基本信息

 姓名：陈伏生

 性别：男

 导师类别：博士生指导教师

 职称：教授（二级岗）

 学位：博士

个人简历

2013.01-至今  江西农业大学林学院/园林与艺术学院  历任教授、首席教授、二级教授，党支部书记、教研室主任、重点实验室主任、林学学科带头人，副院长、院长等职。

2009.02-2010.02  Cornell University自然资源系  访问学者

2005.07-2012.12  南昌大学生命科学学院  博士后、讲师、副教授、博士生导师

2000.09-2005.06  中国科学院沈阳应用生态研究所   生态学专业  博士

1997.08-2000.08  江西农业大学林学院   树木生态教研室  教师

1993.09-1997.07  江西农业大学林学院   林学专业      学士

联系方式

E-mail：chenfusheng@jxau.edu.cn

社会兼职

 教育部高等学校林学类教学指导委员会委员（2018-），中国自然资源学会理事森林资源专业委员会副主任委员兼秘书长（2019-），江西省政府学位委员会第二届学科评议组成员（2018-），江西省林学会常务理事森林培育专业委员会主任（2020-），《生态学杂志》编委（2016-）等

教学工作

 主讲研究生《生态环境建设与管理》《高级生态学》《水土保持植物群落》等课程；本科生《森林土壤学》《森林生态学》《林业与全球气候变化》《林学专业导论》等课程。

研究方向

 主要从事森林培育、森林生态、水土保持等方面的研究，重点是森林土壤、根叶性状、人工林培育和天然林保育等领域。

课题项目

[1]国家自然科学基金面上项目，“氮磷添加对常绿阔叶林主要树种凋落叶和细根性状及其分解的影响”（32171759），60万，主持人

[2]国家自然科学基金重点项目，“气候变化背景下农林生态系统土壤有机碳动态与微生物参与机制”（31930070），课题一“全球变化背景下森林土壤碳库形成及稳定性研究”，102.01万，课题负责人

[3]国家自然科学基金面上项目，“南岭东部常绿阔叶林主要树种根际与根叶养分对磷添加的响应”（31870427），60万，主持人

[4]国家自然科学基金重点项目，“亚热带人工林补植树种根叶功能属性环境可塑性及其对生产力的影响”（31730014），课题二“亚热带人工林补植树种与目标树种竞争效应及根叶功能属性对光环境的响应机制”，101万，课题负责人

[5]国家自然科学基金地区项目“退化红壤区人工林林下植物根系生长与凋落物分解的互作机制”（31360179），55万，主持人

[6]国家自然科学基金地区项目“氮磷添加对丘陵红壤人工林根际过程与叶片养分属性的影响”（31160107），55万，主持人

[7]国家自然科学基金地区项目“山江湖工程植被恢复典型林地土壤氮素矿化及其根际效应”（30960311），27万，主持人

[8]国家自然科学基金青年项目“城乡梯度森林土壤氮磷转化、吸收和生态化学计量”（30600473），18万，主持人

[9]国家重点研发计划，课题二“人工林类型与结构对物质循环过程的影响”第四专题“水平结构和垂直结构对马尾松和杉木林物质循环过程的影响”（2016YFD0600202-2），85万，专题负责人

[10]国家重点基础研究发展计划，973课题“林分结构对生态系统养分平衡影响机制”（2012CB416903）第四专题“林分结构调整与养分管理方式对生态系统养分平衡和CNP化学计量比的影响”，109万，专题负责人

[11]江西省重点研发计划（B类）,“吉泰盆地低效人工林补植树种筛选及结构优化技术”（20181ACH80006），50万，主持人

[12]江西省科技厅，“亚热带人工林高效培育与生态管理”（20165BCB19006, 5511优势科技创新团队人才计划, 赣科发计字［2017］40号），50万，主持人

[13]江西省科技厅“毛竹林氮磷转化根际效应对采伐强度的响应及大小年变异机制”（20153BCB22008，江西省主要学科学术与技术带头人，赣科发计字［2015］71号），30万，主持人

[14]江西省科技厅“亚热带人工林生态”（20122BCB23005，江西省青年科学家培养对象计划，省杰青），8万，主持人

[15]中央财政林业科技推广示范项目“南方丘陵山区鲜食枣丰产栽培技术示范”（JXTG[2015]-07），100万，主持人

[16]江西省林业科技创新专项资金“观赏竹种质资源的收集与评价利用”（201505），45万，主持人

[17]江西省高等学校科技落地计划项目“毛竹伐蔸引生促腐释养的生态学机制”（KJLD14028），20万，主持人；

[18]留学归国人员科研启动基金“氮磷调控对退化红壤植被恢复典型林地根际-微生物互作过程的影响”（ 2011NCU001），主持人

[19]中国博士后基金“土壤-茶树铝循环与茶叶铝安全”（20070421040），主持人

[20] 江西省科技支撑计划项目“山区竹材与竹笋的高值化利用技术集成研究”（20142BBG70003），主持人

[21]江西省自然科学基金项目“赣南脐橙根系-微生物互作及根际微生物多样性”（2012BAB204005），主持人

[22]江西省自然科学青年基金“赣南脐橙果园氮磷循环及其化学计量”（2007GQN1935），主持人

[23]国家林草局“江西九连山森林生态系统国家定位观测研究站运行经费”（2016-2021），负责人

[24]教育部，新农科研究与改革实践项目“面向国家生态文明建设需求的林科实践育人体系构建与实证研究”（教高厅函〔2020〕20号 [No.139]），主持人

[25]江西省学位与研究生教育教学改革研究项目“林学一流学科研究生课程体系建设的研究与实践”（JXYJG-2021-XXX），主持人

[26]江西省学位与研究生教育教学改革研究重点项目“一流学科创建中研究生培养方案的改革与创新：基于全国林学学科专业课程与学位论文的调研”（JXYJG-2017-047），主持人

[27]江西省教育厅，江西省高等学校教学改革研究课题重点项目，一流专业和一流学科背景下学院一流课程体系建设的研究与实践（JXJG-20-3-1），主持人

[28]江西省教育厅，2019年江西省研究生优质课程和案例建设项目，生态环境建设与管理，负责人

[29] 江西省教育厅，2021年省级线上线下混合式一流课程（本科），森林土壤学，负责人

[30]江西省教育厅，2020年省级精品在线开放课程（本科），森林土壤学，负责人

论文情况（共计160多篇，第一作者或通讯作者80余篇）

[1]Liu Q#, Wang FC#, Liu R, Hu XF, Wang HM, Chen F-S*. Aboveground litter input alters the effects of understory vegetation removal on soil microbial communities and enzyme activities along a 60-cm profile in a subtropical plantation forest. Applied Soil Ecology, 2022, 104489, https://doi.org/10.1016/j.apsoil.2022.104489

[2]Huang C*, Feng JY, Tang FR, He HS, Liang Y, Wu MM., Xu WR, Liu B, Shi FX, Chen FS. Predicting the responses of boreal forests to climate-fire-vegetation interactions in Northeast China. Environmental Modelling & Software, 2022, 153, https://doi.org/10.1016/j.envsoft.2022.105410

[3]Feng J; Chen FS, Tang F; Wang F; Liang K, He L, Huang C.* The Trade-offs and synergies of ecosystem services in Jiulianshan National Nature Reserve in Jiangxi Province, China. Forests 2022, 13, 416. https://doi.org/10.3390/f13030416

[4]Ye XM, Wang FC, Hu XF, Lin Y, Sun RX, Liang X, Chen F-S*. Experimental approach alters N and P addition effects on leaf traits and growth rate of subtropical Schima superba seedlings. Forests, 2022,13,141. https:// doi.org/10.3390/f13020141

[5]Gu H-J, Zhang C-C, Chen F-S, Huang J-H, Wang J-S, Bruelheide H, Trogisch S, Fang X-M, Li J-J, Bu W-S*. The bamboo rhizome evolution in China is driven by geographical isolation and trait differentiation. Forests 2021, 12, 1280. https://doi.org/10.3390/ f12091280

[6]Guo CL, Chen FS, Li JW, Fang XM, Wan SZ, Zhang LS*. Navel orange fine root nutrient content and rhizosphere effects varied with tree ages and soil depths in a hilly red soil region of China. Acta Agriculturae Scandinavica, Section B— Soil & Plant Science, 2021, 71(8): 696-705. https://doi.org/10.1080/09064710.2021.1940269

[7]Yuan Y, Gao S, Dai XQ, Chen FS, Wang HM. Effect of nitrogen and phosphorus addition on soil aggregation and its associated organic carbon. Chemistry and Ecology, 2021, 37: 7, 603-615, DOI: 10.1080/02757540.2021.1936512

[8]Ye XM, Bu WS, Hu XF, Liu B, Liang K, Chen F-S*. Species divergence in seedling leaf traits and tree growth response to nitrogen and phosphorus addition in a subtropical broadleaved evergreen forest. Journal of Forestry Research, 2021, 10.1007/s11676-021-01437-2

[9]Fang X-M, Zhang X-L, Zong Y-Y, Li W-Q, Li J-J, Guo L-P, Wang H-M, Chen F-S*. Responses of leaf litter decomposability to nitrogen and phosphorus additions are associated with cell wall carbohydrate composition in a subtropical plantation. Plant and Soil, 2021, 467(1-2): 359-372 http://doi.org/10.1007/s11104-021-05099-1.

[10]Wang S-N, Hu Y-P, Chen J-L, Qi L-L, Zeng H, Ding H, Huo G-H, Zhang L-P, Chen F-S*, Yan J-Q*. First record of the rare genus Typhrasa (Psathyrellaceae, Agaricales) from China with description of two new species MycoKeys 2021, 79: 119–128. doi: 10.3897/mycokeys.79.63700

[11]Qiu LJ, Zhang Y, Mao R, Chen FS, Liu J, Yang GY, Wan SZ*. Understory removal accelerates nucleic phosphorus release but retards residual phosphorus release in decomposing litter of Phyllostachys edulis in subtropical China. Land Degradation & Development, 2021, https://doi.org/10.1002/ldr.3942.

[12]Wu AQ, Hu XF, Wang FC, Guo CL, Wang HM, Chen F-S*. Nitrogen deposition and phosphorus addition alter mobility of trace elements in subtropical forests in China. Science of the Total Environment, 2021, 781, https://doi.org/10.1016/j.scitotenv.2021.146778

[13]Li W-Q, Huang Y-X, Chen F-S, Liu Y-Q, Lin X-F, Zong Y-Y, Wu G-Y, Yu Z-R, Fang X-M*. Mixing with broad-leaved trees shapes the rhizosphere soil fungal communities of coniferous tree species in subtropical forests. Forest Ecology and Management, 2021, https://doi.org/10.1016/j.foreco.2020.118664.

[14]Fang XM, Wang GG, Xu Z-J, Zong Y-Y, Zhang X-L, Li J-J, Wang HM, Chen F-S*. Litter addition and understory removal influenced soil organic carbon quality and mineral nitrogen supply in a subtropical plantation forest. Plant and Soil, 2021, 460(1), 527-540. https://doi.org/10.1007/s11104-020-04787-8

[15]Bu WS#, Wang F-C#, Zhang C-C, Bruelheide H, Fang XM, Wang H-M, Chen F-S*. The contrasting effects of nitrogen and phosphorus fertilizations on the growth of Cunninghamia lanceolata depend on the season in subtropical China. Forest Ecology and Management, 2021, 482: 118874. https://doi.org/10.1016/j.foreco.2020.118874

[16]Liu R, Zhang Y, Hu X-F, Wan SZ, Wang HM, Liang C, Chen F-S*. Litter manipulation effects on microbial communities and enzymatic activities vary with soil depth in a subtropical Chinese fir plantation. Forest Ecology and Management, 2021, 480: 118641 https://doi.org/10.1016/j.foreco.2020.118641

[17]Zhang C, Zhang XY*, Kuzyakov Y, Wang HM, Fu XL, Yang Y, Chen FS, Dungait AJJ, Green MS, Fang XM. Responses of C-, N- and P- acquiring hydrolases to P and N fertilizers in a subtropical Chinese fir plantation depend on soil depth. Applied Soil Ecology, 2020, 150, 103465.

[18]Niu Y, Zhang MY, Bai SH, Xu ZH, Liu YQ, Chen FS, Guo XM, Luo HD, Wang SL, Xie JY, Yuan X. Successive mineral nitrogen or phosphorus fertilization alone significantly altered bacterial community rather than bacterial biomass in plantation soil. Applied Microbiology and Biotechnology, 2020, 104(16): 7213-7224.

[19]Niu Y, Zhang MY, Bai SH, Xu ZH, Liu YQ, Chen F-S, Guo XM, Zhang L, Luo HD, Zhang Q. Mineral fertilization and soil depth slightly affected aggregate structures despite significantly altered microbial properties in surface forest soils. Journal of Soils and Sediments, 2020, 20(10): 3615-3626.

[20]Bu W-S, Gu H-J, Zhang C-C, Zhang Y, Singh AN, Fang X-M, Fan J, Wang HM, Chen F-S*. Mixed broadleaved tree species increases soil phosphorus availability but decreases the coniferous tree nutrient concentration in subtropical China. forests, 2020, 11, 461: doi:10.3390/f11040461.

[21]Wan S-Z, Chen F-S*, Hu X-F, Zhang Y, Fang X-M. Urbanization aggravates imbalances in the active C, N and P pools of terrestrial ecosystems. Global Ecology and Conservation, 2020, https://doi.org/10.1016/j.gecco.2019.e00831.

[22]Wang F-C, Fang XM, Wang GG*, Mao R, Lin XF, Wang, HM, Chen F-S*. Effects of nutrient addition on foliar phosphorus fractions and nutrient resorption in different-age leaves of Chinese fir in subtropical China. Plant and Soil, 2019, 443: 41–54. DOI: 10.1007/s11104-019-04221-8

[23]Wang J-L, Li Q-K, Fu X-L, Dai X-Q, Kou L, Xu M-J, Chen S-F, Chen F-S*, Wang H-M*. Mechanisms driving ecosystem carbon sequestration in a Chinese fir plantation: nitrogen versus phosphorus fertilization. European Journal of Forest Research, 2019, 138: 863–873 https://doi.org/10.1007/s10342-019-01208-z

[24]Ye X-M^#, Zhang Y^#, Chen F-S*, Fang X-M, Lin X-F, Wan S-Z, He P, Wang GG. The effects of simulated deposited nitrogen on nutrient dynamics in decomposing litters across a wide quality spectrum using a ¹⁵N tracing technique. Plant and Soil, 2019, 442:141–156. https://doi.org/10.1007/s11104-019-04158-y

[25]Fang XM, Zhang XL, Chen F-S*, Zong Y-Y, Bu W-S, Wan S-Z, Luo YQ, Wang HM, Phosphorus addition alters the response of soil organic carbon decomposition to nitrogen deposition in a subtropical forest. Soil Biology and Biochemistry, 2019, 133: 119–128. https://doi.org/10.1016/j.soilbio.2019.03.005

[26]Chen F-S*, Wang GG*, Fang XM, Wan SZ, Zhang Y, Liang C. Nitrogen deposition effect on forest litter decomposition is interactively regulated by endogenous litter quality and exogenous resource supply. Plant and Soil, 2019, 437: 413-426, https://doi.org/10.1007/s11104-019-04006-z

[27]Wang, F.C., Wang, G.G., Mao, R., Fang, X.M., Wang, H.M., Bu, W.S., Chen, F.-S.* Effect of simulated nitrogen deposition on nutrients and nonstructural carbohydrates of major understory plants in a Chinese fir plantation of subtropical China. Forests, 2019, 10, 155; doi:10.3390/f10020155

[28]Hu, X.F., Wu, A.-Q., Wang, F.-C., Chen, F.-S.*The effects of simulated acid rain on internal nutrient cycling and the ratios of Mg, Al, Ca, N, and P in tea plants of a subtropical plantation. Environmental Monitoring and Assessment, 2019, 191:99; https://doi.org/10.1007/s10661-019-7248-z

[29] Bu, W.S., Chen, F.-S.*, Wang, F.C., Fang, X.M., Mao, R., Wang, H.M. The species-specific responses of nutrient resorption and carbohydrates accumulation in leaves and roots to nitrogen addition in a subtropical mixed plantation. Canadian Journal of Forest Research, 2019, 49: 826–835. dx.doi.org/10.1139/cjfr-2018-0322

[30]Li, L.*, McCormack, M.L., Chen, F.-S., Wang, H.-M., Ma, Z.-Q.*, Guo, D.-L. Different responses of absorptive roots and arbuscular mycorrhizal fungi to fertilization provide diverse nutrient acquisition strategies in Chinese fir. Forest Ecology and Management, 2019, 433(1): 64-72.

[31]Yang, Y., Zhang, X.Y.*, Zhang, C., Wang, H.M., Fu, X.L., Chen, F.S., Wan, S.Z., Sun, X.M., Wen, X.F., Wang, J.F. Understory vegetation plays the key role in sustaining soil microbial biomass and extracellular enzyme activities. Biogeosciences, 2018, 15: 4481-4494.

[32]Ma, Z.Q., Zhang, X.Y.*, Zhang, C., Wang, H.M., Chen, F.S., Fu, X.L., Fang, X.M., Sun, X.M., Lei, Q.L. Accumulation of residual soil microbial carbon in Chinese fir plantation soils after nitrogen and phosphorus additions. Journal of Forestry Research, 2018, 29 (4): 953-962.

[33]Hu, X.F., Chen, F.-S.*, Wine, M.L., Fang, X.M. Increasing acidity of rain in subtropical tea plantation alters aluminum and nutrient distributions at the root-soil interface and in plant tissues. Plant and Soil, 2017, 417:261–274. DOI 10.1007/s11104-017-3256-3.

[34]Fu, X.L., Guo, D.L., Wang, H.M.*, Dai, X.Q., Li, M.L., Chen, F.S. Differentiating between root- and leaf-litter controls on the structure and stability of soil micro-food webs. Soil Biology & Biochemistry, 2017. 113, 192-200.

[35]Wan, S.Z., Gu, H.J., Yang, Q.P., Hu, X.F., Fang, X.M., Chen, F.-S.* Long-term fertilization increases soil nutrient accumulations but decreases biological activity in navel orange orchards of subtropical China. Journal of Soils and Sediments, 2017, 17:2346 -2356, DOI: 10.1007/s11368-016-1439-9.

[36]Wang, F.C., Fang, X.M., Ding, Z.Q., Wan, S.Z., Chen, F.-S.* Effects of understory plant root growth into the litter layer on the leaf litter decomposition of two woody species in a subtropical forest. Forest Ecology and Management, 2016, 364, 39-45. doi.org/10/1016/j.foreco.2016.01.003.

[37]Fang, X.M., Christenson, L., Wang, F.C., Zeng, J.P., Chen, F.-S.* Pine caterpillar outbreak and stand density impacts on nitrogen and phosphorus dynamics and their stoichiometry in Masson pine plantation in subtropical China. Canadian Journal of Forest Research, 2016, 46: 601–609. dx.doi.org/10.1139/cjfr-2015-0357

[38] Cui, L.F., Liang, C.*, Duncan, D.S., Bao, X.L., Xie, H.T., He, H.B., Wickings, K., Zhang, X.D., Chen, F.S. Impacts of vegetation type and climatic zone on neutral sugar distribution in natural forest soils. Geoderma, 2016, 282:139-146.

[39]Tang, Y.Q., Zhang, X.Y.*, Li, D.D., Wang, H.M., Chen, F.S., Fu, X.L., Fang, X.M., Sun X.M., Yu, G.R. Impacts of nitrogen and phosphorus additions on the abundance and community structure of ammonia oxidizers and denitrifying bacteria in Chinese fir plantations. Soil Biology & Biochemistry, 2016, 103: 284-293.

[40]Chen, F.-S.*, Niklas, K.J., Liu, Y., Fang, X.M., Wan, S.Z., Wang, H.M. Nitrogen and phosphorus additions alter nutrient dynamics but not resorption efficiencies of Chinese fir leaves and twigs differing in age. Tree Physiology, 2015, 35 (10): 1106-1117. doi:10.1093/treephys/tpv076.

[41]Dong, W.Y., Zhang, X.Y.*, Liu, X.Y., Fu, X.L., Chen, F.S., Wang, H.M., Sun, X.M., Wen, X.F. Responses of soil microbial communities and enzyme activities to nitrogen and phosphorus additions in Chinese fir plantations of subtropical China. Biogeosciences, 2015, 12, 5537-5546. doi:10.5194/bg-12-5537-2015

[42]Xiong, Y.M.*, Xu, X.L., Zeng, H., Wang, H.M., Chen, F.S., Guo, D.L.* Low nitrogen retention in soil and litter under conditions without plants in a subtropical pine plantation, Forests 2015, 6, 1-xmanuscripts; doi:10.3390/f60x000x

[43]Zou, L.Q., Chen, F.-S.*, Duncan, D., Fang, X.M., Wang, H.M. Reforestation and slope position effects on nitrogen, phosphorus pools and carbon stability of various soil aggregates in a red soil hilly land of subtropical China. Canadian Journal of Forest Research, 2015, 45: 26-35. dx.doi.org/10.1139/cjfr-2014-0275

[44]Chen, F.-S.*, Yavitt, J., Hu, X.F. Phosphorus enrichment helps increase soil carbon mineralization in vegetation along an urban-to-rural gradient, Nanchang, China. Applied Soil Ecology, 2014, 75: 181-188.

[45]Chen, F.-S.*, Duncan, D.S., Hu, X.F., Liang, C. Exogenous nutrient manipulations alter endogenous extractability of carbohydrates in decomposing foliar litters under a typical mixed forest of subtropics. Geoderma, 2014, 214-215: 19-24.

[46]Fang, X.M., Chen, F.-S.*, Hu, X.F., Yuan, P.C., Li, J., Chen, X. Aluminum and nutrient interplay across an age-chronosequence of tea plantations within a hilly red soil farm of subtropical China. Soil Science and Plant Nutrition, 2014, 60: 448-459. DOI:10.1080/00380768.2014.912950

[47]Fan, J., Wang, J.Y., Hu, X.F., Chen, F.-S.* Seasonal dynamics of soil nitrogen availability and phosphorus fractions under urban forest remnants of different vegetation communities in Southern China. Urban Forestry & Urban Greening, 2014, 13: 576-585

[48]Chen, F.-S.*, Niklas, K.J., Chen, G.S., Guo, D.L. Leaf traits and relationships differ with season as well as among species groupings in a managed Southeastern China forest landscape. Plant Ecology, 2012, 213: 1489-1502.

[49]Chen, F.-S.*, Feng, X., Liang, C. Endogenous versus exogenous nutrient affects C, N, and P dynamics in decomposing litters in mid-subtropical forests of China. Ecological Research, 2012, 27: 923-932.

[50]Duan, X.H., Hu, X.F., Chen, F.S., Deng, Z.Y*. Bioactive ingredient levels of tea leaves are associated with leaf Al level interactively influenced by acid rain intensity and soil Al supply. Journal of Food, Agriculture & Environment, 2012, 10 (3&4): 1801-1886.

[51]Chen, F.-S., Niklas, K.J., Zeng, D.H*. Important foliar traits depend on species-grouping: analysis of a remnant temperate forest at the Keerqin Sandy Lands, China. Plant and Soil, 2011, 340: 337-345.

[52]Fang, Y.T.*, Gundersen, P., Vogt, R.D., Koba, K., Chen, F.S., Chen, X.Y., Yoh, M. Atmospheric deposition and leaching of nitrogen in Chinese forest ecosystems. Journal of Forest Research, 2011, 16(5): 341-350.

[53]Hu, X.F., Chen, F.-S.*, Nagle, G., Fang, Y.T., Yu, M.Q. Soil phosphorus fractions and tree phosphorus resorption in pine forests along an urban-to-rural gradient in Nanchang, China. Plant and Soil, 2011, 346: 97-106.

[54]Ren, W., Chen, F.-S.*, Hu, X.F., Yu, M.Q., Feng, X. Soil nitrogen transformations varied with plant community under Nanchang urban forests in mid-subtropical zone of China. Journal of Forestry Research, 2011, 22(4): 569-576.

[55]Chen, F.-S.*, Fahey, T.J., Yuan, M.Y., Gan, L. Key nitrogen cycling processes in pine plantations along a short urban-rural gradient in Nanchang, China. Forest Ecology and Management, 2010, 259: 477-486.

[56]Chen, F.-S.*, Zeng, D.H., Fahey, T.J., Liao, P.F. Organic carbon in soil physical fractions under different-aged plantations of Mongolian pine in semi-arid region of Northeast China. Applied Soil Ecology, 2010, 44: 42-48.

[57]Chen, F.-S.*, Zeng, D.H., Fahey, T.J., Yao, C.Y., Yu, Z.Y. Response of leaf anatomy of Chenopodium acuminatum to soil resource availability in a semi-arid grassland. Plant Ecology, 2010, 209: 375-382.

[58]Zeng, D.H.*, Li, L.J., Fahey, T.J., Yu, Z.Y., Fan, Z.P., Chen, F.S. Effects of nitrogen addition on vegetation and ecosystem carbon in a semi-arid grassland. Biogeochemistry, 2010, 98:185-193.

[59]Chen, F.-S.*, Li, X., Nagle, G., Zhan, S.X. Topsoil phosphorus signature in five forest types along an urban-suburban-rural gradient in Nanchang, southern China. Journal of Forestry Research, 2010, 21: 39-44.

[60]Chen, F.-S.., Zeng, D.H.*, Fahey, T.J. Changes in soil nitrogen availability due to stand development and management practices on semi-arid sandy lands, in northern China. Land Degradation & Development, 2009, 20: 481-491

[61]Yu, Z.Y., Chen, F.S., Zeng, D.H.*, Zhao, Q., Chen, G.S. Soil inorganic nitrogen, microbial biomass carbon and nitrogen under pine plantations in a Zhanggutai sandy soil. Pedosphere, 2008, 18(6): 775-784.

[62] Chen, F.-S., Zeng, D.H.*, Zhou, B., Singh, A.N., Fan, Z.P. Seasonal variation in soil nitrogen availability under Mongolian pine plantations in Keerqin Sand Lands, China. Journal of Arid Environments, 2006, 67: 226-239.

[63] Chen, F.-S., Zeng, D.H.*, He, X.Y. Small-scale spatial variability of soil nutrients and vegetation properties in semi-arid northern China. Pedosphere, 2006, 16(6): 778-787.

[64]Chen, F.-S., Zeng, D.H.*, Hu, X.F., Chen, G.S., Yu, Z.Y. Soil animals and nitrogen mineralization under sand-fixation plantations. Journal of Forestry Research, 2007, 18(1): 73-77.

[65]Singh, A.N., Zeng, D.H.*, Chen, F.S. Effect of young woody plantations on carbon and nutrient accumulation rates in redeveloping soil of coalmine spoil in dry tropical environment, India. Land Degradation & Development, 2006, 17:13-21.

[66]Singh, A.N.*, Zeng, D.H., Chen, F.S. Heavy metal concentrations in redeveloping soil of mine spoil under plantations of certain native woody species in dry tropical environment, India. Journal of Environmental Sciences, 2005, 17(1): 168-174.

[67]Chen, F.-S., Zeng, D. H.*, Singh, A. N., Chen, G. S. Effects of soil moisture and soil depth on nitrogen mineralization process under Mongolian pine plantations in Zhanggutai sandy land, P. R. China. Journal of Forestry Research, 2005, 16(2): 101-104.

[68]Chen, G. S., Zeng, D. H.*, Chen, F. S. Concentrations of foliar and surface soil in nutrients of Pinus sp. plantations in relation to species and stand age in Zhangutai sandy land, northeast China. Journal of Forestry Research, 2004, 15(1): 11-18.

[69]Gao, P., Liu, Z. X.*, Chen, F. S. The runoff characteristics and harmonic analysis of the soil moisture dynamics in Robinia pseudoacacia stand. Journal of Forestry Research, 2003, 14(4):295-298.

[70]Chen, F.-S., Chen, G. S., Zeng, D. H.*, Liang, C. The effects of peat and weathered coal on the growth of Pinus sylvestris var. mongolica seedlings on aeolian sandy soil. Journal of Forestry Research, 2002, 13(4): 251-254.

[71]陈伏生*,易敏,马际凯,靳藏馥,张露,孙荣喜,郑勇奇.中国林木种业发展现状与展望.江西农业大学学报, 2021, 43(3): 488-496.

[72]刘俏,林勇,胡小飞,吴安琪,叶学敏,陈伏生*.氮磷肥调控茶树锌硒等中微量元素吸收与分配.生态学报, 2021, 41(2): 637-644.

[73]郭利平,陈伏生*,陈秀龙,张芸,李建军,石福习.新形势下水土保持人才培养质量的提升途径——以江西农业大学为例. 水土保持应用技术, 2021, (3): 49-52

[74]刘俏,刘仁,张扬,陈伏生*.水土保持与荒漠化防治学科近20年来的研究热点与发展趋势——基于我国硕士学位论文的可视化分析.亚热带水土保持, 2020, 32(3): 8-14.

[75]吴安琪,张扬,万松泽,方向民,刘仁,胡添翼,陈伏生*.一株金黄蓝状菌解磷特性及其对毛竹的促生效应. 应用生态学报, 2019, 30(01):173-179.

[76]叶学敏,顾菡娇,杜天真,郭韫丽,陈伏生*.基于 CiteSpace 森林培育学科的研究热点和发展历程.广西林业科学, 2019, 48(3): 408-415.

[77]刘仁,张宇飞,金志芳,毛瑢,张扬,李晓东,陈伏生*.温度调控外源氮添加对毛竹细根分解及其养分释放的影响[J].生态学杂志, 2019, 38(12): 3617-3625.

[78]王小东#,刘鹏#,刘美娟,肖相元,陈伏生*.中国红豆属植物生物与生态学特征研究现状.植物科学学报, 2018, 36(3): 440-451.

[79]吴安琪,欧阳晓芳,陈伏生*.基于知识图谱分析的金钱松生物学研究进展.南方林业科学, 2017, 45(6): 42-47.

[80]顾菡娇,高璜,陈伏生*,张文根,卜文圣,杨光耀,王海霞.竹子观赏特性及其在园林景观配置中的应用.南方林业科学, 2016, 44(5): 61-64.

[81]杨清培,金志农,裘利洪,施建敏,程松林,郭英荣,陈伏生*.江西武夷山南方铁杉更新格局及代际关联性分析.生态学杂志, 2014, 33(4): 939-945.

[82]陈伏生*,张园敏,胡小飞,冯雪,任文,刘苑秋.丘陵陡坡荒山灌木草丛及其造林地生态系统碳库的分配格局.水土保持学报, 2012, 26(1): 151-155.

[83]黄媛,段小华,胡小飞,邓泽元,陈伏生*.模拟酸雨和铝调控对茶叶主要化学品质与铝积累的影响.热带亚热带植物学报, 2011, 19(3): 254-259.

[84]弓晓静,余明泉,胡小飞,郭恢财,陈伏生*.氮磷添加对红壤区城郊湿地松林凋落叶分解的影响.生态学杂志, 2010, 29(12): 2327-2333.

[85]郭恢财,廖鹏飞,陈伏生*.脐橙果园土壤养分动态与酶活性的季节变化.生态学杂志, 2010, 29(4): 754-759.

[86]詹书侠,陈伏生*,胡小飞,甘露,朱友林.中亚热带丘陵红壤区森林演替典型阶段土壤氮磷有效性.生态学报, 2009, 29(9): 4673-4680.

[87]陈伏生*,余焜,甘露,胡小飞.温度、水分和森林演替对中亚热带丘陵红壤氮素矿化影响的模拟实验.应用生态学报, 2009, 20 (7): 1529-1535.

[88]余明泉,袁平成,陈伏生*,胡小飞,杜天真.城市化对湿地松人工林氮素供应的影响.应用生态学报, 2009, 20(3): 531-536.

[89]余明泉,杜天真,陈伏生*,胡小飞.城乡梯度森林土壤原易位氮素矿化.林业科学研究, 2009, 22(1): 69-74.

[90]甘露,陈伏生*,胡小飞,田秋香,葛刚,詹书侠.南昌市不同植物类群叶片氮磷浓度及其化学计量比.生态学杂志, 2008, 27(3): 344-348.

[91]陈伏生*,胡小飞,葛刚.城市地被植物麦冬叶片氮磷化学计量比和养分再吸收效率.草业学报, 2007, 16(4): 47-54.

[92]胡小飞,陈伏生*,葛刚.森林采伐对林地表层主要特征及其生态过程的影响.土壤通报, 2007, 38(6): 1213-1218.

[93]胡小飞,陈伏生*,胡岸峰,甘露,姚成义,胡海军.氮磷添加对麦冬根部养分浓度及其化学计量比的影响.热带亚热带植物学报, 2007, 15(5): 377-382.

[94]陈伏生,曾德慧*,范志平,赵琼.森林土壤氮素有效性的野外估测方法.林业科学, 2007, 43(S1): 83-88.

[95] 陈伏生,曾德慧*,范志平,陈广生,Singh, A.N.沙地不同树种人工林土壤氮素矿化过程及其有效性研究.生态学报, 2006, 26(2): 341-348.

[96]陈伏生,曾德慧*,范志平,陈广生,于占源,赵琼.章古台沙地樟子松人工林土壤有效氮的研究.北京林业大学学报, 2005, 27(3): 6-11.

[97] 陈伏生,曾德慧*.耕种对沙地土壤全磷空间变异性的影响.中国环境科学, 2005, 13(S): 85-88.

[98]陈伏生,曾德慧*,王桂荣.泥炭和风化煤改良盐碱土的效果分析.辽宁工程技术大学学报.2004, 23(6):861-864.

[99] 陈伏生,曾德慧*.科尔沁沙地退化草场土壤养分的空间结构分析.草业学报, 2004,13(1): 39-44.

[100] 陈伏生,曾德慧*,陈广生,范志平.开垦对草甸土有机碳的影响.土壤通报,2004, 35(4):413-419.

[101] 陈伏生,曾德慧*,陈广生.土地利用变化对沙地土壤全氮空间分布格局的影响.应用生态学报,2004,15(6):953-957.

[102] 陈伏生,曾德慧*,何兴元.森林土壤氮素转化与循环.生态学杂志,2004,23(5): 126-133.

[103] 陈伏生,王桂荣,张春兴,曾德慧*.施用泥炭对风沙土改良及蔬菜生长的影响.生态学杂志,2003,22(4):16-19.

[104] 陈伏生,曾德慧*,陈广生,王桂荣.风沙土改良剂对白菜生理特性和生长状况的影响.水土保持学报,2003,17(2):152-155.

授权专利

[1]陈伏生,郭春兰,方向民,张扬,万松泽,杨清培.发明专利:竹蔸促腐复合剂.专利号:ZL201610235903.7,授权公告号:CN105802886,授权公告日:20190215

[2]陈伏生,张扬,张林平,栾丰刚,方向民,万松泽,胡小飞,李冬.发明专利:一种金黄篮状菌及其应用.专利号:ZL201710946541.7,申请日期:20171011授权公告号:CN107858293,授权公告日:20201124.

[3]陈伏生,王小东,卜文圣,方向民,毛荣,吴高洋,刘斌,刘仁,叶学敏,吴安琪.实用新型专利:一种凋落物收集装置. 专利号: ZL 2019 20500588.5,授权公告号:CN210047753U,授权公告日:20200211

[4]陈伏生,张扬,毛瑢,方向民,卜文圣. 发明专利:一株路德维希肠杆菌PN6及其应用.申请号:ZL201911376891.X.申请日:20191227,公开/公告号:CN111117910B,授权公告日:20210831

[5]Chen, Fusheng; Zhang, Yang; Fang, Xiangmin and Wang, Fangchao. Australian Government, Innovation patent Australia: Enterobacter ludwigii PN6 and its application. Patent number: 2021104551. Term of patent: Eight years from 26 July 2021.

专著情况

[1]曾菊平,金志芳,陈伏生主编.九连山森林生态研究—动物昆虫专题.南昌:江西科学技术出版社. 2021

[2]黄超,胡小飞,金志芳,王方超,陈伏生著.九连山森林生态研究—生态系统服务价值评估.南昌:江西科学技术出版社. 2021

[3]陈伏生,张绿水,刘兵主编.江西绿色屏障研究与实践.南昌:江西人民出版社. 2020.

[4]叶清,金志芳,陈伏生主编.九连山森林生态研究—水土气候专题.南昌:江西科学技术出版社. 2020.

[5]陈伏生,卜文圣主编.园林观赏竹资源培育与应用评价.南昌:江西科学技术出版社. 2019.

[6]陈伏生主编.城乡梯度森林生态过程研究.北京:中国林业出版社. 2013.

获奖情况

[1]陈伏生,张文元,方向民,等.丘陵山区杉竹林地力提升与高产高效高值协同培育技术集成及示范（J-20-1-02-R01）.江西省科学技术进步奖,一等奖, 2021

[2]陈伏生,张绿水,刘兵,等.江西绿色屏障的研究与实践（19-3-128）.江西省社会科学界联合会,江西省第十九次社会科学优秀成果奖三等奖, 2021.

[3]陈伏生,毛瑢,方向民,等.生态文明江西试验区人工林结构优化及提质增效的理论与技术（2019-KJJ-2-45）.国家林业和草原局,第十届梁希林业科学技术奖,二等奖, 2019

[4]陈伏生,方运霆,胡小飞,等.南方城市森林生物地球化学循环特征及环境驱动机制(Z-17-2-04-R01).江西省人民政府,江西省自然科学奖,二等奖, 2018

[5]陈伏生,汪思龙,王辉民,等.亚热带人工林经营的生态化学计量学原理与应用(2016-KJ-3-31-R01).国家林业局,第七届梁希林业科学技术奖,三等奖, 2016

[6]陈伏生,季春峰,胡小飞,等.城乡森林氮磷削减理论与群落构建技术(2015-KJ-3-10-R01).国家林业局,第六届梁希林业科学技术奖,三等奖, 2015

[7]陈伏生,胡小飞,曾德慧.亚热带森林土壤关键过程调控及其与叶性状的关联性(Z-14-3-04-R01).江西省人民政府,江西省自然科学奖,三等奖, 2014

[8]张露,陈伏生,刘苑秋,等.江西人工公益林的关键生态过程与调控技术研究(2013-KJ-2-16).国家林业局科学技术委员会,第五届梁希林业科学技术奖,二等奖, 2013

[9]陈伏生,刘兴平,刘苑秋,等.立德树人 导学导研 强林兴林，新时代研究生导师队伍的建设与实践.江西省教学成果奖一等奖,2021

称号荣誉

[1]国家百千万人才

[2]国家有突出贡献中青年专家

[3]国务院政府特殊津贴专家

[4]全国林业和草原教学名师

[5]江西省优秀共产党员

[6]江西省新时代赣鄱先锋

[7]江西省5511优势科技创新团队人才

[8]江西省主要学科学术与技术带头人

[9]江西省百千万人才工程人选

[10]江西省青年科学家培养对象

[11]江西省高等学校中青年学科带头人

[12]江西省高等学校青年骨干教师

[13]江西省优秀博士论文指导教师

[14]江西省优秀硕士论文指导教师

[15]江西省优秀科技特派员

[16]辽宁省优秀（博士）毕业生

[17]中国科学院院长奖学金获得者

[18]Can J For Res优秀审稿人

[19]生态学报优秀审稿人

[20]生态学杂志优秀审稿人

[21]应用与环境生物学报优秀审稿人