General Information
Name: Zhang Guangbin
Title: Associate Professor
Work Email: gbzhang@issas.ac.cn
Work Phone: 025-86881132
Research Fields
(1)Greenhouse gas emissions from agroecosystems
(2)Soil carbon sequestration and emission reduction
(3)Climate change mitigation in agriculture
Education Background
(1)2006-2011, Ph.D., Soil Science, Institute of Soil Science, Chinese Academy of Sciences, Nanjing, China
(2)2002-2006, Bachelor, Environmental Science, Shandong Agricultural University, Taian, China
Professional Experience
(1)2019-2020, Visiting Scholar, Natural Resource Ecology Laboratory, Colorado State University, Fort Collins, USA
(2)2018-Present, Vice Director, Center for Soil Utilization and Environmental Change, Institute of Soil Science, Chinese Academy of Sciences, Nanjing, China
(3)2015-Present, Associate Professor, Center for Soil Utilization and Environmental Change, Institute of Soil Science, Chinese Academy of Sciences, Nanjing, China
(4)2011-2015, Assistant Professor, Center for Soil Utilization and Environmental Change, Institute of Soil Science, Chinese Academy of Sciences, Nanjing, China
Social Positions
(1)2022-Present, Member, Carbon Neutrality and Global Change Working Group, Soil Science Society of China (SSSC)
(2)2021-Present, Innovation member, Youth Working Committee, Soil Science Society of China (SSSC)
(3)2021-Present, Editorial Board Member, MC Agriculture & Environmental Sciences
(4)2021-2023, Guest Editor, Agronomy
(5)2020-2022, Review Editor, Frontiers in Agronomy, Frontiers in Soil Science
(6)2017-2020, Member, Asia Oceania Geosciences Society (AOGS)
(7)2016-2017, Member, European Geosciences Union (EGU)
(8)2011-Present, Member, Soil Science Society of China (SSSC)
Projects
(1)Shifting typical single rice into ratoon rice affects CH4 and N2O emissions and soil organic carbon in rice-based ecosystems, 2023.01-2026.12, National Natural Science Foundation of China (PI).
(2)Research and development and integrated demonstration of collaborative technology of green yield enhancement and carbon sequestration and emission reduction in paddy fields, 2022.09-2025.08, The Special fund project for science and technology development in Ningbo Science and Technology Bureau, Zhejiang Province, China (Co-PI).
(3)Study on key technologies of reducing greenhouse gas emission by coupling optimization of fertilizer and water in typical farmlands, 2022.01-2024.12, The Scientific and Technological Innovation Special Fund Project of Carbon Peak and Carbon Neutrality in Jiangsu Province, China (PI).
(4)Methanogenic pathways of the typical rice fields in China and the responses to key influencing factors, 2019.01-2022.12, National Natural Science Foundation of China (PI).
(5)Effect of fertilization on crop yield and greenhouse gas emissions from ratoon rice field under plastic film mulching cultivation, 2018.08-2020.08, The Open Project Program of Key Laboratory of Agricultural Environment in Southwest Mountain Areas, Ministry of Agriculture, China (PI).
(6)Quantification of ratoon rice rhizosphere priming effect and its microorganism mechanism, 2018.06-2020.05, The Open Project Program of State Key Laboratory of Soil and Sustainable Agriculture, Ministry of Science and Technology, China (Co-PI).
(7)Methanogenic pathways of the typical rice fields in China and the responses to key influencing factors, 2018.01-2021.12, The Youth Innovation Promotion Association of Chinese Academy of Sciences (PI).
(8)Mechanism in response of greenhouse gas emissions from rice fields to climate change and cultivation approach of emission reduction, 2017.07-2020.12, The National Key Research and Development Program of China (Participant).
(9)The study in mechanism of CH4 emission from rice with high response to [CO2] enrichment and the effect of N-fertilization, 2016.01-2019.12, National Natural Science Foundation of China (PI).
(10)CH4 and N2O emissions from ratoon rice fields in China, 2016.01-2018.12, The Knowledge Innovation Program of Institute of Soil Science, Chinese Academy of Sciences (PI).
(11)Mechanism in the effects of urea application on CH4 emission from rice field, 2014.07-2017.06, Outstanding Young Talent Program of State Key Laboratory of Soil and Sustainable Agriculture, Ministry of Science and Technology, China (PI).
(12)The mechanism of CH4 emission from permanently flooded rice fields and its response to water and fertilizer managements, 2013.01-2015.12, National Natural Science Foundation of China (PI).
(13)CH4 emission from permanently flooded rice fields: process mechanisms, influencing factors, and their responses to water and fertilizer managements, 2012.07-2015.06, the Jiangsu Province Science Foundation for Youths (PI).
Publications
Peer-reviewed Papers
(1)Yu HY, Zhang XC, Shen WY, Yao HY*, Meng XT, Zeng JY, Zhang GB*, Zamanien K. A global meta-analysis of ecological functions and economic benefits of co-culture models in paddy fields. Agriculture, Ecosystems and Environment, 2023, 341: 108195.
(2)Ji Y, Xu YJ, Zhao MY, Zhang GB*, Conrad R, Liu PF, Feng ZZ, Ma J, Xu H. Winter drainage and film mulching cultivation mitigated CH4 emission by regulating the function and structure of methanogenic archaeal and fermenting bacterial communities in paddy soil. Journal of Environmental Management, 2022, 323: 116194.
(3)Zhang GB, Huang Q, Song KF, Zhu XL, Ma J, Zhang Y, Yan XY, Xu H*. Gaseous emissions and grain-heavy metal contents in rice paddies: A three-year partial organic substitution experiment. Science of the Total Environment, 2022, 826: 154106.
(4)Zhang GB, Song KF, Huang Q, Zhu XL, Gong H, Ma J, Xu H*. Heavy metal pollution and net greenhouse gas emissions in a rice-wheat rotation system as influenced by partial organic substitution. Journal of Environmental Management, 2022, 307: 114599.
(5)Song KF, Zhang GB, Ma J, Peng SB, Lv SH*, Xu H*. Greenhouse gas emissions and health risk assessment of different ratoon rice varieties. Field Crops Research, 2022, 277: 108423.
(6)Yu HY, Zhang GB*, Xia LL, Huang Q, Ma J, Zhu CW, Shan J, Jiang Q, Zhu JG, Smith P, Yan XY, Xu H. Elevated CO2 does not necessarily enhance greenhouse gas emissions from rice paddies. Science of the Total Environment, 2022, 810: 152363.
(7)Yu HY, Zhang GB, Ma J, Wang TY, Song KF, Huang Q, Zhu CW, Jiang Q, Zhu JG, Xu H*. Elevated Atmospheric CO2 Reduces CH4 and N2O Emissions of Two Contrasting Rice Cultivars from a Subtropical Paddy Field in China. Pedosphere, 2022, 32(5): 707-717.
(8)Li BL, Peng SB, Shen RP, Yang ZL, Yan XY, Li XF, Li RR, Li CY, Zhang GB*. Development of a new index for automated mapping of ratoon rice cultivated area using time-series NDVI imagery. Pedosphere, 2022, 32(4): 576-587.
(9)Yu HY, Wang TY, Huang Q, Song KF, Zhang GB, Ma J, Xu H*. Effects of elevated CO2 concentration on CH4 and N2O emissions from paddy fields: A meta-analysis. Science China: Earth Science, 2022, 65(1): 96-106.
(10)Huang Q, Zhang GB, Ma J, Song KF, Zhu XL, Shen WY, Xu H*. Dynamic interactions of nitrogen fertilizer and straw application on greenhouse gas emissions and sequestration of soil carbon and nitrogen: A 13-year field study. Agriculture, Ecosystems and Environment, 2022, 325: 107753.
(11)Liu Q, Li Y, Liu S, Gao W, Shen J, Zhang GB, Xu H, Zhu Z, Ge T, Wu J. Anaerobic primed CO2 and CH4 in paddy soil are driven by Fe reduction and stimulated by biochar. Science of The Total Environment, 2022, 808: 151911.
(12)Wang S, Sun P, Zhang GB, Gray N, Dolfing J, Esquivel-Elizondo S, Pe?uelas J, Wu Y. Contribution of periphytic biofilm of paddy soils to carbon dioxide fixation and methane emissions. The Innovation, 2022, 3: 100192.
(13)Zhang GB, Zhu XL, Shen WY, Ji Y, Xu H, Ma J*. Methane emission and acetate-dependent methanogenesis in rice-based cropping systems with urea addition. MC Agriculture & Environmental Sciences, 2021, 1(4): 03-19.
(14)Sun G, Sun M, Du LS, Zhang Z, Wang ZC, Zhang GB, Nie SA, Xu HQ, Wang H*. Ecological rice-cropping systems mitigate global warming-A meta-analysis. Science of the Total Environment. 2021, 789: 147900.
(15)Yang YT, Zhang GB#, Ma J, Huang Q, Yu HY, Song KF, Zhu XL, Miao X, Xu H*. Responses of methanogenic pathway and fraction of CH4 oxidization to rice planting in a flooded paddy soil. Pedosphere, 2021, 31(6): 859-871.
(16)Zhang GB, Huang Q, Song KF, Yu HY, Ma J, Xu H*. Responses of greenhouse gas emissions and soil carbon and nitrogen sequestration to field management in the winter season: A 6-year measurement in a Chinese double-rice field. Agriculture, Ecosystems and Environment, 2021, 318: 107506.
(17)Zhang GB, Song KF, Miao X, Huang Q, Ma J, Gong H, Zhang Y, Keith P, Yan XY, Xu H*. Nitrous oxide emissions, ammonia volatilization, and grain-heavy metal levels during the wheat season: effect of partial organic substitution for chemical fertilizer. Agriculture, Ecosystems and Environment, 2021, 311: 107340.
(18)Song KF, Zhang GB#, Yu HY, Huang Q, Zhu XL, Wang TY, Xu H, Lv SH, Ma J*. Evaluation of methane and nitrous oxide emissions in a three-year case study on single rice and ratoon rice paddy fields. Journal of Cleaner Production, 2021, 297: 126650.
(19)Song KF, Zhang GB, Yu HY, Xu H, Lv SH, Ma J*. Methane and nitrous oxide emissions from a ratoon paddy field in Sichuan Province, China. European Journal of Soil Science, 2021, 72(3): 1478-1491.
(20)Dong YJ, Zeng FW, Yuan J, Zhang GB, Chen YX, Liu XJ, Hilario P, Ren TS, Lv SH*. Integrated rice management to simultaneously improve rice yield and nitrogen use efficiency in various paddy field environments. Pedosphere, 2020, 30(6): 863-873.
(21)Dong YJ, Yuan J, Zhang GB, Ma J, Hilario P, Liu XJ, Lv SH*. Optimization of nitrogen fertilizer rate under integrated rice management in the hilly area of Southwest China. Pedosphere, 2020, 30(6): 759-768.
(22)Dong YJ, Zhang GB, Ma J, Hilario P, Lv SH*. Water retention and warming effect of integrated rice management for the hilly areas of Southwest China. Agronomy Journal, 2020, 112(4): 3140-3151.
(23)Zhang GB, Yang YT, Huang Q, Ma J, Yu HY, Song KF, Dong YJ, Lv SH, Xu H*. Reducing yield-scaled global warming potential and water use by rice plastic film mulching in winter flooded paddy field. European Journal of Agronomy, 2020, 114: 126007.
(24)Liu G, Ma J, Yang YT, Yu HY, Zhang GB, Xu H*. Effects of straw incorporation with a microbial inoculant on nitrous oxide and methane emissions from a wheat-rice rotation system. Pedosphere, 2019, 29(2): 204-215.
(25)Yang YT, Huang Q, Yu HY, Song KF, Ma J, Xu H, Zhang GB*. Winter tillage with the incorporation of stubble reduces the net global warming potential and greenhouse gas intensity of double-cropping rice fields. Soil & Tillage Research, 2018, 183: 19-27.
(26)Zhang GB, Ma J, Yang YT, Yu HY, Song KF, Dong YJ, Lv SH, Xu H*. Achieving low methane and nitrous oxide emissions with high economic incomes in a rice-based cropping system. Agricultural and Forest Meteorology, 2018, 259: 95-106.
(27)Zhang GB, Ma J, Yang YT, Yu HY, Shi YP, Xu H*. Variations of stable carbon isotopes of CH4 emission from three typical rice fields in China. Pedosphere, 2017, 27(1): 52-64.
(28)Zhang GB, Yu HY, Fan XF, Yang YT, Ma J, Xu H*. Drainage and tillage practices in the winter fallow season mitigate CH4 and N2O emissions from a double-rice field in China. Atmospheric Chemistry and Physics, 2016, 16(18): 11853-11866.
(29)Zhang GB, Yu HY, Fan XF, Ma J, Xu H*. Carbon isotope fractionation reveals distinct process of CH4 emission from different compartments of paddy ecosystem. Scientific Reports, 2016, 6: 27065.
(30)Liu G, Yu HY, Zhang GB, Xu H, Ma J*. Combination of wet irrigation and nitrification inhibitor reduced nitrous oxide and methane emissions from a rice cropping system. Environmental Science and Pollution Research, 2016, 23(17): 17426-17436.
(31)Zhang GB, Yu HY, Fan XF, Liu G, Ma J, Xu H*. Effect of rice straw application on stable carbon isotopes, methanogenic pathway, and fraction of CH4 oxidized in a continuously flooded rice field in winter season. Soil Biology & Biochemistry, 2015, 84: 75-82.
(32)Zhang GB, Zhang WX, Yu HY, Ma J, Xu H*, Yagi K. Increase in CH4 emission due to weeds incorporation prior to rice transplanting in a rice-wheat rotation system. Atmospheric Environment, 2015, 116: 83-91.
(33)Zhang GB, Zhang WX, Yu HY, Ma J, Xu H*, Yagi K. Fraction of CH4 oxidized in paddy field measured by stable carbon isotopes. Plant and Soil, 2015, 389: 349-359.
(34)Ji Y, Liu G, Ma J, Zhang GB, Xu H*. Effects of urea and controlled release urea fertilizers on methane emission from paddy fields: A multi-year field study. Pedosphere, 2014, 24(5): 662–673.
(35)Li XL, Ma J, Yao YJ, Liang SL, Zhang GB, Xu H*, Yagi K. Methane and nitrous oxide emissions from irrigated lowland rice paddies after wheat straw application and midseason aeration. Nutrient Cycling in Agroecosystems, 2014, 100: 65-76.
(36)Zhang GB, Ji Y, Liu G, Ma J, Xu H*. Carbon isotope fractionation during CH4 transport in a paddy field. SCIENCE CHINA Earth Sciences, 2014, 57(7): 1664-1670.
(37)Zhang GB, Liu G, Zhang Y, Ma J, Xu H*, Yagi K. Methanogenic pathway and fraction of CH4 oxidized in paddy fields: seasonal variation and effect of water management in winter fallow season. PLoS ONE, 2013, 8(9): e73982.
(38)Zhang GB, Ji Y, Ma J, Liu G, Xu H*, Cai ZC, Yagi K. Pathway of CH4 production, fraction of CH4 oxidized, and 13C isotope fractionation in a straw incorporated rice field. Biogeosciences, 2013, 10: 3375-3389.
(39)Ma J, Ji Y, Zhang GB, Xu H*, Yagi K. Timing of midseason aeration to reduce CH4 and N2O emissions from double rice cultivation in China. Soil Science and Plant Nutrition, 2013, 59(1): 35-45.
(40)Ji Y, Liu G, Ma J, Zhang GB, Xu H*, Yagi K. Effect of controlled-release fertilizer on mitigation of N2O emission from paddy field in South China: a multi-year field observation. Plant and Soil, 2013, 371:473-486.
(41)Zhang GB, Ji Y, Ma J, Xu H*, Cai ZC, Yagi K. Intermittent irrigation changes production, oxidation, and emission of CH4 in paddy fields determined with stable carbon isotope technique. Soil Biology & Biochemistry, 2012, 52: 108-116.
(42)Zhang XY, Zhang GB, Ji Y, Ma J, Xu H*, Cai ZC. Straw application altered CH4 emission, concentration and 13C-isotopic signature of dissolved CH4 in a rice field. Pedosphere, 2012, 22(1): 13-21.
(43)Zhang GB, Zhang XY, Ji Y, Ma J, Xu H*, Cai ZC. Carbon isotopic composition, methanogenic pathway, and fraction of CH4 oxidized in a rice field flooded year-round. Journal of Geophysical Research, 2011, 116, G04025.
(44)Zhang GB, Zhang XY, Ma J, Xu H*, Cai ZC. Effect of drainage in the fallow season on reduction of CH4 production and emission from permanently flooded rice fields. Nutrient Cycling in Agroecosystems, 2011, 89(1): 81-91.
(45)Zhang GB, Ji Y, Ma J, Xu H*, Cai ZC. Case study on effects of water management and rice straw incorporation in rice fields on production, oxidation, and emission of methane during fallow and following rice seasons. Soil Research, 2011, 49(3): 238-246.
(46)Li XL, Zhang GB, Xu H*, Cai ZC, Yagi K. Effect of timing of joint application of hydroquinone and dicyandiamide on nitrous oxide emission from irrigated lowland rice paddy field. Chemosphere, 2009, 75(10): 1417-1422.
(47)Ma ED, Zhang GB, Ma J, Xu H*, Cai ZC, Yagi K. Effects of rice straw returning methods on N2O emission during wheat-growing season. Nutrient Cycling in Agroecosystems, 2010, 88(3): 463-469.
(48)Zhang GB, Li XL, Ma J, Xu H*, Cai ZC. Effects of water management on production, oxidation, and emission of CH4 from rice paddy soil. Ecology and Environmental Sciences, 2009, 18(3): 1066-1070. (In Chinese)
(49)Zhang GB, Ma J, Xu H*, Cai ZC. Application of stable carbon isotope technique in study of methane emission from rice field. Acta Pedologica Sinica, 2009, 46(4): 676-683. (In Chinese)
(50)Zhang GB, Ma J, Xu H*, Cai ZC. Literature review on estimation of methane emission from paddy fields in China. Acta Pedologica Sinica, 2009, 46(5): 907-916. (In Chinese)
(51)Zhang GB, Ma ED, Zhang XY, Ma J, Xu H*, Cai ZC. Effects of rice straw incorporation and land management in winter on methane emission during rice-growing season. Journal of Agro-Environment Science, 2009, 28(12); 2501-2505. (In Chinese)
(52)Zhang GB, Ma J, Ma ED, Xu H*, Cai ZC. Effects of Urea application on methane production, oxidation and emission from a paddy soil. Soils, 2010, 42 (2): 178-183. (In Chinese)
(53)Zhang GB, Zhang XY, Ma ED, Ma J, Xu H*, Cai ZC. Effects of land management in winter on production, oxidation and emission of CH4 during the rice-growing season. Journal of Ecology and Rural Environment, 2010, 26(2): 97-102. (In Chinese)
(54)Zhang GB, Zhang XY, Ji Y, Ma J, Li XP, Xu H*, Cai ZC. Effects of rice straw application in winter on CH4 production, oxidation, and emission from continuously flooded rice field during the rice-growing season. Soils, 2010, 42(6): 895-900. (In Chinese)
(55)Zhang GB, Ma J, Xu H*, Cai ZC. Advances on methanogenic pathways in rice fields. Soils, 2011, 43(1): 6-11. (In Chinese)
(56)Zhang XY, Ma ED, Zhang GB, Ma J, Xu H*, Cai ZC. Effects of rice straw application in wheat season on production, oxidation and emission of CH4 during the following rice-growing season. Journal of Agro-Environment Science, 2010, 29(9); 1827-1833. (In Chinese)
(57)Zhang XY, Zhang GB, Ji Y, Ma J, Xu H*, Cai ZC. Study on the rules of CH4 production, oxidation, and emission and their influencing factors in continuously flooded rice field. Ecology and Environmental Sciences, 2010, 19(11): 2540-2545. (In Chinese)
(58)Yu J, Liu G, Ma J, Zhang GB, Xu H*, Cai ZC. CH4 and N2O fluxes from winter fallow paddy fields in a hilly area of southeast China. Ecology and Environmental Sciences, 2012, 21(1): 55-58. (In Chinese)
(59)Zhang XY, Zhang GB, Ji Y, Ma J, Xu H*, Cai ZC. Temporal variation of CH4 flux and its δ13C from winter flooded rice field. Acta Pedologica Sinica, 2012, 49(2): 296-302. (In Chinese)
(60)Zhang WX, Yu HY, Zhang GB, Ma J, Xu H*. Effect of rice variety on production and emission of CH4 and δ13CH4. Ecology and Environmental Sciences, 2015, 24(2): 196-203. (In Chinese)
(61)Song KF, Yu HY, Zhang GB, Xu H, Lv SH, Ma J*. N2O emissions from ratoon paddy fields covered with plastic film mulching in the hilly area of central Sichuan, China. Journal of Agro-Environment Science, 2019, 38(6): 1381-1387. (In Chinese)
(62)Song KF, Yang YT, Yu HY, Zhang GB, Xu H, Lv SH, Ma J*. Effects of plastic film mulching cultivation of ratoon rice on CH4 emissions in the hilly area of central Sichuan, China. Acta Ecologica Sinica, 2019, 39(19): 7258-7266. (In Chinese)
(63)Song KF, Zhang GB, Xu H, Ma J*. A Review of Research on Influencing Factors and Sustainability of Ratoon Rice Cultivation in China. Acta Pedologica Sinica, 2020, 57(6): 1365-1377. (In Chinese)
(64)Sun YX, Zhang GB, Fang H, Zhang ZB, Liao CL, Zhou H*. Effects of pore structure on greenhouse gas emission of paddy soils. Soils, 2020, 53(1): 154-160. (In Chinese)
(65)Miao X, Huang Q, Zhu XL, Ma J, Zhang GB, Xu H*. Effects of partial organic substitution for chemical fertilizer on CH4 and N2O emissions in paddy field. Ecology and Environmental Sciences, 2020, 29(4): 740-747. (In Chinese)
(66)Yu HY, Zhang GB, Ma J, Xu H*. Response of CH4 and N2O emissions to elevated atmospheric CO2 concentration from rice fields: A review. Soils, 2021, 53(3): 458-467. (In Chinese)
(67)Yu HY, Huang Q, Wang TY, Zhang GB, Ma J, Zhu CW, Xu H*. Effect of elevated CO2 on N2O emissions from different rice cultivars in rice fields. Environmental Science, 2021, 42(8): 3924-3930. (In Chinese)
(68)Yu HY, Song KF, Huang Q, Wang TY, Zhang GB, Ma J, Zhu CW, Xu H*. Response of Yield, CH4 and N2O emissions from paddy fields to long-term elevated CO2 concentration. Environmental Science, 2021, 42(10): 5021-5029. (In Chinese)
(69)Wang TY, Fan D, Song KF, Zhang GB, Xu H, Ma J*. Reduced methane and nitrous oxide emissions from ratoon rice paddy in Chaohu polder area, China. Journal of Agro-Environment Science, 2021, 40(8): 1829-1838. (In Chinese)
(70)Yu HY, Wang TY, Huang Q, Song KF, Zhang GB, Ma J, Xu H*. Effects of elevated CO2 concentration on CH4 and N2O emissions from paddy fields: A meta-analysis. Science China Earth Sciences, 2022, 65(1): 96–106. (In Chinese)
(71)Yu HY, Wang TY, Huang Q, Zhang GB, Ma J, Zhu CW, Xu H*. Effect of long-term elevated CO2 concentration on CH4 emissions from rice paddy fields. Acta Pedologica Sinica, 2022, 59(4): 1057–1067. (In Chinese)
(72)Zhu XL, Huang Q, Song KF, Ma J, Zhang GB*, Xu H. Seasonal variations in methane production potential and methanogenic pathway in a permanently flooded rice field. Acta Pedologica Sinica, 2022, DOI: 10.11766/trxb202107050347. (In Chinese)
(73)Shen WY, Huang Q, Song KF, Ma J, Zhang GB*, Xu H. Methane production potential and methanogenic pathways in paddy soils under different rice-based cropping systems. Environmental Science, 2022, 43(7): 462-470. (In Chinese)
(74)Zhang G B, Ma J, Xu H, et al. Status quo of research and suggestions on reduction of non-CO2 greenhouse gas emission from Chinese farmland. Bulletin of Chinese Academy of Sciences, 2022, doi: 10.16418/j.issn.1000-3045.20211112001. (In Chinese)
Book Chapters
(1)Zhang GB. Chapter 5: Application of carbon stable isotope tracing technology in soil carbon cycle research. In: Zhang JB, Dai SY, Wen T, Cai ZC (Eds.). Principle and application of carbon and nitrogen stable isotope tracer. Beijing: Science Press, 2022, 110-145.
(2)Zhang GB, Xie ZB. Chapter 9: Greenhouse gas emissions from farmland and carbon sequestration technology. In: State Key Laboratory of Soil and Sustainable Agriculture (Eds.). Soil management for sustainable agricultural. Beijing: Science Press, 2021, 266-316.
(3)Zhang GB. Chapter 10: Use of 13C natural abundance method and tracer technique to study the processes of carbon cycling in soils. In: Cao YC, Zhang JB, Wen T, et al. (Eds.). Stable isotope tracer technique and mass spectrometry analysis: the applications in study of soil, ecology and environment. Beijing: Science Press, 2018, 285-302.
(4)Yan XY, Li YE, Xu H, Zhang GB, Ma J. Chapter 8: The control technology of greenhouse gas emissions from paddy fields. In: Wang LG, Qiu JJ, et al. (Eds.). Agricultural sources of greenhouse gas monitoring technology research procedures and control technology. Beijing: Science Press, 2016, 122-141.
Conference Papers
(1)Zhang GB, Ma J, Xu H*, Lv SH, Yan XY*. Mitigation of yield-scaled global warming potential by plastic mulch technology in rice crops in Southwestern China. In “Climate Smart Agriculture for the Small-Scale Farmers in the Asian and Pacific Region”, Edited by Shirato H and Hasebe A, 2019, 1-18.
Awards & Honors
(1)2022, The Young and Middle-Aged Science and Technology leader of “333 High-Level Talents Project” in Jiangsu Province, China.
(2)2018, Member of Youth Innovation Promotion Association, Chinese Academy of Sciences, China.
(3)2016, Outstanding Young Scholar Award of Soil Science Society of China (SSSC).
(4)2012, Best Paper Award of State Key Laboratory of Soil and Sustainable Agriculture, Institute of Soil Science, Chinese Academy of Sciences, Nanjing, China.
(5)2011, Outstanding Dean Award, Chinese Academy of Sciences, China.
(6)2011, The Wuyisun Award, Nanjing Branch of Chinese Academy of Sciences, China.
