):251-264. DOI:10.1093/jxb/erac420

[70] 魏華, 楊金, 成軍鋒, 劉麗莉, 曹雪, 蘇少峰, 王璐, 王猛*. 2022. 千渭之會國家濕地公園典型底泥真菌群落結構及功能研究. 微生物學雜誌, 42(6):75-86. DOI:10.3969/j.issn.1005-7021.2022.06.010

[69] Watmough, S., Gilbert-Parkes, S., Basiliko, N., Lamit, L. J., Lilleskov, E. A., Andersen, R., Del Aguila-Pasquel, J., Artz, R. E., Benscoter, B. W., Borken, W., Bragazza, L., Brandt, S. M., Bräuer, S. L., Carson, M. A., Chen, X., Chimner, R. A., Clarkson, B. R., Cobb, A. R., Enriquez, A. S., Farmer, J., Grover, S. P., Harvey, C. F., Harris, L. I., Hazard, C., Hoyt, A. M., Hribljan, J., Jauhiainen, J., Juutinen, S., Kane, E. S., Knorr, K.-H., Kolka, R., Könönen, M., Laine, A. M., Larmola, T., Levasseur, P. A., Mccalley, C. K., Mclaughlin, J., Moore, T. R., Mykytczuk, N., Normand, A. E., Rich, V., Robinson, B., Rupp, D. L., Rutherford, J., Schadt, C. W., Smith, D. S., Spiers, G., Tedersoo, L., Thu, P. Q., Trettin, C. C., Tuittila, E.-S., Turetsky, M., Urbanová, Z., Varner, R. K., Waldrop, M. P., Wang, M., Wang, Z., Warren, M., Wiedermann, M. M., Williams, S. T., Yavitt, J. B., Yu, Z.-G., Zahn, G. 2022. Variation in carbon and nitrogen concentrations among peatland categories at the global scale. PLOS ONE, 17:e0275149. DOI:10.1371/journal.pone.0275149

[68] Li, T., Yuan, X., Ge, L. M.,Cao, C. H., Suo, Y. C., Bu, Z. J., Peng, C. H., Song, H. X., Liu, Z. P., Liu, S. S., Wang, M*. 2022. Weak impact ofnutrient enrichment on peat: evidence from physicochemical properties. Frontiers in Ecology and Evolution. DOI:10.3389/fevo.2022.973626

[67] Cao, C. H., Huang, J. J., Ge, L. M., Li, T., Bu, Z. J., Wang, S. Z., Wang, Z. C., Liu, Z. P., Liu, S. S., Wang, M*. 2022. Does shift in vegetation abundance after nitrogen and phosphorus additions play a key role in regulating fungal community structure in a northern peatland? Frontiers in Microbiology, 13:920382. DOI:10.3389/fmicb.2022.920382

[66]Lu, F., Wu, J. H., Yi, B. L., Xu, Z. W., Wang, M., Sundberg, Sebastian., Bu, Z. J. 2022. Long-Term Phosphorus Addition Strongly Weakens the Carbon Sink Function of a Temperate Peatland. Ecosystems. DOI:10.1007/s10021-022-00754-9

[65] Verbeke, B. A., Lamit, L. J., Lilleskov, E. A., Hodgkins, S. B., Basiliko, N., Kane, E. S., Andersen, R., Artz, R. R. E., Benavides, J. C., Benscoter, B. W., Borken, W., Bragazza, L., Brandt S. M., Bräuer, S. L., Carson, M. A., Charman, D., Chen X., Clarkson, B. R., Cobb, A. R., Convey, P., del Águila Pasquel, J., Enriquez, A. S., Griffiths, H., Grover, S. P., Harvey, C. F., Harris, L., Hazard, C., Hodgson, D., Hoyt, A. M., Hribljan, J., Jauhiainen, J., Juutinen, S., Knorr, K. H., Kolka, R. K., Könönen, M., T., Larmola, T., McCalley, C. K., McLaughlin, J., Moore, T. R., Mykytczuk, N., Normand, A. E., Rich, V., Roulet, N., Royles, J., Rutherford, J., Smith, D. S., Svenning, M. M., Tedersoo, L., Thu, P. Q., Trettin C. C., Tuittila, E. S., Urbanová, Z., Varner, R. K., Wang, M., Wang, Z., Warren, M., Wiedermann, M. M., Williams, S., Yavitt, J. B., Yu, Z. G., Yu, Z. C., Chanton, J. P.* 2022. Latitude, elevation, and mean annual temperature predict peat organic matter chemistry at a global scale. Global Biogeochemical Cycles, 36:e2021GB007057

[64] 何玉傑, 孔澤, 戶曉, 張江, 王猛, 彭長輝, 朱求安*. 2022. 水熱條件分別控制了中國溫帶草地NDVI的年際變化和增長趨勢. 生態學報, 42(2):766-777

[63] Li, T., Peng, C. H., Bu, Z. J., Zhu, Q. A., Song, H. X., Guo, X. Y., Wang, M.* 2021. Woody plants reduce the sensitivity of soil extracellular enzyme activity to nutrient enrichment in wetlands: A meta-analysis. Soil Biology & Biochemistry, 159:108280

[62] Zhang, J., Zhu, Q. A., Yuan, M. S., Liu, X. W., Chen, H., Peng, C. H., Wang, M., Yang, Z. A., Jiang, L., Zhao, P. X. 2021. Extrapolation and uncertainty evaluation of carbon dioxide and methane emissions in the Qinghai-Tibetan Plateau wetlands since the 1960s. Frontiers in Earth Science, 8:361

[61] Zhang, C. B.*, Wang, J., Liu, W. L., Jiang, H., Wang, M., Ge, Y., Chang, J. 2021. Denitrifying bacterial community dominantly drove nitrogen removals in vertical flow constructed wetlands as impacted by macrophyte planting patterns. Chemosphere, 281:130418. https://doi.org/10.1016/j.chemosphere.2021.130418

[60] Xu, X. Y., Lu, K. J., Wang, Z. C.*, Wang, M., Wang, S. Z. 2021. Effects of drainage on dissolved organic carbon (DOC) characteristics of surface water from a mountain peatland. Science of the Total Environment, 789:147848. https://doi.org/10.1016/j.scitotenv.2021.147848

[59] Guo, X. Y.,Peng, C. H.*, Li, T., Huang, J. J., Song, H. X., Zhu, Q. A., Wang, M.* 2021.The effects of drought and re-watering on non-structural carbohydrates of Pinustabulaeformis seedlings. Biology, 10:281.https://doi.org/10.3390/biology10040281

[58] Yuan, M. S.,Zhu, Q. A.*, Zhang, J., Liu, J. X., Chen, H., Peng, C. H., Li, P., Li, M. X.,Wang, M., Zhao, P. X. 2021. Global response of terrestrial gross primaryproductivity to climate extremes. Science of the Total Environment, 750:142337.https://doi.org/10.1016/j.scitotenv.2020.142337

[57] 葛樂明, 李通, 袁欣, 黃晶晶, 王升忠, 卜兆君, 王猛*. 2020. 短期排水下泥炭酶活性和碳循環過程的模擬實驗研究. 濕地科學, 18(6):730-739.http://wetlands.neigae.ac.cn/CN/Y2020/V18/I6/730

[56] 徐曉雲, 汪祖丞*, 王猛, 徐志偉, 陸楷鈞, 王升忠*. 2020. 白江河林場天然與長期排水泥炭沼澤表層泥炭和積水中可溶性有機碳特徵的比較. 濕地科學, 18(6):740-749.http://wetlands.neigae.ac.cn/CN/Y2020/V18/I6/740

[55] Zhang, J., Zhu,Q. A.*, Yuan, M. S., Liu, X. W., Chen, H., Peng, C. H., Wang, M., Yang, Z. A.,Jiang, L., Zhao P. X.* 2020. Extrapolation and uncertainty evaluation of carbondioxide and methane emissions in the Qinghai-Tibetan plateau wetlands since the1960s. Frontiers in Earth Science, 8:361.https://doi.org/10.3389/feart.2020.00361

[54] Li, T., Ge, L.M., Huang, J. J., Yuan, X., Peng, C. H., Wang, S. Z., Bu, Z. J., Zhu, Q. A.,Wang, Z. C., Liu, W. G., Wang, M.* 2020. Contrasting responses of soilexoenzymatic interactions and the dissociated carbon transformation to short-and long-term drainage in a minerotrophic peatland. Geoderma, 377:114585.https://doi.org/10.1016/j.geoderma.2020.114585

[53] Du, Y. Y., Luo,B., Han, W. J., Duan, Y. Y., Yu, C. C., Wang, M., Ge, Y., Chang, J.* 2020.Increasing plant diversity offsets the influence of coarse sand on ecosystemservices in microcosms of constructed wetlands. Environmental Science andPollution Research, https://doi.org/10.1007/s11356-020-09592-5

[52] Zhang, J. J.,Peng, C. H., Xue, W., Yang, B., Yang, Z. A., Niu, S. L., Zhu, Q. A., Wang, M.*2020. Dynamics of soil water extractable organic carbon and inorganic nitrogenand their environmental controls in mountain forest and meadow ecosystems inChina. Catena, 187:104338. https://doi.org/10.1016/j.catena.2019.104338

[51] Song, H. X.,Huang, J. J., Ge, L. M., Peng, C. H., Zhao, P. X.*, Guo, X. Y., Li, T., Shen,X. J., Zhu, Q. A., Liu, W. G., Wei, H., Wang, M.** 2020. Interspecificdifference in N:P stoichiometric homeostasis drives nutrient release and soilmicrobial community composition during decomposition. Plant and Soil, 452:29-42.https://doi.org/10.1007/s11104-020-04513-4

[50] Li, P., Zhu, Q.A., Peng, C. H.*, Zhang, J., Wang, M., Zhang, J. J., Ding, J. H., Zhou, X. L.2020. Change in autumn vegetation phenology and the climate controls from 1982to 2012 on the Qinghai-Tibet Plateau. Frontiers in Plant Sciences,https://doi.org/10.3389/fpls.2019.01677.

[49] Zhang, J.,Ding, J. H., Zhang, J., Yuan, M. S., Li, P., Xiao, Z. Y., Peng, C. H., Chen,H., Wang, M., Zhu, Q. A.* 2020. Effects of increasing aerosol optical depth onthe gross primary productivity in China during 2000-2014. EcologicalIndicators, 108:105761. https://doi.org/10.1016/j.ecolind.2019.105761

[48] 楊斌, 彭長輝*, 張賢, 劉偉國, 段敏, 王猛. 2019. 乾旱脅迫對刺槐幼苗葉片氮含量、光合速率及非結構性碳水化合物的影響. 套用於環境生物學報, 25(6):1261-1269. https://doi.org/10.19675/j.cnki.1006-687x.2019.03011

[47] Li, T., Bu, Z.J., Liu, W. Y., Zhang, M. Y., Peng, C. H.*, Zhu, Q. A., Shi, S. W., Wang, M.**2019. Weakening of the ‘enzymatic latch’ mechanism following long-termfertilization in a minerotrophic peatland. Soil Biology and Biochemistry,136:107258. https://doi.org/10.1016/j.soilbio.2019.107528

[46] Wang, M.*#,Tian, J. Q.#, Bu, Z. J., Lamit, J. L., Chen, H., Zhu, Q. A., Peng, C. H. 2019.Structural and functional differentiation of the microbial community in the surfaceand subsurface peat of two minerotrophic fens in China. Plant and Soil,437:21-40. https://doi.org/10.1007/s11104-019-03962-w

[45] Smith, N. G.*,Keenan, T. F., Prentice, I. C., Wang, H., Wright, J., Niinemets, Ü., Grous, KY., Domingues, T. F., Guerrieri, R., Ishida, F. Y., Kattge, J., Kruger, E L.,Maire, V., Rogers, A., Serbin, S. P., Tarvainen, L., Togashi, H. F., Townsend,P. A., Wang, M., Weerasinghe, L. K., Zhou, S. X. 2019. Global photosyntheticcapacity is optimized to the environment. Ecology Letters, 22:506-517.https://doi.org/10.1111/ele.13210

[44] Shi, S. W.,Yang, M. X., Hou, Y., Peng, C. H.*, Wu, H. B., Zhu, Q. A., Liang, Q., Xie, J.F., Wang, M. Simulation of dissolved organic carbon concentrations and fluxesin Chinese monsoon forest ecosystems using a modified TRIPLEX-DOC model.Science of the Total Environment, 697:134054.https://doi.org/10.1016/j.scitotenv.2019.134054

[43] Guo, Y. R.,Peng, C. H.*, Zhu, Q. A., Wang, M., Wang, H., Peng, S. S., He, H. L. 2019.Modelling the impacts of climate and land use changes on soil water erosion:Model applications, limitations and future challenges. Journal of EnvironmentalManagement, 250:109403. https://doi.org/10.1016/j.jenvman.2019.109403

[42] Pan, K. X., Lu,Y. J., He, S. N., Yang, G. F., Chen, Y., Fan, X., Ren, Y., Wang, M., Zhu, K.D., Shen, Q., Jiang, Y. P., Shi, Y., Meng, P. P., Tang, Y. L., Chang, J., Ge,Y.* 2019. Urban green spaces as potential habitats for introducing a nativeendangered plant, Calycanthus chinensis. Urban Forestry & Urban Greening,46:126444. https://doi.org/10.1016/j.ufug.2019.126444

[41] Zhang, K. R.,Zhu, Q. A.*, Liu, J. X., Wang, M., Zhou, X. L., Li, M. X., Wang, K. F., Ding,J. H., Peng, C. H.* 2019. Spatial and temporal variations of N2O emissions fromglobal forest and grassland ecosystems. Agricultural and Forest Meteorology,266-267:129-139. https://doi.org/10.1016/j.agrformet.2018.12.011

[40] Wang, K. F.,Peng, C. H.*, Zhu, Q. A., Wang, M., Wang, G. S., Zhou, X. L., Yang, Y. Z.,Ding, J. H., Wei, H. 2019. Changes in soil organic carbon and microbial carbonstorage projected during the 21st century using TRIPLEX-MICROBE. EcologicalIndicators, 98:80-87. https://doi.org/10.1016/j.ecolind.2018.10.045

[39] Yang, B., Peng,C. H.*, Harrison, S. P., Wei, H., Wang, H., Zhu, Q. A., Wang, M. 2018.Allocation mechanisms of non-structural carbohydrates of Robinia pseudoacaciaL. seedlings in response to drought and waterlogging. Forests, 9:754.https://doi.org/10.3390/f9120754

[38] Moore, T. R.*,Large, D., Talbot, J., Wang, M., Riley, J. L. 2018. The stoichiometry ofcarbon, hydrogen and oxygen in peat. Journal of Geophysical Research:Biogeosciences, 123:3101-3110. https://doi.org/10.1029/2018JG004574

[37] Feng, L.,Sundberg, S., Ooi, M., Wu, Y. H., Wang, M., Bu, Z. J.* 2018. Oxygen-deficiencyand allelochemicals affect Sphagnum spore persistence in peatlands. Plant andSoil, 432:403-413. https://doi.org/10.1007/s11104-018-3809-0

[36] Wei, H., Peng,C. H.*, Yang, B., Song, H. X., Li, Q., Jiang, L., Wei, G., Wang, K. F., Wang,H., Liu, S. R., Liu, X. J., Chen, D. X., Li, Y. D., Wang, M.* 2018. Contrastingsoil bacterial community, diversity, and function in two forests in China.Frontiers in Microbiology, 9:1693. https://doi.org/10.3389/fmicb.2018.01693

[35] Li, P., Peng,C. H.*, Wang, M., Luo, Y. P., Li, M. X., Zhang, K. R., Zhang, D. L., Zhu, Q.A.** 2018. Dynamics of vegetation autumn phenology and its response to multipleenvironmental factors from 1982 to 2012 on Qinghai-Tibetan Plateau in China.Science of the Total Environment, 637-638:855-864.https://doi.org/10.1016/j.scitotenv.2018.05.031

[34] Wei, H., Peng,C. H.*, Liu, S. R., Liu, X. J., Li, P., Song, H. X., Yuan, M. S., Wang, M.2018. Variation in soil methane fluxes and comparison between two forests inChina. Forests, 9:204. https://doi.org/10.3390/f9040204

[33] Zhang, J. J.,Peng, C. H., Xue, W., Yang, Z. A., Yang, B., Li, P., Zhu, Q. A., Wang, M.*2018. Soil CH4 and CO2 dynamics and nitrogen transformations with incubation inmountain forest and meadow ecosystems. Catena, 163:24-32.https://doi.org/10.1016/j.catena.2017.12.005

[32] Wang, M.*,Talbot, J., Moore, T. R. 2018. Drainage and fertilization effects on nutrientavailability in an ombrotrophic peatland. Science of the Total Environment,621:1255-1263. https://doi.org/10.1016/j.scitotenv.2017.10.103

[31] Wang, H.*,Harrison, S. P., Prentice, I. C., Yang, Y. Z., Bai, F., Togashi, H. F., Wang,M., Zhou, S. X., Ni, J. 2018. The China Plant Trait Database: towards acomprehensive regional compilation of functional traits for land plants.Ecology, 99:500-500. https://doi.org/10.1002/ecy.2091

[30] Talbot, J.*,Moore, T. R., Wang, M., Riley, J. L. 2017. Distribution of lead and mercury inOntario peatlands. Environmental Pollution, 231:890-898.https://doi.org/10.1016/j.envpol.2017.08.095

[29] Zhu, Q. A.*,Peng, C. H.*, Ciais, P., Jian, J., Liu, J. X., Bousquet, P., Li, S. Q., Chang,J., Fang, X. Q., Zhou, X. L., Chen, H., Liu, S. R., Lin, G. H., Gong, P., Wang,M., Wang, H., Xiang, W. H., Chen, J. Interannual variation in methane emissionsfrom tropical wetlands triggered by repeated El Niño Southern Oscillation.Global Change Biology, 23:4706-4716. https://doi.org/10.1111/gcb.13726

[28] Li, M. X.,Peng, C. H., Wang, M., Yang, Y. Z., Zhang, K. R., Li, P., Yang, Y., Ni, J.,Zhu, Q. A.* 2017. Spatial patterns of leournal of GeophysicalResearch-Biogeosciences, 122:1564-1575. https://doi.org/10.1002/2016JG003529

[27] Du, M. X.,Peng, C. H.*, Wang, X. G., Chen, H., Wang, M., Zhu, Q. A.** 2017.Quantification of methane emissions from municipal solid waste landfills inChina during the past decade. Renewable & Sustainable Energy Reviews,78:272-279. https://doi.org/10.1016/j.rser.2017.04.082

[26] Li, M. X.,Peng, C. H.*, Wang, M., Xue, W., Zhang, K. R., Wang, K. F., Shi, G. H., Zhu, Q.A.** 2017. The carbon flux of global rivers: A re-evaluation of amount andspatial patterns. Ecological Indicators, 80:40-51.https://doi.org/10.1016/j.ecolind.2017.04.049

[25] Li, P., Peng,C. H.*, Wang, M., Li, W. Z., Zhao, P. X., Wang, K. F., Yang, Y. Z., Zhu, Q. A.*2017. Quantification of the response of global terrestrial net primaryproduction to multifactor global change. Ecological Indicators, 76:245-255.https://doi.org/10.1016/j.ecolind.2017.01.021

[24] Wang, K. F.,Peng, C. H.*, Zhu, Q. A., Zhou, X. L., Wang, M., Zhang, K. R., Wang, G. S.2017. Modeling global soil carbon and soil microbial carbon by integratingmicrobial processes into the ecosystem process model TRIPLEX-GHG. Journal ofAdvances in Modelling Earth Systems, 9:2368-2384.https://doi.org/10.1002/2017MS000920

[23] Zhang, K. R.,Peng, C. H.*, Wang, M., Zhou, X. L., Li, M. X., Wang, K. F., Ding, J. H., Zhu,Q. A.** 2017. Process-based TRIPLEX-GHG model for simulating N2O emissions fromglobal forests and grasslands: Model development and evaluation. Journal ofAdvances in Modelling Earth Systems, 9:2079-2102.https://doi.org/10.1002/2017MS000934

[22] Wang, M.*,Larmola, T., Murphy, M. T., Moore, T. R., Bubier, J. T. 2016. Stoichiometricresponse of shrubs and mosses to long-term nutrient (N, P and K) addition in anombrotrophic peatland. Plant and Soil, 400:403-416.https://doi.org/10.1007/s11104-015-2744-6

[21] Zhang, J. J.,Peng, C H.*, Zhu, Q. A., Xue, W., Shen, Y., Yang, Y. Z., Shi, G. H., Shi, S.W., Wang, M.** 2016. Temperature sensitivity of soil carbon dioxide and nitrousoxide emissions in mountain forest and meadow ecosystems in China. AtmosphericEnvironment, 142:340-350. https://doi.org/10.1016/j.atmosenv.2016.08.011

[20] Zhu, Q. A.*,Peng, C. H.*, Liu, J. X., Jian, J., Fang, X. Q., Chen, H., Niu, Z. G., Gong,P., Lin, G. H., Wang, M., Wang, H., Yang, Y., Chang, J., Ge, Y., Xiang, W. H.,Deng, X. W., He, J. S. 2016. Climate-driven increase of natural wetland methaneemissions offset by human-induced wetland reduction in China over the pastthree decades. Scientific Reports, 6:38020. https://doi.org/10.1038/srep38020

[19] Fan, M. Y.,Pan, K. X., Han. W. J., Lu, Y. J., Shen, Q., Wang, M., Ren, Y., Qu, Z. L.,Chang, J., Ge, Y.* 2016. A strategy for introducing an endangered plant Moslahangchowensis to urban area based on nitrogen preference. Acta PhysiologiaePlantarum, 38:265. https://doi.org/10.1007/s11738-016-2278-4

[18] Shi, G. H.,Peng, C. H.*, Wang, M., Shi, S. W., Yang, Y. Z., Chu, J. Y., Zhang, J. J., Lin,G. H., Shen, Y., Zhu, Q. A.** 2016. The spatial and temporal distribution ofdissolved organic carbon exported from three Chinese rivers to the China Sea.PLoS ONE, 11:e0165039. https://doi.org/10.1371/journal.pone.0165039

[17] Zhao, Z. Y.,Chang, J., Han, W. J., Wang, M., Ma, D. P., Du, Y. Y., Qu, Z. L., Chang, S. X.,Ge, Y.* 2016. Effects of plant diversity and sand particle size on methaneemission and nitrogen removal in microcosms of constructed wetlands. EcologicalEngineering, 95:390-398. https://doi.org/10.1016/j.ecoleng.2016.06.047

[16] Shi, S. W.,Peng, C. H.*, Wang, M., Zhu, Q. A., Yang, G., Yang, Y. Z., Xi, T. T., Zhang, T.L. 2016. A global meta-analysis of changes in soil carbon, nitrogen, phosphorusand sulfur, and stoichiometric shifts after forestation. Plant and Soil,407:323-340. https://doi.org/10.1007/s11104-016-2889-y

[15] Yang, Y. Z.,Zhu, Q. A.*, Peng, C. H., Wang, H., Xue, W., Lin, G. H., Wen, Z. M., Chang, J.,Wang, M., Liu, G. B., Li, S. Q. 2016. A novel approach for modelling vegetationdistributions and analysing vegetation sensitivity through trait-climaterelationships in China. Scientific Reports, 6:24110.https://doi.org/10.1038/srep24110

[14] Song, X. Z.*,Gu, H. H., Wang, M., Zhou, G. M., Li, Q. 2016. Management practices regulatethe response of Moso bamboo foliar stoichiometry to nitrogen deposition.Scientific Reports, 6:24107. https://doi.org/10.1038/srep24107

[13] Wang, M., Moore,T. R.*, Talbot, J., Riley, J. L. 2015. The stoichiometry of carbon andnutrients in peat formation. Global Biogeochemical Cycles, 29:113-121.https://doi.org/10.1002/2014GB005000

[12] Liu, J. G.,Chen, H., Zhu, Q. A., Shen, Y., Wang, X., Wang, M., Peng, C. H. 2015. A novelpathway of direct methane production and emission by eukaryotes includingplants, animals and fungi: An overview. Atmospheric Environment, 115:26-35.https://doi.org/10.1016/j.atmosenv.2015.05.019

[11] Wang, M.*,Moore, T. R., Talbot, J., Richard P. J. H. 2014. The cascade of C:N:Pstoichiometry in an ombrotrophic peatland: from plants to peat. EnvironmentalResearch Letters, 9:024003. https://doi.org/10.1088/1748-9326/9/2/024003

[10] Wang, M.*,Moore, T. R. 2014. Carbon, nitrogen, phosphorus and potassium stoichiometry inan ombrotrophic peatland reflects plant functional type. Ecosystems,17:673-684. https://doi.org/10.1007/s10021-014-9752-x

[9] Wang, M.*,Murphy, M. T., Moore, T. R. 2014. Nutrient resorption of two evergreen shrubsin response to long-term fertilization in a bog. Oecologia, 174:365-377.https://doi.org/10.1007/s00442-013-2784-7

[8] Lu, Y. J., Wang,M., Ge, Y., Fu, C. X., Chang, J.* 2014. Response of photosynthetic andmorphological characteristic of Mosla chinensis and congenerous weed M. scabrato soil water content. Russian Journal of Ecology, 45:367-374.https://doi.org/10.1134/S106741361405018X

[7] 曾競, 卜兆君*, 王猛, 馬進澤, 趙紅艷, 李鴻凱, 王升忠. 2013. 氮沉降對泥炭地影響的研究進展.生態學雜誌, 32(2):473-481.

[6] Chu, Z. Y., Ge,Y., Chang, J.*, Wang, M., Jiang, H., He, J. S., Peng, C. H. 2011. Leafrespiration/photosynthesis relationship and variation: an investigation of 39woody and herbaceous species in east subtropical China. Trees, 25:301-310.https://doi.org/10.1007/s00468-010-0506-x

[5] Wang, M., Chang,J., Ge, Y.*, Chang, S. X.*, Huang, C. C., Wang, S. Y. 2010. Ecophysiologicaldifferentiation of two Mosla species in response to nitrogen and water levels.Communications in Soil Science and Plant Analysis, 41:2699-2712.https://doi.org/10.1080/00103624.2010.518262

[4] Chang, J., Wang,M., Guan, B. H., Gu, B. J., Jiang, D. A., Liu, Z., Liao, J. X., Ge, Y.* 2010. Responsesof a widespread weed and an endangered congeneric plant to potassium.Communications in Soil Science and Plant Analysis, 41:571-583.https://doi.org/10.1080/00103620903531151

[3] Cao, Q. J.,Wang, M., Ge, Y., Chang, J.*, Chang, S. X., Zhang, J. M. 2010. Growth responsesof two Mosla species to soil nitrogen and water supply. Botanical Studies,51:451-456.

[2] Wang, M., Gu, B.J., Ge, Y., Liu, Z., Jiang, D. A., Chang, S. X., Chang, J.* 2009. Differentresponses of two Mosla species to potassium limitation in relation to acid raindeposition. Journal of Zhejiang University-Science B, 10:563-571.https://doi.org/10.1631/jzus.B0920037

[1] 張建民, 王猛, 葛曉萍, 吳建之, 葛瀅*, 李世鵬, 常傑. 2009. ICP-AES法與傳統FAAS法測定土壤速效鉀和鈉的數據可轉性研究.光譜學與光譜分析, 29(5):1405-1408.

國家環境保護濕地生態與植被恢復重點實驗室副主任，長白山地理過程與生態安全教育部重點實驗室主任助理。國際泥炭地學會（IPS）理事，吉林省泥炭地學會副理事長，國際泥炭地學會中國國家委員會秘書長，中國腐植酸工業協會泥炭分會副秘書長，中國生態學學會濕地專業委員會副秘書長，中國環境科學學會濕地環境生態保育與功能開發專業委員會副秘書長，國際濕地科學家學會（SWS）中國分會副秘書長。Frontiers in Microbiology副主編（Associate Editor）、《濕地科學》期刊編委。

為Global Change Biology、New Phytologist、Ecology、Environment International、Biogeochemistry、Agriculture, Ecosystems & Environment、Plant and Soil、Applied Soil Ecology、Land Degradation & Development、Science of the Total Environment、Ecosystems、Ecological Engineering、Ecological Indicators等期刊的審稿人。