教師簡介
| 姓名:鄭循華 職務(wù):碳中和研究院院長 職稱:教授 電子郵箱:[email protected] | |
個(gè)人簡歷 | ||
鄭循華,,女,,1964年10月出生,四川省雅安市人,。博士,,博士生導(dǎo)師,碳中和研究院院長,,環(huán)境地球化學(xué)團(tuán)隊(duì)帶頭人,。 | ||
教育/工作經(jīng)歷 | ||
2024.11-至今 河南師范大學(xué)環(huán)境學(xué)院 教授 2014.09-至今 中國科學(xué)院大學(xué)崗位教授(先后分別擔(dān)任研究生專業(yè)核心基礎(chǔ)課《碳氮循環(huán)及其模擬》和《碳氮生物地球化學(xué)基礎(chǔ)與模型》的首席教授) 2009.11-至今 中國科學(xué)院大氣物理研究所,二級(jí)研究員 2007.9-2009.10 中國科學(xué)院大氣物理研究所,,三級(jí)研究員 2004.11-2005.10 德國海姆霍茲國家研究中心聯(lián)合國卡爾斯 魯厄研究中心,高級(jí)客座科學(xué)家(全職,,正高級(jí)) 2002.2-2024.10 中國科學(xué)院大氣物理研究所,研究員 1996.6-2002.1 中國科學(xué)院大氣物理研究所,,助研,,副研 1990.8-1993.8 中國科學(xué)院長沙農(nóng)業(yè)現(xiàn)代化研究所(現(xiàn)中國科學(xué)院亞熱帶農(nóng)業(yè)生態(tài)研究所),助研 1993.9-1996.6 中國科學(xué)院大氣物理研究所 博士 1987.9-1990.8 中國科學(xué)院沈陽應(yīng)用生態(tài)研究所 碩士 1983.9-1987.8 北京農(nóng)業(yè)大學(xué)(現(xiàn)中國農(nóng)業(yè)大學(xué))土壤農(nóng)業(yè)化學(xué)系 學(xué)士 | ||
研究領(lǐng)域 | ||
長期從事碳氮循環(huán)和陸地生態(tài)系統(tǒng)-大氣碳氮?dú)怏w交換研究,,并做出如下重要學(xué)術(shù)貢獻(xiàn): 1.陸地生物地球化學(xué)過程模型自主研發(fā):獨(dú)立或主持創(chuàng)建區(qū)域氮循環(huán)模型IAP-N(長期應(yīng)用于編制我國提交聯(lián)合國的國家農(nóng)田N2O排放清單)和高分辨率三維水文-生物地球化學(xué)過程模型CNMM-DNDC(作為地球系統(tǒng)數(shù)值模擬國家大科學(xué)裝置的陸地生物地球化學(xué)過程分系統(tǒng)模型離線版),。 2.碳氮?dú)怏w地氣交換通量的原位測量技術(shù)方法自主研發(fā):主持研制了多組分碳氮?dú)怏w地氣交換通量箱法自動(dòng)觀測系統(tǒng)、渦動(dòng)相關(guān)法觀測系統(tǒng),、氮?dú)獾韧寥篮獨(dú)怏w排放同步直接測定系統(tǒng),,推動(dòng)了開路中紅外量子級(jí)聯(lián)激光氨分析儀等高精度、快響應(yīng)國產(chǎn)碳氮?dú)怏w激光分析儀的自主研發(fā),、批量國產(chǎn)與科研應(yīng)用,。 3.科研團(tuán)隊(duì)建設(shè):圍繞碳氮?dú)怏w地氣交換研究,在大氣邊界層物理和大氣化學(xué)國家重點(diǎn)實(shí)驗(yàn)室創(chuàng)建成一個(gè)建制化科研團(tuán)隊(duì),,該團(tuán)隊(duì)集測量技術(shù)方法研發(fā),、過程機(jī)理探索、過程模型構(gòu)建與清單及預(yù)測評(píng)估研究于一體,。 4.在Nature,、GCB、GBC等國際主流學(xué)術(shù)期刊發(fā)表研究論文190余篇(Web of Science H-指數(shù)48),。 | ||
主要學(xué)術(shù)及社會(huì)兼職 | ||
2006—2024,,擔(dān)任中國氣象學(xué)會(huì)理事 2016—2024,,擔(dān)任中國氣象學(xué)會(huì)大氣環(huán)境學(xué)委員會(huì)主任委員 2011至今,,擔(dān)任全球農(nóng)業(yè)溫室氣體研究聯(lián)盟(GRA,一個(gè)政府間部長級(jí)聯(lián)盟)中國專家代表 2016至今,,擔(dān)任GRA的農(nóng)業(yè)景觀管理研究網(wǎng)絡(luò)負(fù)責(zé)人 2021至今,,擔(dān)任Agr. Ecosys. Envirn.(中科院一區(qū)SCI期刊)副主編2013—2016,擔(dān)任政府間氣候變化專門委員會(huì)(IPCC)的EFDB編委 2017—2019,,擔(dān)任IPCC溫室氣體清單指南主要作者 2021—2024,,擔(dān)任IPCC《短期氣候驅(qū)動(dòng)因素方法學(xué)報(bào)告》撰寫規(guī)劃專家 | ||
科研項(xiàng)目情況 | ||
先后主持承擔(dān)國際國內(nèi)科研任務(wù)28項(xiàng),,合計(jì)經(jīng)費(fèi)10471余萬元: 1.國際合作科研項(xiàng)目 聯(lián)合國全球環(huán)境基金(GEF)課題(2001-2005年,72萬美元,,折合597萬元) 歐洲氮計(jì)劃項(xiàng)目專題(2006-2011年,,7萬歐元,折合70萬元) 德國科學(xué)基金會(huì)項(xiàng)目(2004-2009年,,7萬歐元,,折合70萬元) 2.國家自然科學(xué)基金項(xiàng)目 國家杰出青年基金項(xiàng)目(2005-2008年,140萬元) 創(chuàng)新研究群體項(xiàng)目(2011-2015年,,1200萬元) 重點(diǎn)項(xiàng)目(2024-2028年,,2003-2007年,合計(jì)450萬元) 重點(diǎn)國際合作項(xiàng)目(2018-2022年,,356萬元) 其他項(xiàng)目(合計(jì)287萬元) 3.科技部科研項(xiàng)目 973計(jì)劃項(xiàng)目(2011-2015年,,3842萬元) 重點(diǎn)研發(fā)計(jì)劃課題(2023-2027年,395萬元) 4.國家發(fā)改委科研項(xiàng)目 國家重大科技基礎(chǔ)設(shè)施建設(shè)項(xiàng)目子任務(wù)(2018-2022年,,580萬元) 5.農(nóng)業(yè)部科研項(xiàng)目 公益性行業(yè)(農(nóng)業(yè))科研專項(xiàng)課題(2008-2010年,,2011-2015年,合計(jì)524萬元) 6.中國科學(xué)院科研項(xiàng)目 重要方向性項(xiàng)目(2006-2010年,,300萬元) 百人計(jì)劃(2009年,,100萬元) 科研儀器設(shè)備研制項(xiàng)目(2009-2017年,240萬元) 先導(dǎo)科技專項(xiàng)課題(2019-2023年,,2011-2015年,,合計(jì)714萬元) 重點(diǎn)部署0到1原始創(chuàng)新項(xiàng)目(2019-2023年,286萬元) 國際合作項(xiàng)目(2024-2025年,,2012-2014年,,合計(jì)100萬元) 7.地方科研任務(wù)(2021-2022年,2023-2024年,,合計(jì)220萬元) | ||
代表性論文 | ||
1) Zheng X, Han S, 2018. A generic method framework for accurately quantifying greenhouse gas footprints of crop cultivation systems. Atmospheric and Oceanic Science Letters 11(1), 15–28. 2) Zheng X, Wang R, 2017. Protocols for Chamber-based Manual Measurement of CH4 and N2O Fluxes from Terrestrial Ecosystems. [In Chinese.] Beijing: The Meteorological Press. pp. 101. 3) Wolf B, Zheng X, Brüggemann N, Chen W, Dannenmann M, Han X, Sutton MA, Wu H, Yao Z, Butterbach-Bahl K, 2010. Grazing-induced reduction of natural nitrous oxide release from continental steppe. Nature 464, 881-884. 4) Zheng X, Xie B, Liu C, Zhou Z, Yao Z, Wang Y H, Wang YL, Yang L, Zhu J, Huang Y, Butterbach-Bahl K, 2008. Quantifying net ecosystem carbon dioxide exchange of a short-plant cropland with intermittent chamber measurements. Global Biogeochemical Cycles 22, GB3031. 5) Zheng X, Zhou Z, Wang YS, Zhu J, Wang YL, Yue J, Shi Y Kobayashi K, Inubushi K, Huang Y, Han S, Xu Z, Xie B, Butterbach-Bahl K, Yang L, 2006. Nitrogen-regulated effects of free-air CO2 enrichment on methane emissions from paddy rice fields. Global Change Biology 12 (9), 1717-1732. 6) Zheng X, S Han, Y Huang, Wang Y, Wang M, 2004. Re-quantifying the emission factors based on field measurements and estimating the direct N2O emission from Chinese croplands. Global Biogeochemical Cycles 18(2), GB2018. 7) Zheng X, Huang Y, Wang Y, Wang M, 2003. Seasonal characteristics of nitric oxide emission from a typical Chinese rice-wheat rotation during the non-waterlogged period. Global Change Biology 9 (2), 219-227. 8) Zheng X, Huang Y, Wang Y, Wang M, Jin J, Li L, 2003. Effects of soil temperature on nitric oxide emission from a typical Chinese rice-wheat rotation during the non-waterlogged period. Global Change Biology 9(4): 601-611. 9) Zheng X, Fu C, Xu X, Yan X, Huang Y, Chen G, Han S, Hu F, 2002. The Asian nitrogen cycle case study. Ambio 31(2), 79-87. 10) Zheng X, Mei B, Wang YH, Xie B, Wang YS, Dong H, Xu H, Chen G, Cai Z, Yue J, Gu J, Su F, Zou J, Zhu J, 2008. Quantification of N2O fluxes from soil-plant systems may be biased by the applied gas chromatograph methodology. Plant and Soil 311, 211-314. 11) Zheng X, Liu C, Han S, 2008. Description and application of a model for simulating regional nitrogen cycling and calculating nitrogen flux. Advances in Atmospheric Sciences 25(2), 181-201. 12) Zheng X, Wang M, Wang Y, et al., 2000. Impacts of soil moisture on nitrous oxide emission from croplands: a case study on the rice-based agro-ecosystem in Southeast China. Chemosphere-Global Change Science 2, 207-224. 13) Chen W, Wolf B, Zheng X, Yao Z, Butterbach-Bahl K, Brüggemann N, Liu C, Han S, Han X, 2011. Annual methane uptake by temperate semiarid steppes as regulated by stocking rates, aboveground plant biomass and topsoil air permeability. Global Change Biology 17, 2803-2816. (Corresponding author) 14) Chen W, Wolf B, Yao Z, Brüggemann N, Butterbach-Bahl K, Liu C, Han S, Han X, Zheng X, 2010. Annual methane uptake by the typical semiarid steppe of Inner Mongolia, China. Journal of Geophysical Research 115, D15108 (Corresponding author) 15) Chen W, Wolf B, Brüggemann N, Butterbach-Bahl K, Zheng X, 2011. Annual emissions of greenhouse gases from sheepfolds in Inner Mongolia. Plant and Soil 340, 291-301 (Corresponding author) 16) Xu Z, Zheng X, Wang YS, Wang YL, Huang Y, Zhu J, 2006. Effect of free-air atmospheric CO2 enrichment on dark respiration of rice plants (Oryza sativa L.). Agriculture, Ecosystems & Environment 115, 105-112. (Corresponding author) 17) Xie B, Zheng X, Zhou Z, Gu J, Zhu B, Chen X, Shi Y, Wang YY, Zhao Z, Liu C, Yao Z, Zhu J, 2010. Effects of nitrogen fertilizer on CH4 emission from rice fields in China: multi-site field observations. Plant and Soil 326, 393–401 (Corresponding author) 18) Yao Z, Zheng X, Xie B, Mei B, Wang R, Butterbach-Bahl K, Zhu J, Yin R, 2009. Tillage and crop residue management significantly affects N-trace gas emissions during the non-rice season of a subtropical rice-wheat rotation. Soil Biology and Biochemistry 41, 2131-2140 (Corresponding author) 19) Yao Z, Zhou Z, Zheng X, Xie B, Liu C, Butterbach-Bahl K, and Zhu J, 2010. Effects of tillage during the non-waterlogged period on nitrous oxide and nitric oxide emissions in typical Chinese rice-wheat rotation ecosystems. Journal of Geophysical Research 115, G01013 (Corresponding author) 20) Yao Z, Wu X, Wolf B, Dannenmann M, Butterbach-Bahl K, Brüggemann N, Chen W, Zheng X, 2010. Soil-atmosphere exchange potential of NO and N2O in different land use types of Inner Mongolia, as affected by soil temperature, soil moisture, freeze-thaw and drying-wetting events. Journal of Geophysical Research 115, D17116 (Corresponding author) 21) Yao Z, Wolf B, Chen W, Butterbach-Bahl K, Brüggemann N, Wiesmeier M, Dannenmann M, Blank B, Zheng X, 2010. Spatial variability of N2O, CH4 and CO2 fluxes within the Xilin River catchment of Inner Mongolia, China-a soil core study. Plant and Soil 331, 341-359. (Corresponding author) 22) Yao Z, Zhou Z, Zheng X, Xie B, Mei B, Wang R, Butterbach-Bahl K, Zhu J, 2010. Effects of organic matter incorporation on nitrous oxide emissions from the rice-wheat rotation ecosystems in China. Plant and Soil 327, 315-330 (Corresponding author) 23) Liu C, Zheng X, Zhou Z, Han S, Wang Y, Wang K, Liang W, Li M, Chen D, Yang Z, 2010. Nitrous oxide and nitric oxide emissions from an irrigated cotton field in Northern China. Plant and Soil 332, 123-134. (Corresponding author) 24) Liu C, Meng S, Wang K, Zhou Z, Han S, Chen D, Yang Z, Zheng X, 2011. Effects of irrigation, fertilization and crop straw management on nitrous oxide and nitric oxide emissions from a wheat-maize rotation field in northern China. Agriculture, Ecosystems and Environment 140, 226-233. (Corresponding author) 25) Liu C, Holst J, Butterbach-Bahl K, Yao Z, Brüggemann N, Han X, Tas B, Susenbeth A, Han S, Zheng X, 2009. Growing season methane budget of a typical Inner Mongolian steppe. Atmospheric Environment 43, 3086-3095. (Corresponding author) 26) Liu C, Holst J, Yao Z, Brüggemann N, Butterbach-Bahl K, Han S, Han X, Zheng X, 2009. Sheepfolds as "hotspots" of nitric oxide (NO) emission in a semi-arid Inner Mongolian steppe. Agriculture, Ecosystems and Environment 134, 136-142. (Corresponding author) 27) Liu C, Holst J, Brüggemann N, Butterbach-Bahl K, Yao Z, Han S, Han X and Zheng X, 2008. Effects of irrigation on nitrous oxide, methane and carbon dioxide fluxes in an Inner Mongolian steppe. Advances in Atmospheric Sciences 25 (5): 748-756. (Corresponding author) 28) Liu C, Holst J, Brüggemann N, Butterbach-bahl K, Yao Z, Yue J, Han S, Han X, Krümmelbeind J, Hornd R, and Zheng X, 2007. Grazing reduces methane uptake by soils in a semi-arid steppe in Inner Mongolia, China. Atmospheric Environment 41, 5948-5958. (Corresponding author) 29) Zhou Z, Zheng X, Xie B, Liu C, Han S, Zhu J, 2010. Nitric oxide emissions from rice-wheat rotation fields in eastern China: effect of fertilization, soil water content, and crop residue. Plant and Soil 336, 87-98. (Corresponding author) 30) Zhou Z, Zheng X, Xie B, Han S, Liu C, 2010. A process-oriented model of N2O emission from rice-winter wheat rotation agro-ecosystem: structure, validation and sensitivity. Advances in Atmospheric Sciences 27, 137-150. (Corresponding author) 31) Mei B, Zheng X, Xie B, Dong H, Zhou Z, Wang R, Deng J, Cui F, Tong H, Zhu J, 2009. Nitric oxide emissions from conventional vegetable fields in southeastern China. Atmospheric Environment 43, 2762-2769 (Corresponding author) 31) Mei B, Zheng X, Xie B, Dong H, Yao Z, Liu C, Zhou Z, Wang R, Deng J, Zhu J, 2011. Characteristics of Multiple-Year Nitrous Oxide Emissions from Conventional Vegetable Fields in Southeastern China. Journal of Geophysical Research 116, D12113 (Corresponding author) 32) Gu J, Zheng X, Zhang W, 2009. Background nitrous oxide emissions from croplands in China in the year 2000. Plant and Soil 320, 307-320. (Corresponding author) 33) Gu J, Zheng X, Wang Y, Ding W, Zhu B, Chen X, Wang Y, Zhao Z, Shi Y, Zhu J, 2007. Regulatory effects of soil properties on background N2O emissions from agricultural soils in China. Plant and Soil 295, 53-65. (Corresponding author) 34) Cui F, Zheng X, Liu C, Wang K, Zhou Z, Deng J, 2014. Assessing biogeochemical effects and best management practice for a wheat-maize cropping system using the DNDC model. Biogeosciences 11, 91-107. (Corresponding author) 36) Yue J, Han S, Zheng X, 2012. Designing a regional nitrogen cycle module of grassland for the IAP-N model. Advances in Atmospheric Sciences 29, 320-332. (Corresponding author). 37) Cui F, Yan G, Zhou Z, Zheng X, Deng J, 2012. Annual emissions of nitrous oxide and nitric oxide from a wheat-maize cropping system on a silt loam calcareous soil in the North China Plain. Soil Biology & Biochemistry 48, 10-19. (Corresponding author) 38) Yao Z, Zheng X, Dong H, Xie B, Wang R, Mei B, Zhu J, 2012. A 3-year record of N2O and CH4 emissions from a sandy loam paddy during rice seasons as affected by different nitrogen application rates. Agriculture, Ecosystems and Environment 152, 1-9. (Corresponding author) 39) Liu C, Wang K, Zheng X, 2012. Responses of N2O and CH4 fluxes to fertilizer nitrogen addition rates in an irrigated wheat-maize cropping system in northern China. Biogeosciences 9, 839-850. (Corresponding author) 40) Deng J, Zhou Z, Zheng X, Liu C, Xie B, Yao Z, Cui F, Han S, Zhu J, 2012. Annual emissions of nitrous oxide and nitric oxide from rice-wheat rotation and vegetable fields: a case study in the Tai-Lake region, China. Plant and Soil 360, 37-53. (Corresponding author) 41) Xie B, Zhou Z, Mei B, Zheng X, Dong H, Wang R, Han S, Cui F, Wang Y, Zhu J, 2012. Influences of free-air CO2 enrichment (FACE), nitrogen fertilizer and crop residue incorporation on CH4 emissions from irrigated rice fields. Nutrient Cycling in Agricultural Ecosystems 93, 373–385. (Corresponding author) 42) Chen W, Wolf B, Zheng X, Yao Z, Butterbach-bahl K, Brüggemann N, Han S, Liu C, Han X, 2013. Carbon dioxide emission from temperate semiarid steppe during the non-growing season. Atmospheric Environment 64, 141-149. (Corresponding author) 43) Chen W, Zheng X, Chen Q, Wolf B, Butterbach-Bahl, K, Brüggemann N, Lin S, 2013. Effects of increasing precipitation and nitrogen deposition on CH4 and N2O fluxes and ecosystem respiration in a degraded steppe in Inner Mongolia, China. Geoderma 192, 335-340. (Corresponding author) 44) Wang K, Zheng X, Pihlatie M, Vesala T, Liu C, Haapanala S, Mammarella I, Rannik ü, Liu H, 2013. Comparison between static chamber and tunable diode laser-based eddy covariance techniques for measuring nitrous oxide fluxes from a cotton field. Agricultural and Forest Meteorology 171-172: 9-19. (Corresponding author) 45) Wang R, Feng Q, Liao T, Zheng X, Butterbach-Bahl K, Zhang W, Jin C, 2013. Effects of nitrate concentration on the denitrification potential of a calcic cambisol and its fractions of N2, N2O and NO. Plant and Soil 363, 175-189. (Corresponding author) 46) Liu C, Wang K, Zheng X, 2013. Effects of nitrification inhibitors (DCD and DMPP) on nitrous oxide emission, crop yield and nitrogen uptake in a wheat-maize cropping system. Biogeosciences 10, 2427–2437.(Corresponding author) 47) Yao Z, Zheng X, Wang R, Dong H, Xie B, Mei B, Zhou Z, Zhu J, 2013. Greenhouse gas fluxes and NO release from a Chinese subtropical rice-winter wheat rotation system under nitrogen fertilizer management. Journal of Geophysical Research-Biogeosciences 118, 623-638. (Corresponding author) 48) Wang K, Liu C, Zheng X, Pihlatie M, Li B, Haapanala S, Vesala T, Liu H, Wang Y, Liu G, Hu F, 2013. Comparison between eddy covariance and automatic chamber techniques for measuring net ecosystem exchange of carbon dioxide in cotton and wheat fields. Biogeosciences 10, 6865–6877. (Corresponding author) 49) Yan G, Zheng X, Cui F, Yao Z, Zhou Z, Deng J, Xu Y, 2013. Two-year simultaneous records of N2O and NO fluxes from a farmed cropland in the Northern China Plain with a reduced nitrogen addition rate by one-third. Agriculture, Ecosystems & Environment 178, 39–50. (Corresponding author) 50) Yao Z, Zheng X, Dong H, Xie B, Liu C, Wang R, Butterbach-Bahl K, Zhu J, 2013 Nitrous oxide and methane fluxes from a rice-wheat crop rotation under wheat residue incorporation and no tillage practices. Atmospheric Environment 79, 641-649. (Corresponding author) 51) Liao T, Wang R, Zheng X, Sun Y, Butterbach-Bahl K, Chen N, 2013. Automated online measurement of N2, N2O, NO, CO2, and CH4 emissions based on a gas-flow-soil-core technique. Chemosphere 93, 2848-2853. (Corresponding author) 52) Deng J, Zhou Z, Zheng X, Li C, 2013. Modeling impacts of fertilization alternatives on nitrous oxide and nitric oxide emissions from conventional vegetable fields in southeastern China. Atmospheric Environment 81, 642-650. (Corresponding author) 53) Cui F, Zheng X, Liu C, Wang K, Zhou Z, Deng J, 2014. Assessing biogeochemical effects and best management practice for a wheat-maize cropping system using the DNDC model. Biogeosciences 11, 91-107. (Corresponding author) 54) Zhang W, Gu J, Zheng X, 2015. Direct nitrous oxide emissions related to fertilizer-nitrogen, precipitation, and soil clay fraction: empirical models. Atmospheric and Oceanic Science Letters 8(5), 277-282. (Corresponding author) 55) Chen W, Zheng X, Wolf B, Yao Z, Liu CY, Butterbach-Bahl K, 2017. The potential of soil carbon dioxide, methane and nitrous oxide exchanges of differently grazed semiarid steppes: based on soil core experiment. Fresenius Environmental Bulletin 26, 2571-2581. (Corresponding author) 56) Zhang W, Li Y, Zhu B, Zheng X, Liu C, Tang J, Su F, Zhang C, Ju X, Deng J, 2018. CNMM-DNDC: a process-oriented hydro-biogeochemical model enabling simulation of the gaseous carbon and nitrogen emissions and hydrologic nitrogen losses from a subtropical catchment. Science of the Total Environment 616?617, 305-317. (Corresponding author) 57) Zhang H, Yao Z, Wang K, Zheng X, Ma L, Wang R, Liu C, Zhang W, Zhu B, Tang X, Hu Z, Han S, 2018. Annual N2O emissions from conventionally grazed typical alpine grass meadows in the eastern Qinghai-Tibetan Plateau. Science of the Total Environment 625, 885-899. (Corresponding author) 58) Li S, Zheng X, Liu C, Yao Z, Zhang W, Han S, 2018. The influences of observation method, season, soil depth, land use and management practice on soil dissolvable organic carbon concentrations: a meta-analysis. Science of the Total Environment 631-632, 105-114. (Corresponding author) 59) Lin F, Liu C, Hu X, Fu Y, Zheng X, Zhang W, Wang R, Cao G, 2018. Non-cropping period accounting for over a half of annual nitric oxide releases from cultivated calcareous-soil alpine ecosystems with marginally low emission factors. Atmospheric and Oceanic Science Letters 11(4), 338-344. (Corresponding author) 60) Chen W, Zheng X, Wolf B, Yao Z, Liu C, Butterbach-Bahl K, Brüggemann N, 2019. Long-term grazing effects on soil-atmosphere exchanges of CO2, CH4 and N2O at different grasslands in Inner Mongolia: a soil core study. Ecological Indicators 105, 316-328. (Corresponding author) 61) Lin F, Liu C, Hu X, Fu Y, Zheng X, Wang R, Zhang W, Cao G, 2019. Characterizing nitric oxide emissions from two typical alpine ecosystems. Journal of Environmental Sciences-China 77, 312-322. (Corresponding author) 62) Zhang H, Yao Z, Ma L, Zheng X, Wang R, Wang K, Liu C, Zhang W, Zhu B, Tang X, Hu Z, Han S, 2019. Annual methane emissions from degraded alpine wetlands in the eastern Tibetan Plateau. Science of the Total Environment 657, 1323-1333. (Corresponding author) 63) Dubache G, Li S, Zheng X, Zhang W, Deng J, 2019. Modeling ammonia volatilization following urea application to winter cereal fields in the United Kingdom by improving a biogeochemical model. Science of the Total Environment 660, 1403-1418. (Corresponding author) 64) Li S, Zheng X, Zhang W, Han S, Deng J, Wang K, Wang R, Yao Z, Liu C, 2019. Modeling ammonia volatilization following the application of synthetic fertilizers to cultivated uplands with calcareous soils using an improved DNDC biogeochemistry model. Science of the Total Environment 660, 931-946 (Corresponding author) 65) Zhang W, Liu C, Zheng X, Wang K, Cui F, Wang R, Li S, Yao Z, J Zhu, 2019. Using a modified DNDC biogeochemical model to optimize field management of a multi-crop (cotton, wheat, and maize) system: a site-scale case study in northern China. Biogeosciences 16, 2905-2922. (Corresponding author) 66) Wang K, Wang D, Zheng X, Nelson D, 2020. Applicability of a closed-path quantum cascade laser spectrometer for eddy covariance flux measurements of nitric oxide over a cropland during a low emission period. Agricultural and Forest Meteorology 282–283, 107855. | ||
授權(quán)發(fā)明專利 | ||
[1],、同步測量N2O、CH4和CO2通量的渦動(dòng)相關(guān)法裝置,,CN109031468B,,2020.04.10,第二發(fā)明人 [2],、箱式法物質(zhì)通量自動(dòng)觀測的系統(tǒng)及方法,,CN106770933B,2019.04.23,,第二發(fā)明人 [3],、一種同步測定土壤底物和氣體排放的裝置及方法, [4],、一種微量氣體自動(dòng)采集和分析系統(tǒng)及其方法,CN102053164B,,2013.05.22,,第五發(fā)明人 | ||
