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南京农业大学资源与环境科学学院导师教师师资介绍简介-熊正琴

/2021-03-27


熊正琴,1973年6月生于中国重庆市涪陵区,汉族,2008年1月作为留学引进人才被南京农业大学特聘为资源与环境科学学院土壤学
(国家重点学科)教授,美国波特兰州立大学物理系兼职研究教授,主要研究领域为碳氮循环与生态环境。
e-mail: zqxiong@njau.edu.cn Phone: 86-25-84395148 Fax: 86-25-84395210 Mobile:
86-1360-5188-915
一、教育经历:
1999/9 - 2002/6,中国科学院,植物营养学,博士,导师:朱兆良院士
1996/9 - 1999/8,南京农业大学,蔬菜学,硕士,导师:李式军教授
1992/9 - 1996/7,南京农业大学,园艺,学士二、工作经历:
2008/1 - 至今,南京农业大学,资源与环境科学学院,教授,博士生导师
2007/6 - 2007/12,美国波特兰州立大学,物理系,助理研究教


2005/1 - 2007/12,美国波特兰州立大学,物理系,高级访问学

者、博士后
2002/7 - 2005/1,中国科学院南京土壤研究所,助理研究员三、获奖情况
① 国家教育部2019 年度高等学校科学研究优秀成果奖—自然科学一等奖“稻田温室气体排放与生物质炭减排潜力 ” 邹建文、潘根兴、熊正琴、张阿凤、王金阳
② 江苏省十大青年科技之星 2014.


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③ 国家教育部新世纪优秀人才(NCET-10-0475) 2009.
④ 江苏省科学技术进步奖一等奖 2004.
⑤ 江苏省第一届优秀硕士学位论文奖 2000.
四、主持或参加科研项目及人才计划项目情况:
(1) 主持人才计划项目情况:
① 教育部新世纪优秀人才计划,NCET-10-0475,农田生态系统温室气体排放规律研究,2010/01-2012/12,50 万元,已结题,主持。
② 南京农业大学引进杰出人才基金,030804094,氮素循环与生态环境,2008/01-2010/12,50 万元,已结题,主持。
(2) 主持国家自然科学基金项目情况:
① 国家自然科学基金面上项目,41977078,菜地氧化亚氮产生过程辨析及羟胺和亚硝态氮的潜在贡献,2020/01-2023/12, 62 万元,在研,主持。
② 国家自然科学基金面上项目,41471192,生物炭对菜地土壤 N2O 产生过程的影响机理研究,2015/01-2018/12,90 万元,已结题,主持。
③ 国家自然科学基金面上项目,41171238,农业生物质循环利用 减 缓 稻 田 综 合 净 温 室 效 应 潜 力 观 测 与 评 估 , 2012/01-2015/12,70
万元,已结题,主持。
④ 国家自然科学基金面上项目,40971139,水旱轮作体系中土壤剖面N2O 行为过程及机理研究,2010/01-2012/12,40 万元,已结题,主持。
(3) 主持其他科研项目情况:


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① 公益性行业(农业)科研专项,201503106,“化肥面源污染农田综合治理技术方案”课题-气态损失过程阻控研究与集成示范,2015/01-2019/12,138 万元,在研,课题主持。
② 公益性行业(农业)科研专项,200903003,“气候变化对农业生产的影响及应对技术研究”课题-气候变化对稻麦轮作系统养分管理的影响及应对技术研究,2009/01-2013/12,
71.4 万元,已结题,课题主持。
③ 国家科技支撑计划,2013BAD11B01,子课题菜地氧化亚氮减排技术研发,2013/01-2016/12,78 万元,在研,子课题主持。
④ 国家科技部 973 计划,2009CB118603,“主要粮食作物高产栽培与资源高效利用的基础研究”子课题—南方高产高效稻田体系综合温室效应观测研究,2009/01-2013/12,15
万元,已结题,子课题主持。
⑤ 高等学校博士学科点专项科研基金博导类资助课题, 20110097110001,集约化种植模式下蔬菜地生态系统碳收支及净温室效应的观测与评估,2012/01-2014/12,12
万元,已结题,主持。
⑥ 国际合作项目,DE-FG02-08ER64515,甲烷和氧化亚氮收支缺口研究,2008/01-2010/12,55 万元,已结题,主持。
⑦ 国际合作项目,DE-FG02-04ER63913,稻田温室气体排放, 2005/04-2007/09,83 万元,已结题,主持。
(4) 参与科研项目情况:
① 高等学校学科创新引智计划,B12009,农业资源与环境学科生物学研究创新引智基地,2012/01-2016/12,450 万元,已结题,骨干参与。
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② 国家自然科学基金重点项目,40830528,稻田土壤有机碳固定与稳定化过程及机制:土壤-作物-微生物相互作用研究, 2009/01-2012/12,175 万元,已结题,骨干参与。
③ 国家自然科学基金“十·五”重大项目,30390080,主要农田生态系统氮素行为与氮肥高效利用的基础研究, 2003/01-2006/12,800 万元,已结题,骨干参与。
五、发表论文
发表SCI 文章(*通讯作者):
1. Xiong Z.Q.*, Xing G.X., Tsuruta H., Shen G.Y., Shi S.L., Du L.J. (2002) Measurement of
nitrous oxide emissions from two rice-based cropping systems in China. Nutrient Cycling in
Agroecosystems 64: 125–133.
2. Xiong Z.*, Xing G., Tsuruta H., Shen G., Shi S., Du L. (2002) Field study on nitrous oxide
emissions from upland cropping systems in China. Soil Science and Plant Nutrition 48: 539–546.
3. Xing G.X.*, Shi S.L., Shen G.Y., Du L.J., Xiong Z.Q. (2002) Nitrous oxide
emissions from paddy soil in three rice-based cropping systems in China. Nutrient Cycling in
Agroecosystems 64: 135–143.
4. Xing G.*, Zhu J., Xiong Z.*, and Yamasaki S. (2004) Ag, Ta, Ru and Ir enrichment in surface
soil: Evidence for land pollution of heavy metal from atmospheric deposition. Global
Biogeochemical Cycles 18(1): GB1046, doi: 10.1029/2003GB002123.
5. Zhu Z.*, Xiong Z., Xing G. (2005) Impacts of population growth and economic
development on the nitrogen cycle in Asia. Science in China (Series C, Life Sciences) 48
(special issue): 729–737.
6. Xiong Z.Q.*, Xing G.X., Zhu Z.L. (2006) Water dissolved nitrous oxide from paddy
agroecosystem in China. Geoderma 136: 524–532. DOI: 10.1016/j.geoderma.2006.04.010
7. Xiong Z.*, Xie Y., Xing G., Zhu Z. and Butenhoff C. (2006) Measurements
of nitrous oxide emissions from vegetable production in China. Atmospheric
Environment 40: 2225–2234. doi: 10.1016/j.atmosenv.2005.12.008.

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8. Xiong Z.Q.*, Xing G.X., and Zhu Z.L. (2007) Nitrous oxide and methane emissions as affected
by water, soil and nitrogen. Pedosphere 17(2): 146– 155.
9. Xie Y.X., Xiong Z.Q., Xing G.X. *, Sun G.Q., Zhu Z.L. (2007) Assessment
of nitrogen pollutant sources in surface waters of Taihu lake region. Pedosphere 17(2): 200–208.
10. Xiong Z.Q., Freney J.R., Mosier A.R.*, Zhu Z.L., Lee Y. and Yagi K. (2008) Impacts
of population growth, changing food preferences and agricultural practices on the nitrogen
cycle in East Asia. Nutrient Cycling in Agroecosystems 80:189–198 DOI: 10.1007/s10705-007-9132-4.
11. Xie Y., Xiong Z.*, Xing G., Yan X., Shi S., Sun G., Zhu Z. (2008) Source of nitrogen in wet
deposition to a rice agroecosystem at Tai lake region. Atmospheric Environment
42: 5182–5192. doi:10.1016/j.atmosenv.2008.03.008.
12. Xiong Z.Q. *, Khalil M.A.K.*, Xing G., Shearer M.J., Butenhoff C. (2009) Isotopic
signatures and concentration profiles of nitrous oxide in a rice-based ecosystem during the drained
crop-growing season. J. Geophys. Res. 114, G02012.
13. Zhao X., Xie Y.X., Xiong Z.Q., Yan X.Y., Xing G.X.*, Zhu Z.L. (2009) Nitrogen fate and
environmental consequence in paddy soil under rice-wheat rotation in the Taihu lake
region, China. Plant Soil 319: 225– 234. DOI 10.1007/s11104-008-9865-0
14. Zhao X., Yan X., Xiong Z., Xie Y., Xing G. *, Shi S., Zhu Z. (2009) Spatial and
temporal variation of inorganic nitrogen wet deposition to the Yangtze river delta region,
China. Water Air Soil Pollut 203:277–289. DOI 10.1007/s11270-009-0011-2
15. Yang X., Shang Q., Wu P., Liu J., Shen Q., Guo S.?, Xiong Z?.(2010) Methane
emissions from double rice agriculture under long-term fertilizing systems in
Hunan, China. Agriculture, Ecosystems and Environment 137: 308-316.
doi:10.1016/j.agee.2010.03.001
16. Xiong Z.Q*, Huang T.Q., Ma Y.C., Xing G.X. and Zhu Z.L. (2010) Nitrate and ammonium
leaching in variable- and permanent-charge paddy soils. Pedosphere 20(2): 209–216


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17. Wang J.Y., Jia J.X., Xiong Z.Q.*, Khalil M.A.K.*, Xing G.X. (2011) Water
regime-nitrogen fertilizer-straw incorporation interaction: field study on nitrous oxide
emissions from a rice agroecosystem in Nanjing, China. Agriculture, Ecosystems and
Environment 141: 437–446. doi:10.1016/j.agee.2011.04.009
18. Wang J., Zhang M., Xiong Z.*, Liu P., Pan G. (2011) Effects of biochar addition on N2O and
CO2 emissions from two paddy soils. Biology and Fertility of Soils 47: 887–896. DOI:
10.1007/s00374-011-0595-8
19. Wang J., Xiong Z.*, Yan X. (2011) Fertilizer-induced emission factors
and background emissions of N2O from vegetable fields in China. Atmospheric
Environment 45:6923–6929. doi:
10.1016/j.atmosenv.2011.09.045.
20. Xia W., Zhang C., Zeng X., Feng Y., Weng J., Lin X., Zhu J., Xiong Z., Xu J., Cai Z. and
Jia Z.* (2011) Autotrophic growth of nitrifying community in an agricultural
soil. The ISME Journal 1–11. doi:10.1038/ismej.2011.5
21. Wang J., Zhang X., Xiong Z. *, Khalil M.A.K., Zhao X., Xie Y., Xing G. (2012) Methane
emissions from a rice agroecosystem in South China: Effects of water regime, straw
incorporation and nitrogen fertilizer. Nutr Cycl Agroecosyst 93:103-112. DOI
10.1007/s10705-012-9503-3
22. Wang J., Zhang X., Liu Y., Pan X., Liu P., Chen Z., Huang T., Xiong Z.* (2012) Modeling
impacts of alternative practices on net global warming potential and greenhouse gas intensity from
rice–wheat annual rotation in China. PLoS ONE 7(9): e45668
23. Wang J., Pan X., Liu Y., Zhang X., Xiong Z.* (2012) Effects of biochar amendment in two soils
on greenhouse gas emissions and crop production. Plant Soil 360(1): 287–298. DOI
10.1007/s11104-012-1250-3
24. Ma Y., Wang J., Zhou W., Yan X., Xiong Z.* (2012) Greenhouse gas emissions during
the seedling stage of rice agriculture as affected by cultivar type and crop density.
Biology and Fertility of Soils 48: 489–595. DOI: 10.1007/s00374-011-0656-z
25. Jia J., Sun L., Kong X., Yan X., Xiong Z.* (2012) Annual N2O and CH4 emissions from
intensively managed vegetable fields in Nanjing, China.


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Soil Science and Plant Nutrition 58: 91–
103.doi.org/10.1080/00380768.2011.644510.
26. Jia J.X., Ma Y.C., Xiong Z.Q.* (2012) Net ecosystem carbon budget, net global warming
potential and greenhouse gas intensity in intensive vegetable ecosystems in China.
Agriculture, Ecosystems and Environment 150: 27– 37.
27. Jia J., Li B., Chen Z., Xie Z. and Xiong Z.* (2012) Effects of biochar
application on vegetable production and emissions of N2O and CH4. Soil Science and
Plant Nutrition 58: 503–509.
DOI:10.1080/00380768.2012.686436
28. Liu S., Zhang L., Jiang J., Chen N., Yang X., Xiong Z., Zou J.* (2012) Methane and nitrous
oxide emissions from rice seedling nurseries under flooding and moist irrigation regimes in
Southeast China. Science of the Total Environment 426: 166–171.
29. Wang B., Zhang C., Liu J., Zeng X., Li F., Wu Y., Lin X., Xiong Z., Xu J., Jia Z.* (2012)
Microbial community changes along a land-use gradient of desert soil origin. Pedosphere 22(5):
593–603.
30. Sun L., Li B., Ma Y., Wang J., Xiong Z.* (2013) Year-round atmospheric wet and dry
deposition of nitrogen and phosphorus on water and land surfaces in Nanjing,
China. Water Environ. Res. 85: 514–521. doi:10.2175/106143012X13560205144614
31. Ma Y.C., Kong X.W., Yang B., Zhang X.L., Yan X.Y., Yang J.C., Xiong
Z.Q. *(2013) Net global warming potential and greenhouse gas intensity of annual rice-wheat
rotations with integrated soil-crop system management. Agriculture, Ecosystems and
Environment. 164: 209– 219. DOI:10.1016/j.agee.2012.11.003
32. Ma Y., Sun L., Zhang X., Yang B., Wang J., Yin B., Yan X., Xiong Z.* (2013) Mitigation of
nitrous oxide emissions from paddy soil under conventional and no-till practices using
nitrification inhibitors during the winter wheat growing season. Biology and Fertility of Soils
49(6): 627– 635. DOI: 10.1007/s00374-012-0753-7
33. Wang J., Chen Z., Ma Y., Sun L., Xiong Z. *, Huang Q.*, Shen Q. (2013) Methane and nitrous
oxide emissions as affected by organic-inorganic


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mixed fertilizer from a rice paddy in southeast China. J Soils Sediments
13:1408–1417. DOI 10.1007/s11368-013-0731-1
34. Sun L., Liu Y., Wang J., Khalil M.A.K., Zou J., Xiong Z.* (2014) Atmospheric
nitrogen and phosphorus deposition at three sites in Nanjing, China, and possible links to
nitrogen deposition sources. CLEAN
- Soil, Air, Water 42 (11): 1650–1659. DOI:10.1002/clen.201300692
35. Sun L., Li L., Chen Z., Wang J., Xiong Z.* (2014) Combined effects of nitrogen deposition
and biochar application on emissions of N2O, CO2, and NH3 from agricultural and
forest soils. Soil Science and Plant Nutrition 60 (2): 254–265.
DOI:10.1080/00380768.2014.885386
36. Zhang X., Fan C., Ma Y., Liu Y., Li L., Zhou Q., Xiong Z. * (2014) Two approaches for
net ecosystem carbon budgets and soil carbon sequestration in a rice-wheat
rotation system in China. Nutrient Cycling in Agroecosystems 100: 301–313. DOI:
10.1007/s10705-014-9651-8
37. Li Z.*, Liu H., Luo C., Li P., Li H. and Xiong Z. (2014) Industrial wastewater
discharge retrieval based on stable nighttime light imagery in China from 1992 to
2010. Remote Sens. 6 : 7566–7579; doi:10.3390/rs6087566
38. Zhang M., Fan C.H., Li Q.L., Li B., Zhu Y.Y., Xiong Z.Q.* (2015) A 2-yr field
assessment of the effects of chemical and biological nitrification inhibitors on nitrous oxide
emissions and nitrogen use efficiency in an intensively managed vegetable cropping system.
Agriculture, Ecosystems and Environment 201: 43–50. DOI: 10.1016/j.agee.2014.12.003
39. Yang B., Xiong Z.*, Wang J., Xu X., Huang Q.*, Shen Q. (2015). Mitigating net
global warming potential and greenhouse gas intensities by substituting chemical nitrogen
fertilizers with organic fertilization strategies in rice-wheat annual rotation systems in
China: A 3-year field experiment. Ecological Engineering
289–297. 10.1016/j.ecoleng.2015.04.071
40. Yang B., Chen Z., Zhang M., Zhang H., Zhang X., Pan G., Zou J., Xiong Z.* (2015) Effects
of elevated atmospheric CO2 concentration and temperature on the soil profile methane
distribution and diffusion in rice– wheat rotation system. Journal of Environmental Sciences
32: 62–71. DOI:10.1016/j.jes.2014.11.010
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41. Li B., Fan C.H., Xiong Z.Q.*, Li Q.L., Zhang M. (2015) The combined effects of nitrification
inhibitor and biochar incorporation on yield-scaled N2O emissions from an intensively
managed vegetable field in southeastern China.
Biogeosciences12: 2003–
2017.doi:10.5194/bg-12-2003-2015
42. Li B., Fan C.H., Zhang H., Chen Z.Z., Sun L.Y., Xiong Z.Q.* (2015) Combined
effects of nitrogen fertilization and biochar on the net global warming potential,
greenhouse gas intensity and net ecosystem economic budget in intensive vegetable
agriculture in southeastern China. Atmospheric Environment 100:
10–19. DOI: 10.1016/j.atmosenv.2014.10.034
43. Liu Y.L., Zhou Z., Zhang X., Xu X., Chen H., Xiong Z.* (2015). Net global
warming potential and greenhouse gas intensity from the double rice system with
integrated soil–crop system management: A three-year field study.
Atmospheric Environment 116:92–101. DOI:10.1016/j.atmosenv.2015.06.018
44. Wang J., Chen Z., Xiong Z.*, Chen C., Xu X., Zhou Q., Kuzyakov Y. (2015) Effects
of biochar amendment on greenhouse gas emissions, net ecosystem carbon budget and properties
of an acidic soil under intensive vegetable production. Soil Use and Management. 31:
375–383. DOI: 10.1111/sum.12202
45. Li Z.*, Liu H., Luo C., Li Y., Li H., Pan J., Jiang X., Zhou Q., Xiong Z. (2015) Simulation
of runoff and nutrient export from a typical small watershed in China using the
Hydrological Simulation Program–Fortran. Environ Sci Pollut Res. DOI 10.1007/s11356-014-3960-y.
46. Wang J., Wang C., Chen N., Xiong Z., Wolfe D., Zou J.* (2015) Response of rice
production to elevated [CO2] and its interaction with rising temperature or nitrogen supply:
a meta-analysis. Climatic Change doi :10.1007/s10584-015-1374-6
47. Li Z.*, Luo C., Xi Q., Li H., Pan J., Zhou Q., Xiong Z. (2015) Assessment of the
AnnAGNPS model in simulating runoff and nutrient in a typical small watershed in the Taihu
Lake basin, China. Catena 133 : 349–361. DOI : 10.1016/j.catena.2015.06.007


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48. Zhao M., Tian Y., Ma Y., Zhang M., Yao Y., Xiong Z., Yin B.*, Zhu Z.(2015)
Mitigating gaseous nitrogen emissions intensity from a Chinese rice cropping system through an
improved management practice aimed to close the yield gap. Agriculture, Ecosystems & Environment
203: 36–45.
49. Xu W., Luo X. S., Pan Y. P., Zhang L., Tang A. H., Shen J. L., Zhang Y., Li K. H., Wu Q. H.,
Yang D. W., Zhang Y. Y., Xue J., Li W. Q., Li Q. Q., Tang L., Lu S. H., Liang T., Tong Y. A., Liu
P., Zhang Q., Xiong Z. Q., Shi X. J., Wu L. H., Shi W. Q., Tian K., Zhong X. H., Shi K., Tang Q.
Y., Zhang L. J., Huang J. L., He C. E., Kuang F. H., Zhu B., Liu H., Jin X., Xin Y. J., Shi X.
K., Du E. Z., Dore A. J., Tang S., Collett Jr. J. L., Goulding K., Sun Y. X., Ren
J., Zhang F. S., and Liu X. J. (2015) Quantifying atmospheric nitrogen deposition
through a nationwide monitoring network across China. Atmos. Chem. Phys., 15, 12345-12360.
doi:10.5194/acp-15-12345-2015
50. Xiong Z.*, Liu Y., Wu Z., Zhang X., Liu P., Huang T. (2015) Differences in net global
warming potential and greenhouse gas intensity between major rice-based cropping systems in
China. Scientific Report 5, 17774. doi:10.1038/srep17774
51. Wang J.Y.*, Xiong Z.Q., & Kuzyakov Y. (2016) Biochar stability in soil: meta-analysis of
decomposition and priming effects. GCB Bioenergy. 8(3):512-523. DOI: 10.1111/gcbb.12266.
52. Zhang M., Chen Z.Z., Li Q.L., Fan C.H., Xiong Z.Q.* (2016). Quantitative
relationship between nitrous oxide emissions and nitrogen application rate for a typical
intensive vegetable cropping system in Southeastern China. CLEAN - Soil, Air, Water. 44 (12):
1725–1732. DOI: 10.1002/clen.201400266
53. Liu Y.L., Dokohely M. E., Fan C.H., Li Q.L., Zhang X.X., Zhao H.Y., Xiong Z.Q.*
(2016). Influence of different seedling-nursing methods on methane and nitrous oxide emissions in
the double rice cropping system of South China. CLEAN - Soil, Air, Water
44(12):1733–1738. DOI: 10.1002/clen.201400479
54. Wang J.Y., Dokohely M.E., Xiong Z.Q.*, Kuzyakov Y. (2016) Contrasting effects
of aged and fresh biochars on glucose-induced priming


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and microbial activities in paddy soil. J Soils Sediments. 16:191–203. DOI:
10.1007/s11368-015-1189-0
55. Chen Z., Zhang J., Xiong Z.*, Pan G., Müller C. (2016) Enhanced gross nitrogen transformation
rates and nitrogen supply in paddy fields under elevated atmospheric carbon dioxide and
temperature. Soil Biology and Biochemistry 94: 80-87. DOI:10.1016/j.soilbio.2015.11.025
56. Zhou Z., Xu X., Bi Z., Li L., Li B., Xiong Z.* (2016) Soil concentration profiles and
diffusion and emission of nitrous oxide influenced by the application of biochar in a
rice-wheat annual rotation system. Environ Sci Pollut Res. 23:7949-7961. DOI:
10.1007/s11356-015-5929-x
57. Zhang X., Xu X., Liu Y., Wang J., Xiong Z.* (2016) Global warming potential and
greenhouse gas intensity in rice agriculture driven by high yields and nitrogen use
efficiency. Biogeosciences 13, 2701-2714, doi:10.5194/bg-13-2701-2016
58. Wang J., Xiong Z.*, Yan X., Kuzyakov Y. (2016) Carbon budget by priming in a
biochar-amended soil. European Journal of Soil Biology 76: 26-34. DOI information:
10.1016/j.ejsobi.2016.07.003
59. Chen Z., Wang B., Wang J., Pan G., Xiong Z.*. (2016) Contrasting effects of
elevated CO2 and warming on temperature sensitivity of soil organic matter decomposition
in a Chinese paddy field. Environmental Monitoring and Assessment
188(10):545. DOI: 10.1007/s10661-016-5563-1
60. Zhang, M. Li B., Xiong Z.Q. *. (2016) Effects of organic fertilizer on net global warming
potential under an intensively managed vegetable field in southeastern China: a
three-year field study. Atmospheric Environment. 145: 92-103. DOI:
10.1016/j.atmosenv.2016.09.024
61. Xu X., Wu Z., Dong Y., Zhou Z., Xiong Z. *(2016) Effects of nitrogen and biochar amendment
on the soil methane concentration profiles and diffusion in a rice-wheat annual rotation
system. Scientific Report 6, 38688. DOI: 10.1038/srep38688
62. Li B., Bi Z., Xiong Z.* (2017) Dynamic responses of nitrous oxide emission and
nitrogen use efficiency to nitrogen and biochar amendment in an intensified vegetable field in
southeastern China. GCB Bioenergy. 9:400-413. DOI: 10.1111/gcbb.12356.
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63. Fan C., Chen H., Li B., Xiong Z.* (2017) Biochar reduces yield-scaled emissions of
reactive nitrogen gases from vegetable soils across China. Biogeosciences, 14, 2851–2863.
Doi:10.5194/bg-14-2851-2017
64. Fan C., Li B., Xiong Z.* (2018) Nitrification inhibitors mitigated reactive gaseous nitrogen
intensity in intensive vegetable soils from China. Science of the
Total Environment, 612: 480–489.DOI: 10.1016/j.scitotenv.2017.08.159.
65. Duan P., Wu Z., Zhang Q., Fan C., Xiong Z.* (2018) Thermodynamic responses of
ammonia-oxidizing archaea and bacteria explain N2O production from greenhouse
vegetable soils. Soil Biology and Biochemistry 120C:
37-47.10.1016/j.soilbio.2018.01.027.
66. Sun L., Wu Z., Ma Y., Liu Y., Xiong Z.* (2018) Ammonia volatilization and atmospheric N
deposition following straw and urea application from a rice-wheat rotation in southeastern China.
Atmospheric Environment 181: 97–105.
67. Sun L., Wu Z., Ma Y., Liu Y., Xiong Z.* (2018) Nitrogen fertilizer in combination
with an ameliorant mitigated yield-scaled greenhouse gas emissions from a coastal saline
rice field in southeastern China. Environ Sci Pollut Res. 25(16):15896–15908.
68. Duan P., Zhang X., Zhang Q., Wu Z., Xiong Z.* (2018) Field-aged biochar stimulated
N2O production from greenhouse vegetable production soils by nitrification and denitrification.
Science of the Total Environment 642: 1303–1310.
69. Wu Z., Zhang X., Dong Y., Xu X., Xiong Z. *(2018) Microbial explanations
for field-aged biochar mitigating greenhouse gas emissions during a rice-growing season.
Environ Sci Pollut Res. 25(31): 31307– 31317.DOI: 10.1007/s11356-018-3112-x
70. Duan P., Zhang Q., Fan C., Xiong Z. *(2019) Overdose fertilization favors
ammonia-oxidizing archaea producing nitrous oxide in intensive vegetable fields. Science of
the Total Environment. 650: 1787–1794. DOI: 10.1016/j.scitotenv.2018.09.341
71. Yang B., Ma Y., Xiong Z.* (2019) Effects of different composting strategies on
methane, nitrous oxide and carbon dioxide emissions and


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nutrient loss during small-scale anaerobic composting. Environ Sci Pollut Res.
26(1):446-455.DOI:10.1007/s11356-018-3646-y
72. Duan P., Zhou J., Feng L., Xiong Z. *(2019) Pathways and controls of N2O
production in greenhouse vegetable production soils. Biology and Fertility of Soils. 55
(3):285-297. doi:10.1007/s00374-019-01348-9. 73.

73. Li B., Zhou J., Lu Y., Xiong Z.* (2019) Field-aged biochar reduces the greenhouse gases
balance in a degraded vegetable field treated by reductive soil disinfestation.
Environ Sci Pollut Res. 26:10609–10620. DOI: 10.1007/s11356-019-04130-4
74. Chen H., Zhou J., Li B., Xiong Z.* 2019. Yield-scaled N2O emissions as affected by
nitrification inhibitor and overdose fertilization under an intensively managed
vegetable field: A three-year field study. Atmospheric
Environment.206C: 247-257.
10.1016/j.atmosenv.2019.02.036.
75. Zhou J., Li B., Xia L., Fan C., Xiong Z.* (2019) Organic-substitute strategies
reduced carbon and reactive nitrogen footprints and gained net ecosystem economic benefit for
intensive vegetable production. Journal of Cleaner Production 225: 984-994.
10.1016/j.jclepro.2019.03.
76. Zhang X., Duan P., Wu Z., Xiong Z.* (2019) Aged biochar stimulated
ammonia-oxidizing archaea and bacteria-derived N2O and NO production in an acidic vegetable
soil. Science of the Total Environment. 687: 433-440. 10.1016/j.scitotenv.2019.06.128
77. Wu Z., Zhang X., Dong Y., Li B., Xiong Z. * (2019) Biochar amendment reduced greenhouse gas
intensities in the rice-wheat rotation system: six-year field observation and
meta-analysis. Agricultural and Forest Meteorology. 278:107625
78. Dong Y., Wu Z., Zhang X., Feng L., Xiong Z. * (2019) Dynamic responses of
ammonia volatilization to different rates of fresh and field-aged biochar in
a rice-wheat rotation system. Field Crop Research.241, 107568
79. Wu Z., Song Y., Shen H., Jiang X., Li B., Xiong Z.* (2019) Biochar can mitigate methane
emissions by improving methanotrophs for prolonged


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period in fertilized paddy soils. Environmental Pollution. 253, 1038-1046.
10.1016/j.envpol.2019.07.073.
80. Duan P., Zhang Q., Zhang X., Xiong Z. * (2019) Mechanisms of mitigating nitrous
oxide emissions from vegetable soil varied with manure, biochar and nitrification inhibitors.
Agricultural and Forest Meteorology. 278:107672
81. Zhang Q., Song Y., Wu Z., Yan X., Gunina A., Kuzyakov Y., Xiong Z.* (2020) Effects of
six-year biochar amendment on soil aggregation, crop growth, nitrogen and phosphorus use
efficiency in a rice-wheat rotation. Journal of Cleaner
Production 242:118435. doi.org/10.1016/j.jclepro.2019.118435
82. Wu Z., Zhang Q., Zhang X., P. Duan, Yan X., Xiong Z.* (2019) Biochar-enriched soil
mitigated N2O and NO emissions similarly as fresh biochar for wheat production. Science of
the Total Environment. 687: 433-440. 10.1016/j.scitotenv.2019.134943
83. Duan P., Song Y., Li S., Xiong Z.* (2019) Responses of N2O production pathways and
related functional microbes to temperature across greenhouse vegetable field soils.
Geoderma. 355: 113904
发表中文及非SCI文章(*通讯作者):
1. 熊正琴,李式军,周燮,刘高琼,黄保健.茉莉酸甲酯和水杨酸促进大蒜试管鳞茎的形成. 园艺学报. 1999,26(6): 408–409.
2. 熊正琴,刘高琼,李式军.大蒜鳞茎发芽抑制物质对几种作物发芽及生长的影响.南京师大学报,1999,22(3):139–141,146.
3. 王广东,周素平,吴镇,熊正琴,李式军. 稀有香辛植物山葵的离体培养与快速繁殖研究. 南京师大学报,1999,22(3)167–170.
4. 熊正琴,李式军,刘高琼,黄保健.大蒜花序轴离体培养的研究.南京农业大学学报,2000,23(3):25–28.
5. Xiong Z.Q., Xing G.X., Tsuruta H., Shi S.L., Shen G.Y., Du L.J., Qian W. Nitrous oxide emissions
from upland farmland as affected
by summer legume crop cultivation. Agricultural Sciences in China 2002, 1: 977–981.
6. 熊正琴,邢光熹,沈光裕,孙德玲.太湖地区湖、河和井水中氮污染状况

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的研究. 农村生态环境,2002,(2):29–33.
7. 熊正琴,邢光熹,沈光裕,施书莲,杜丽娟.太湖地区湖水与河水中溶解 N2O 及其排放.环境科学,2002, 23(6):26–30.
8. 熊正琴,邢光熹,鹤田治雄,施书莲,沈光裕,杜丽娟,钱薇. 种植夏季
豆科作物对旱地 N2O 排放贡献的研究. 中国农业科学 ,2002, 35(9):1104–1108.
9. 熊正琴,邢光熹,沈光裕,施书莲,钱薇. 人为活动N 对太湖地区水体中
溶解 N2O 的影响. 农业环境保护,2002, 21(5):389–392.
10. 熊正琴,邢光熹,鹤田治雄,施书莲,沈光裕.冬季耕作制度对农田 N2O排放的贡献. 南京农业大学学报,2002, 25(4):49–52.
11. 熊正琴,邢光熹,施书莲,杜丽娟. 轮作制度对稻田水稻季节 N2O 排放的影响. 应用生态学报, 2003,14(10): 1761–1764.
12. 熊正琴,邢光熹,鹤田治雄, 施书莲,沈光裕,杜丽娟.豆科绿肥和化肥
氮对双季稻稻田 N2O 排放贡献的研究.土壤学报,2003, 40 (5): 704–
710.
13. 熊正琴,邢光熹,沈光裕,施书莲.太湖地区井水中溶解 N2O 及其排放的研究.中国生态农业学报,2003, 11(3):99-101.
14. 谢迎新,邢光熹,熊正琴,孙国庆.常熟地区河湖水体的氮污染源研究.农业环境科学学报, 2006,25(3):766–771.
15. 邓美华,谢迎新,熊正琴,邢光熹,颜晓元.长江三角洲氮收支的估算及其环境影响.环境科学学报, 2007,27 (10) : 1709–1716.
16. 谢迎新,赵旭,熊正琴,邢光熹.污水灌溉对稻田土壤氮磷淋失动态变化的影响.水土保持学报,2007,21(4):43–46, 71.
17. 谢迎新,熊正琴,赵旭,邢光熹,郭天财.富营养化河水灌溉对稻田土壤氮磷养分贡献的影响- 以太湖地区黄泥土为例. 生态学报,2008,
28(8):3618–3625.
18. 李晓,颜晓元,邢光熹,熊正琴,史陶钧,沈光裕,曾晓春.不同动物排泄物氮的作物利用及对 N2O 排放的贡献.土壤, 2008, 40(4): 548–553.
19. 谢迎新,张淑利,赵旭,熊正琴,邢光熹长江三角洲地区雨水中 NH +
-N/NO --N 和 15NH +值的变化.应用生态学报,2008,19 (9): 2035–2041.

15

20. Xing G., Zhao X., Xiong Z., Yan X., Xu H., Xie Y., Shi S. (2009)
Nitrous oxide emission from paddy fields in China. Acta Ecologica Sinica 29: 45–50.
21. 黄太庆,马煜春,熊正琴*,孔宪旺,余丰毅.不同种植制度对稻田旱作
季节 CH4 和N2O 排放的影响.生态与农村环境学报,2010, 26 (6):519– 523.
22. 马煜春,孙丽英,孔宪旺,黄太庆,熊正琴*.太湖地区不同集约化栽培
模式下稻田 CH4 排放,土壤学报,2011,48(6)1166–1172.
23. 熊正琴*,邹建文,潘根兴.气候变化对农田生态系统碳氮过程的影响及其生产的启示,农业环境科学学报,2011, 30(9):1720-1725.
24. 刘平丽,张啸林,熊正琴*,黄太庆,丁敏,王金阳.不同水旱轮作体系稻田土壤剖面 N2O 的分布特征.应用生态学报,2011, 22(9): 2363-2369.
25. 程琨,潘根兴*,邹建文,李恋卿,熊正琴,张旭辉,郑金伟. 1949–2006
年间中国粮食生产的气候变化影响风险评价 . 南京农业大学学报,2011(03):83–88.
26. 邹建文,熊正琴.气候变化对农田生态系统碳氮过程的影响.科学中国
人, 2011(5): 29–33.|
27. 贾俊香,张曼,熊正琴*,李叶.南京郊区集约化大棚蔬菜地氧化亚氮排放规律.应用生态学报,2012, 23 (3) :739–744.
28. 贾俊香,熊正琴*,孙丽英.小白菜地土壤剖面 N2O 分布特征与土壤性质变化. 山西农业大学学报(自然科学版),2012, 32(01): 48–52.
29. 张啸林,潘晓健,熊正琴*,王金阳,杨波,刘英烈,刘平丽.应用 DNDC 模
型分析管理措施对稻麦轮作系统 CH4 和 N2O 综合温室效应的影响.应用生态学报,2013,24 (3):690–696.
30. 孔宪旺,刘英烈,熊正琴*,马煜春,张啸林,秦建权,唐启源.湖南地区不
同集约化栽培模式下双季稻稻田 CH4 和 N2O 的排放规律.环境科学学报,2013,33:2612–2618.
31. 李跃飞,夏永秋,李晓波,熊正琴*,颜晓元*.秦淮河典型河段总氮总磷
时空变异特征.环境科学(2013) 34(1):91–97.
32. 杨波,陈照志,周自强,张旭辉,潘根兴,熊正琴*.大气 CO2 浓度和温度

16

升高对稻麦轮作系统土壤剖面甲烷分布的影响. 中国科技论文,2014,9(9):985–990.
33. 李博,李巧玲,范长华,孙丽英,熊正琴*.施用生物炭与硝化抑制剂对
菜地综合温室效应的影响.应用生态学报,2014,25 (9):2651–2657.
34. 李博,张曼,熊正琴*.施用氮肥与生物炭对菜地净综合温室效应的影响研究.中国科技论文,2014,9(9):1057–1062.
35. 李晨华,张彩霞,唐立松,熊正琴,王保战,贾仲君,李彦.长期施肥土壤
微生物群落的剖面变化及其与土壤性质的关系. 微生物学报, 2014(03):319–329.
36. 周自强,李露,张恒,熊正琴*.氮肥配施小麦秸秆生物炭对稻麦轮作土
壤剖面 CH4 和 N2O 浓度的影响.南京农业大学学报,2015,3:431–438.
37. 李露,周自强,潘晓健,熊正琴*.不同时期施用生物炭对稻田 N2O 和 CH4排放的影响.土壤学报, 2015,52 (4):139–148.
38. 潘晓健,刘平丽,李露,周自强,熊正琴*.氮肥和秸秆施用对稻麦轮作
体系下土壤剖面 N2O 时空分布的影响.土壤学报,2015,52 (2):364– 371.
39. 李露,周自强,潘晓健,李博,熊正琴*.氮肥与生物炭施用对稻麦轮作
系统甲烷和氧化亚氮排放的影响. 植物营养与肥料学报, 2015,
21(5):1095–1103.
40. 贾俊香,熊正琴*.典型菜地土壤剖面 N2O、CH4 与 CO2 分布特征研究.中国生态农业学报. 2015, 23(12):1536-1543
41. 张恒,周自强,赵海燕,熊正琴*.青奥会前后南京 PM2.5 重金属污染水平与健康风险评估.环境科学,2016,37(1):28-34
42. 贾俊香,熊正琴*.秸秆生物炭对菜地 N2O、CO2 与 CH4 排放及土壤化学性质的影响.生态与农村环境学报,2016, 32(2):283-288
43. 许欣,陈晨,熊正琴*.生物炭与氮肥对稻田甲烷氧化菌和产甲烷菌数量和潜在活性的影响.土壤学报,2016,53(6):1517-1527
44. 陈晨,许欣,毕智超,熊正琴*.生物炭和有机肥对菜地土壤 N2O 排放及硝化 - 反硝化微生物功能基因丰度的影响 . 环境科学学
报,2017,37(5): 1912-1920.

17

45. 陈晨, 王春隆, 周璐遥, 吴玲, 张钰婷, 熊正琴*. 施用生物炭和硝
化抑制剂对菜地 N2O 排放和蔬菜产量的影响. 南京农业大学学报,2017,40(2):287-294.
46. 陈浩,李博,熊正琴*. 减氮及硝化抑制剂对菜地氧化亚氮排放的影响.
土壤学报, 2017,54(4):938-947
47. 毕智超, 张浩轩, 房歌, 郭澍, 熊正琴*. 不同配比有机无机肥料对菜地 N2O 排放的影响. 植物营养与肥料学报, 2017, 23(1): 154-161.
48. 董玉兵, 吴震,李博,许欣,熊正琴*. 追施生物炭对稻麦轮作中麦
季氨挥发和氮肥利用率的影响. 植物营养与肥料学报, 2017, 23(5):
1258–1267.
49. 熊正琴*,张晓旭. 氮肥高效施用在低碳农业中的关键作用. 植物营养与肥料学报, 2017, 23(6): 1433–1440.
50. 李双双,陈晨,段鹏鹏,许欣,熊正琴*. 生物质炭对酸性菜地土壤 N2O 排放及相关功能基因丰度的影响. 植物营养与肥料学报
2018,24(2), 414-423.
51. 吴震,董玉兵,熊正琴. 生物炭施用 3 年后对稻麦轮作系统 CH4 和 N2O综合温室效应的影响. 应用生态学报 2018, 29(1) : 141-148.
DOI:10.13287/j.1001-9332.201801.028
52. 李博,卢瑛, 熊正琴*.施用生物质炭对集约化菜地土壤肥力质量的影
响.土壤学报 2018,55(6):1345-1357.
53. 冯练,周俊,董玉兵,李双双,熊正琴*.生物质炭对集约化菜地 N2O 排放和蔬菜产量的影响. 植物营养与肥料学报 2019, 25(7): 1116–
1125
54. 宋燕凤,张前前,吴震,段鹏鹏,熊正琴 2020.陈化生物质炭对稻田土壤团聚体稳定性和磷素利用效率的影响. 植物营养与肥料学报
五、专著:
① Xiong Z., Freney J., Mosier A., Zhu Z., Lee Y. and Yagi K. (2008) Impacts of agriculture on the
nitrogen cycle. In Changes in the Human-Monsoon System of East Asia in the Context of Global
Change, Fu C., Freney J. & Stewart J. (Ed.s) World Scientific Publishing Company LTD,
Singapore. ISBN

18

981-283-241-6
② Xiong Z. & Khalil M.A.K. (2009) Greenhouse Gases from Crop Fields. In Climate
Change and Crops. Singh, S.N. (Ed.). Springer. DOI
10.1007/978-3-540-88246-6 6 ISBN 978-3-540-88245-9
③ 熊正琴,邹建文,李恋卿. 气候变化对农田生态系统过程的影响.主编潘根兴
《气候变化对中国农业生产的影响分析与评估》,中国农业出版社,北京,2010. pp99-115
④ Jane M.-F.Johnson, Virginia L.Jin, Caroline Colnenne-David, Catherine
E.Stewart, Claudia PozziJantalia, Zhengqin Xiong. Soil Health and
Intensification of Agroecosytems. Book 2017. Chapter 12 - Row-Crop Production
Practices Effects on Greenhouse Gas Emissions.
https://doi.org/10.1016/B978-0-12-805317-1.00012-9
六、已授权中国发明专利:
① 熊正琴, 李式军.刘高琼,黄保健,周素平.一种大蒜脱毒种苗快速繁殖的方法.一种大蒜脱毒种苗快速繁殖的方法. 中国发明专利,ZL99 1 14259.4
授权公告日 2002-9-18
② 熊正琴,黄太庆,马煜春.水旱轮作稻田土壤气体原位采集系统及采集方法.中国发明专利,ZL200810235421.7。授权公告日 2011-10-12


























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