教师列表

程谊

641A

男,安徽绩溪人,理学博士,金沙国际唯一官网高层次教授人才引进,副教授,硕士生导师,曾任中国科学院南京土壤研究所副研究员。主要从事土壤氮素循环及其农业与生态环境效应研究。在Earth-Science Reviews、Soil Biology and Biochemistry、Global Change BiologySCI期刊发表论文30多篇,其中第一/通讯作者SCI论文25篇(1区期刊17篇,2Top期刊3篇)。并发表中文综述5篇,其中2篇为《土壤学报》新视角与前沿论文。主持3项国家自然科学基金项目、2项国家重点研发计划项目子课题和1项德国EuroChem Agro GmbH技术服务项目。担任土壤学领域老牌权威期刊《EUR J SOIL SCI》副主编、Top期刊《AGR ECOSYST ENVIRON》编委、《农业环境科学学报》特邀责任编辑、《同位素》编委、并获农业环境科学学报(2次)、植物营养与肥料学报优秀审稿人。

 

通讯地址:南京市栖霞区文苑路1号金沙国际唯一官网-金沙国际唯一官网306

邮箱: ycheng@njnu.edu.cn

 

? 研究领域:

115N稀释和示踪技术研究土壤氮素周转机制;

2)新型肥料和增效剂的农学和环境效应评价;

3)农田氮面源污染防控、温室气体减排技术研发;

4)设施大棚土壤利用与修复.


? 个人经历

教育经历:

2010/10—2012/06,中国科学院南京土壤研究所,理学博士

2009/12—2010/09,加拿大埃尔伯塔大学,访问Scott X. Chang

2007/09—2009/11,中国科学院南京土壤研究所,硕博连读 蔡祖聪

2003/09—2007/06,安徽大学生命科学学院(211),理学学士

工作经历:

2018/05—至今,金沙国际唯一官网,高层次教授人才引进,副教授

2016/07—2018/04,中国科学院南京土壤研究所,副研究员

2012/07—2016/06,中国科学院南京土壤研究所,助理研究员


? 主持在研项目

(1) 国家自然科学基金面上项目:我国典型茶园土壤自养和异养硝化作用及其微生物驱动机制,主持,在研(2020.01-2023.12);

(2) 国家自然科学基金面上项目:外源碳对旱地土壤硝态氮同化速率的影响及其作用机理,主持,在研(2017.01-2020.12);

(3) 德国 EuroChem Agro GmbH技术资助项目:新型肥料及硝化抑制剂的农学和环境效应评价,主持,在研(2017.01-2019.12;

(4) 国家重点研发计划项目子课题:肥料氮素迁移转化过程与损失阻控机制,主持,在研(2017.07-2020.12);

(5) 国家重点研发计划项目子课题:农田氮磷径流流失污染与防控机制,主持,在研(2017.07-2020.12.


? 著作论文

[1] Sun X#, Liang B#, Wang J, Cheng Y*, Scott X. Chang, Cai ZC, Müller C, Zhang JB. 2020. Soil N transformation rates are not linked to fertilizer N losses in vegetable soils with high N input. Soil & Tillage Research, Accept.

[2] Cheng Y#, Wang J#, Wang JY, Wang SQ, Scott X. Chang, Cai ZC, Zhang JB*, Niu SL*, Hu SJ*. 2020. Nitrogen deposition differentially affects soil gross nitrogen transformations in organic and mineral forest horizons. Earth-Science Reviews, 201, 103033.

[3] Zhang Y, Dai SY, Huang XQ, Zhao Y, Zhao J*, Cheng Y, Cai ZC, Zhang JB*. 2020. pH-induced changes in fungal abundance and composition affects soil heterotrophic nitrification after 30 days of artificial pH manipulation. Geoderma, 366 (2020) 114255.

[4] He XX, Chi QD, Cai ZC, Cheng Y, Zhang JB*, Müller C. 2020. 15N tracing studies including plant N uptake processes provide new insights on gross N transformations in soil-plant systems. Soil Biology and Biochemistry, 141, 107666.

[5] Cheng Y, Wang J, Scott X. Chang, Cai ZC, Müller C, Zhang JB*. 2019. Nitrogen deposition affects both net and gross soil nitrogen transformations in forest ecosystems: A review. Environmental Pollution, 244, 608–616.

[6] Wang J, Sun N, Xu MG, Wang SQ, Zhang JB, Cai ZC, Cheng Y*. 2019. The influence of long-term animal manure and crop residue application on abiotic and biotic N immobilization in an acidified agricultural soil. Geoderma, 337, 710–717.

[7] Zhang Y, Liu SY, Cheng Y*, Cai ZC, Müller C, Zhang JB*. 2019. Composition of soil recalcitrant C regulates nitrification rates in acidic soils. Geoderma, 337, 965–972.

[8] Liu SY, Chi QD, Cheng Y*, Zhu B, Li WZ, Zhang XF, Huang YQ, Müller C, Cai ZC, Zhang JB*. 2019. Importance of matching soil N transformations, crop N form preference, and climate to enhance crop yield and reducing N loss. Science of the Total Environment, 657, 1265–1273.

[9] Cheng Y, Wang J, Sun N, Xu MG, Zhang JB*, Cai ZC, Wang SQ. 2018. Phosphorus addition enhances gross microbial N cycling in phosphorus-poor soils: a 15N study from two long-term fertilization experiments. Biology and Fertility of Soils, 54, 783-789.

[10] Wang J, Zhang BB, Tian Y, Zhang HC, Cheng Y*, Zhang JB. 2018. A soil management strategy for ameliorating soil acidification and reducing nitrification in tea plantations. European Journal of Soil Biology, 88, 36-40.

[11] She DL*, Zhang L, Gao XM, Yan XY, Zhao X, Xie WM, Cheng Y, Xia YQ*. 2018. Limited N removal by denitrification in agricultural drainage ditches in the Taihu Lake region of China. Journal of Soils and Sediments, 18, 1110-1119.

[12] Cheng Y, Wang J, Wang JY, Scott X. Chang, Wang SQ*. The quality and quantity of exogenous organic carbon input control microbial NO3- immobilization: A meta-analysis. Soil Biology and Biochemistry, 2017, 115, 357-363.

[13] Cheng Y, Xie W, Huang R, Yan XY, Wang SQ*. Extremely high N2O but unexpectedly low NO emissions from a highly organic and chemical fertilized peach orchard system in China. Agriculture, Ecosystems and Environment, 246, 202-209, 2017.

[14] Cheng Y, Zhang JB, Zhu JG, Liu G, Zhu CW*, Wang SQ*. Ten years of elevated atmospheric CO2 doesn’t alter soil nitrogen availability in a rice paddy, Soil Biology and Biochemistry, 98, 99-108, 2016.

[15] Cheng Y, Wang J, Bruno M, Zhang JB, Cai ZC*, Chang SX*, Soil pH has contrasting effects on gross and net nitrogen mineralization neighboring forest and grassland soils in Canada. Soil Biology and Biochemistry, 57, 848-857, 9, 2013.

[16] Cheng Y, Wang J, Zhang JB, Müller C, Wang SQ*, Mechanistic insights into the effects of N fertilizer application on N2O-emission pathways in acidic soil of a tea plantation. Plant and Soil, 389, 45-57, 11, 2015.

[17] Cheng Y, Wang J, Zhang JB, Bruno M, Cai ZC*. The mechanisms behind reduced NH4+ and NO3- accumulation due to litter decomposition in the acidic soil of subtropical forest. Plant and Soil, 378, 295-308, 1, 2014.

[18] Cheng Y, Cai ZC*, Zhang JB, Lang M, Bruno M, Chang SX*, Soil moisture effects on gross nitrification differ between adjacent grassland and forested soils in central Alberta, Canada. Plant and Soil, 352, 289-301, 9, 2012.

[19] Cheng Y, Cai ZC*, Zhang JB, Chang SX*, Gross N transformations were little affected by 4 years simulated N and S depositions in an spen-white spruce dominated boreal forest in Alberta, Canada. Forest Ecology and Management, 262, 571-578, 5, 2011.

[20] Cheng Y, Cai YJ, Wang SQ*, Yak and Tibetan sheep dung return enhance soil N supply and retention in two alpine grasslands in the Qinghai-Tibetan Plateau. Biology and Fertility of Soils, 52, 413-422, 1, 2016.

[21] Cheng Y, Zhang JB, Müller C, Wang SQ*, 15N tracing study to understand the N supply associated with organic amendments in a vineyard soil. Biology and Fertility of Soils, 51, 983-993, 8, 2015.

[22] Cheng Y, Wang J, Wang SQ, Zhang JB, Cai ZC*, Effects of soil moisture on gross N transformations and N2O emission in acid subtropical forest soils. Biology and Fertility of Soils, 50, 1099-1108, 6, 2014.

[23] Cheng Y, Cai ZC*, Chang SX*, Wang J, Zhang JB, Wheat straw and its biochar have contrasting effects on inorganic N retention and N2O emission in a cultivated Black Chernozemic soil. Biology and Fertility of Soils, 48, 941-946, 4, 2012.

[24] Cheng Y, Zhang JB, Wang J, Cai ZC, Wang SQ*. Soil pH is a good predictor of the dominating N2O production processes under aerobic conditions. Journal of Plant Nutrition and Soil Science, 178, 370-373, 3, 2015.

[25] Cheng Y, Wang J, Liu Y, Cai ZC*. Litter decomposition reduces either N2O or NO production in strongly acidic coniferous and broad-leaved forest soils under anaerobic conditions. Journal of Soils and Sediments, 14, 549-557, 10, 2014.

[26] Cheng Y, Cai ZC*, Chang SX*, Wang J, Zhang JB, Effects of soil pH and salt on N2O production in adjacen,t forest and grassland soils in central Alberta, Canada. Journal of Soils and Sediments, 13, 863-868, 2, 2013.

[27] Cheng Y, Wang J, Zhang JB, Wang SQ, Cai ZC*, The different temperature sensitivity of gross N transformations between the coniferous and broad-leaved forests in subtropical China. Soil Science and Plant Nutrition, 61, 506-515, 11, 2014.

[28] Cheng Y, Wang J, Wang L, Wang SQ, Cai ZC*, The effects of temperature change and tree species composition on N2O and NO emissions in acidic forest soils of subtropical China. Journal of Environmental Sciences, 26, 1-9, 7, 2014.

[29] Wang J, Cheng Y, Zhang JB*, Müller C, Cai ZC, Soil gross nitrogen transformations along a secondary succession transect in the north subtropical forest ecosystem of southwest China. Geoderma, 280, 88-95, 2016.

[30] Wang J, Cheng Y, Zhang JB*, Jiang YJ, Sun B, Fan JB, Zhang JB, Müller C, Cai ZC, Effects of 14 years of repeated pig manure application on gross nitrogen transformation in an upland red soil in China. Plant and Soil, 415, 161–173, 2017.

[31] Ma L, Cheng Y, Wang JY, Yan XY*, Mechanical insights into the effect of fluctuation in soil moisture on nitrous oxide emissions from paddy soil. Paddy Water Environ 15, 359–369, 2017.

[32] Cai YJ, Chang SX*, Cheng Y, Greenhouse gas emissions from excreta patches of grazing animals and their mitigation strategies. Earth-Science Reviews 171, 44-57, 2017.

[33] Wang JY, Chadwick DR, Cheng Y, Yan XY*. Global analysis of agricultural soil denitrification in response to fertilizer nitrogen. Science of the Total Environment 616–617 (2018) 908–917.

[34] Dai SY, Wang J, Cheng Y, Zhang JB*, Cai ZC*. 2017. Effects of long-term fertilization on soil gross N transformation rates and their implications. Journal of Integrative Agriculture 16(12): 2863–2870

[35] Zhang JB, Cai ZC*, Cheng Y, Zhu TB. Denitrification and total nitrogen gas production from forest soils of Eastern China. Soil Biology and Biochemistry, 41, 2551-2557, 10, 2009.

[36] Zhang JB, Cai ZC*, Cheng Y, Zhu TB, Immobilization of Nitrate in anaerobic Forest Soils along a North South Transect in East China. Soil Science Society of American Journal, 74, 1193-1200, 6, 2010.

[37] Cai ZC, Zhang JB, Zhu TB, Cheng Y, Stimulation of NO and N2O emissions from soils by SO2 deposition. Global Change Biology, 18, 2280-2291, 2, 2012.

[38] Zhang JB, Müller C, Zhu TB, Cheng Y, Cai ZC*. Heterotrophic nitrification is the predominant NO3- production mechanism in coniferous but not broad-leaf acid forest soil in subtropical China. Biology and Fertility of Soils, 47, 533-542, 2011.

[39] 顾江新#,郭艳杰#,张丽娟,王敬,王慎强,胡荣桂,张金波,蔡祖聪,程谊*. 2020. 果树种植土壤N2O排放研究:认识与挑战. 农业环境科学学报(约稿综述),第4期待刊.

[40] 程谊,张金波*, 蔡祖聪*. 气候-土壤-作物之间氮形态契合在氮肥管理中的关键作用. 土壤学报(新视角与前沿), 201954 (3), 507-515.

[41] 程谊,黄蓉,余云飞,王慎强*.应重视硝态氮同化过程在降低土壤硝酸盐浓度中的作用. 土壤学报(新视角与前沿), 201754 (6), 1326-1331.

[42] 程谊,贾云生,汪玉,赵旭,杨林章,王慎强*.太湖竺山湾小流域果园养分投入特征及其土壤肥力状况分析,农业环境科学学报2014, 33(10)1940-1947.

[43] 程谊,蔡祖聪*,张金波,15N同位素稀释法测定土壤氮素总转化速率研究进展, 土壤, 2009, 41(2), 165-171.

[44] 程谊,张金波,蔡祖聪*,土壤中无机氮的微生物同化和非生物固定作用研究进展, 土壤学报, 2012, 49 (5), 1030-1036.

[45] 崔静雅, 颜明娟, 吴晓荣, 王慎强, 倪康, 蔡祖聪, 张金波*, 程谊*,林地改为茶园对土壤净硝化速率及N2O排放的影响,土壤2017, 49(4)738–744.

[46] 吴晓荣,张蓓蓓*, 余云飞,黄蓉,颜明娟,倪康,崔静雅,王慎强,程谊*,硝化抑制剂对典型茶园土壤尿素硝化过程的影响。农业环境科学学报20173610),2063-2070.

[47] 张金波,程谊,蔡祖聪*. 土壤调配氮素迁移转化的机理. 地球科学进展,2019,341):11-19.

[48] 王敬,程谊,蔡祖聪,张金波*,长期施肥对农田土壤氮素关键转化过程的影响,土壤学报, 2016, 53 (2), 16-28.

[49] 党琦,于涌杰,程谊,张金波*,过硫酸钾氧化法测定溶解性有机氮含量和15N 丰度方法研究,土壤, 2013, 45(6), 999-1002.


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