柴强教授简介
一、个人简介
柴强,男,1972年生,博士、教授,作物栽培学与耕作学专业博士生导师,国家中青年科技创新领军人才,国家现代农业绿肥产业技术体系岗位科学家,甘肃省“领军人才”、“555”科技创新人才,甘肃省“飞天学者”特聘教授。现为中国农学会耕作制度研究会副理事长,中国农业资源与区划学会常务理事,中国植物营养与肥料学会绿肥专业委员会副主任委员,中国农学会立体农业委员会、甘肃省生态学会常务理事,甘肃省农学会、甘肃省作物学会常务理事。甘肃省“首届杰出青年基金”“高校青年教师成才奖”、“中国农学会耕作制度分会首届优秀青年人才奖”、“省委组织部创新青年人才扶持计划”获得者。第十三届全国政协委员、农业和农村委员会委员,甘肃农业大学党委副书记、校长,省部共建干旱生境作物学国家重点实验室常务副主任,甘肃农业大学第十届学术委员会副主任委员。
主要从事多熟种植、节水农业、循环农业、旱地绿肥栽培理论与技术研究。主持完成和国家科技支撑计划、国家自然基金、国家公益性行业计划和省杰出青年基金等各类科研课题20余项。获“甘肃省科技进步奖”6项、地厅级科技进步奖4项,获得国家实用新型专利10项、发明专利3项、软件著作ag凯发k8国际的版权1项,合作研制地方技术标准11项,主编和参编专著14部,在pnas、“nature communications” “advances in agronomy” “journal of cleaner production” “agronomy for sustainable development” “field crops research” “中国农业科学”“作物学报”等国内外学术期刊和国际、国内学术会议发表论文300余篇。
甘肃农业大学作物栽培学与耕作学系列课程省级教学团队负责人。主要为农学本科专业讲授农业生态学课程,曾讲授本科生农作学、农学概论、农业项目投资与评估等课程,主讲作物栽培学与耕作学专业硕士生、博士生高级农作学、宏观农业和植物化学生态学课程;主编、副主编出版教材各1部,参编教材2部;获省级教学成果二等奖1项、精品课程1门。
二、受教育经历
2004/09-2008/06,兰州大学, 旱农生态学, 博士后。导师:李凤民 教授
2000/09-2003/06,甘肃农业大学,作物栽培学与耕作学,博士生。导师:黄高宝 教授
1995/09-1998/06,甘肃农业大学,作物栽培学与耕作学,硕士生。导师:胡恒觉 教授
1991/09-1995/06,甘肃农业大学,农学,本科生。
三、科研与学术工作经历
2008/11 - 至今, 甘肃农业大学农学院,教 授
2003/10-2008/10,甘肃农业大学农学院,副教授
2001/09-2003/09,甘肃农业大学农学院,讲 师
1998/09-2001/09,甘肃农业大学农学系,讲 师
四、主持科研项目(课题)及人才计划项目情况
1. 间作响应密植的地上部生理生态机制研究(31771738).国家自然科学基金.2018.01-2021.12.
2.国家绿肥产业技术体系--旱地绿肥栽培岗位(cars-22-g-12).国家现代农业产业技术体系.2017.01-2020.12.
3.适宜机械化间作模式的节水潜力及机理研究.2017.01-2020.12.
4.河西走廊区玉米小麦水肥高效利用农艺模式集成和技术示范(201503125-3).国家公益性行业(农业)科研专项课题.2015.01-2019.12.
5.黄土高原丘陵沟壑区玉米抗旱增产增效技术集成与示范.黄土高原丘陵沟壑区粮食稳产增效技术集成示范(2015bad22b04-03)国家科技支撑计划子课题.2015.01-2019.12.
6. 间作水分高效利用的种间竞争互补机理(31360323).国家自然科学基金.2014.01-2017.12.
7.间作提高水分利用效率的种间竞争与互补机制(fxrc20130101).甘肃农业大学伏羲杰出人才培育计划.2013-2017.
8.西北绿洲农牧循环技术集成与示范(2012bad14b10).国家科技支撑计划课题.2012.01- 2016.12.
9.西北地区水土资源高效利用农作制模式及配套技术研究与示范(201103001).国家公益性行业(农业)科研专项.2011.01-2015.12.
10. 禾豆间作消减豆科作物氮阻遏的作用机制(31160265).国家自然科学基金.2012.01-2015.12.
11.间作套种提高水分利用效率的种间作用机理(111rjda006).甘肃省杰出青年基金.2012.01-2014.12.
12.间套复合群体水分竞争互补的根间作用机理(30771264).国家自然科学基金.2008.01-2010.12.
13.西北内陆灌区农田循环生产技术集成研究与示范(2007bad89b17).国家科技支撑计划课题.2008.01-2010.12.
14.间套复合群体水分竞争互补的根间作用机理(30771264).国家自然科学基金.2008.01- 2010.12.
15.绿洲节水高效种植模式研究.国家科技支撑计划子课题.2007.01-2010.12.
五、代表性研究成果和学术奖励情况
1. 获奖情况
(1) 西北地区水土资源高效利用农作制模式集成研究与推广. 国家农牧渔业丰收奖一等奖,2019
(2) 西北绿洲农牧循环技术集成与示范.甘肃省科技进步二等奖,2018
(3) 禾豆间作消减豆科作物氮阻遏的作用机制.甘肃省教育厅二等奖,2017
(4) 间作套种提高水分利用效率的种间作用机理.甘肃省教育厅二等奖,2016
(5) 西北绿洲农田循环生产关键技术研究与集成示范.甘肃省科技进步二等奖,2012
(6) 提高兰州市农业综合生产能力的途径及对策研究.甘肃省农牧渔业丰收奖三等奖,2007
(7) 绿洲灌区粮田超吨田水肥高效利用理论与技术研究.甘肃省农牧渔业丰收奖二等奖,2007
(8) 北方干旱内陆河灌区(甘肃张掖)节水高效农业技术体系与示范.甘肃省科技进步二等奖,2006
(9) 集约多熟制农田水肥耦合机理研究.甘肃省自然科学三等奖,2006
(10) 甘肃灌溉农业发展方略研究.甘肃省科技进步三等奖,2003
(11) 甘肃一熟灌区作物持续高产高效技术体系研究与示范.甘肃省科技进步三等奖,2003
(12) 调亏灌溉条件下多作系统的根水肥时空协调机理研究.甘肃省教育厅二等奖,2003
(13) 粮田超高产种植模式及增产机理研究.甘肃省科技进步三等奖,2000
2. 代表性sci论文
[1] wen yin, qiang chai*, yao guo, zhilong fan, falong hu, hong fan, cai zhao, aizhong yu. straw and plastic management regulate air-soil temperature amplitude and wetting-drying alternation in soil to promote intercrop productivity in arid regions[j]. field crops research, 2020, 250: 107758.
[2] cai zhao, zhilong fan, jeffrey a. coulter, wen yin, falong hu, aizhong yu, hong fan, qiang chai. high maize density alleviates the inhibitory effect of soil nitrogen on intercropped pea[j]. agronomy basel, 2020, 10: 248.
[3] yao guo, wen yin, zhilong fan, falong hu, hong fan, cai zhao, aizhong yu, qiang chai*, jeffrey a. coulter. no-tillage with reduced water and nitrogen supply improves water use efficiency of wheat in arid regions[j]. agronomy journal, 2019, 112: 578-591.
[4] wen yin, aizhong yu, yao guo, hong fan, falong hu, zhilong fan, cai zhao, qiang chai*. growth trajectories of wheat/maize intercropping with straw and plastic management in arid conditions[j]. agronomy journal, 2020, 112: 912-925.
[5] zhilong fan, qiang chai*, aizhong yu, cai zhao, wen yin, falong hu, guodong chen, weidong cao, jeffrey a. coulter. water and radiation use in maize–pea intercropping is enhanced with increased plant density[j]. agronomy journal, 2020, 112: 257-273.
[6] yan tan, falong hu, qiang chai*, guang li, jeffrey a. coulter, cai zhao, aizhong yu, zhilong fan, wen yin. expanding row ratio with lowered nitrogen fertilization improves system productivity of maize/pea strip intercropping[j]. european journal of agronomy, 2020, 113: 125986.
[7] meixiu tan, fang gou, tjeerd jan stomph, jing wang, wen yin, lizhen zhang, qiang chai, wopke van der werf. dynamic process-based modelling of crop growth and competitive water extraction in relay strip intercropping: model development and application to wheat-maize intercropping[j]. field crops research, 2020, 246: 107613.
[8] emmanuel asibi aziiba, qiang chai*, jeffrey a. coulter.mechanisms of nitrogen use in maize[j]. agronomy basel, 2019, 9: 775.
[9]aziiba emmanuel asibi, qiang chai*, jeffrey a. coulter.rice blast: a disease with implications for global food security[j]. agronomy basel, 2019, 9: 451.
[10] cai zhao, qiang chai⁎, weidong cao, joann k. whalen, liangxia zhao, lijuan cai. no-tillage reduces competition and enhances compensatory growth of maize intercropped with pea. field crops research, 2019, 243: 107611.
[11] wen yin, zhilong fan, falong hu, aizhong yu, cai zhao, qiang chai*, jefrey a. coulter.innovation in alternate mulch with straw and plastic management bolsters yield and water use efficiency in wheat-maize intercropping in arid conditions. scientific reports, 2019, 9: 6364.
[12] yao guo, wen yin, falong hu, zhilong fan, hong fan, cai zhao, aizhong yu, qiang chai⁎, jeffrey a. coulter.reduced irrigation and nitrogen coupled with no-tillage and plastic mulching increase wheat yield in maize-wheat rotation in an arid region. field crops research, 2019, 243: 107615.
[13] wen yin, zhilong fan, falong hu, hong fan, aizhong yu, cai zhao, qiang chai⁎. straw and plastic mulching enhances crop productivity via optimizing interspecific interactions of wheat–maize intercropping in arid areas. crop science, 2019, 59: 2201-2213.
[14] zhilong fan, yanhua zhao, qiang chai⁎, cai zhao, aizhong yu, jeffrey a. coulter, yantai gan, weidong cao. synchrony of nitrogen supply and crop demand are driven via high maize density in maize/pea strip intercropping. scientific reports, 2019, 9: 10954.
[15] yanhua zhao, zhilong fan, falong hu, wen yin, cai zhao, aizhong yu, qiang chai*. source-to-sink translocation of carbon and nitrogen is regulated by fertilization and plant population in maize-pea intercropping. frontiers in plant science, 2019, 10: 891.
[16] caihong yang, zhilong fan, qiang chai*agronomic and economic benefits of pea/maize
intercropping systems in relation to n fertilizer and maize density. agronomy basel, 2018, 8: 52.
[17] falong hu, yan tan, aizhong yu, cai zhao, jeffrey a. coulter, zhilong fan, wen yin, hong fan, qiang chai*. low n fertilizer application and intercropping increases n concentration in pea (pisum sativum l.) grains[j]. frontiers in plant science, 2018, 9: 1763.
[18] wen yin, aizhong yu, yao guo, yifan wang, cai zhao, zhilong fan, falong hu, qiang chai*. straw retention and plastic mulching enhance water use via synergistic regulation of water competition and compensation in wheat-maize intercropping systems[j]. field crops research, 2018, 299: 78-94.
[19] wen yin, yao guo, falong hu, zhilong fan, fuxue feng, cai zhao, aizhong yu, qiang chai*. wheat-maize intercropping with reduced tillage and straw retention: a step towards enhancing economic and environmental benefits in arid areas[j]. frontiers in plant science, 2018, 9:1328.
[20]jinpu wu, kai xiao, cai zhao, aizhong yu, fuxue feng, long li, qiang chai*.ridge-furrow cropping of maize reduces soil carbon emissions and enhances carbon use efficiency[j].agriculture, ecosystems and environment, 2018, 256: 153-162.
[21] guodong chen, xuefu kong, yantai gan, renzhi zhang, fuxue feng, aizhong yu, cai zhao, sumei wan, qiang chai*. enhancing the systems productivity and water use efficiency through coordinated soil water sharing and compensation in strip-intercropping[j]. scientific reports, 2018, s41598.
[22] yifan wang, yazhou qin, qiang chai*, fuxue feng, cai zhao, aizhong yu. interspecies interactions in relation to root distribution across the rooting profile in wheat-maize intercropping under different plant densities[j]. frontiers in plant science, 2018, 483.
[23] wen yin, qiang chai*, yao guo, fuxue feng, cai zhao, aizhong yu, chang liu, zhilong fan, falong hu, guodong chen.reducing carbon emissions and enhancing crop productivity through strip intercropping with improved agricultural practices in an arid area[j]. journal of cleaner production, 2017, 166: 197-208.
[24] wen yin, cai zhao, qiang chai*, yao guo, fuxue feng, aizhong yu. effects of previous wheat straw on the yield of maize in the oasis irrigation region [j]. crop science, 2017, 57: 3217-3226.
[25] wen yin, guiping chen, fuxue feng, yao guo, falong hu, guodong chen, cai zhao, aizhong yu, qiang chai*. straw retention combined with plastic mulching improves compensation of intercropped maize in arid environment [j]. field crops research, 2017, 204: 42-51.
[26]fang gou, wen yin, yu hong, wopke van der werf, qiang chai, nico heerink, martink.vanittersum.on yield gaps and yield gains in intercropping: opportunities for increasing grain production in northwest china[j]. agricultural systems, 2017, 151: 96-105.
[27]falong hu, fuxue feng, cai zhao, qiang chai*, aizhong yu, wen yin, yantai gan.integration of wheat-maize intercropping with conservation practices reduces co2 emissions and enhances water use in dry areas[j]. soil & tillage research, 2017, 169: 44-53.
[28]falong hu, cai zhao, fuxue feng, qiang chai*, yanping mu, yan zhang.improving n management through intercropping alleviates the inhibitory effect of mineral n on nodulation in pea[j]. plant and soil, 2017, 412: 235-251.
[29] chang liu, herb cutforth, qiang chai*, yantai gan.farming tactics to reduce the carbon footprint of crop cultivation in semiarid areas. a review[j]. agronomy for sustainable development, 2016 ,36: 69-85.
[30] qiang chai*, yantai gan, cai zhao, huilian xu, reagan m waskom, yining niu, kadambot h m siddique. regulated deficit irrigation for crop production under drought stress. a review[j]. agronomy for sustainable development, 2016 ,36: 2-21.
[31] falong hu, yantai gan, qiang chai*, fuxue feng, cai zhao, aizhong yu, yanping mu, yan zhang. boosting system productivity through the improved coordination of interspecific competition in maize/pea strip intercropping[j]. field crops research, 2016, 198: 50-60.
[32]falong hu, yantai gan, aizhong yu, hongyan cui, cai zhao, fuxue feng, wen yin, qiang chai*. intercropping maize and wheat with conservation agriculture principles improves water harvesting and reduces carbon emissions in dry areas[j]. european journal of agronomy, 2016, 74: 9-17.
[33] wen yin, fuxue feng, cai zhao, aizhong yu, falong hu, qiang chai*, yantai gan. integrated double- mulching practices optimizes soil temperature and improves soil water utilization in arid environments[j]. international journal of biometeorology, 2016, 60: 1423-1437.
[34] wen yin, qiang chai*, yao guo, fuxue feng, cai zhao, aizhong yu, falong hu. analysis of leaf area index dynamic and grain yield components of intercropped wheat and maize under straw mulch combined with reduced tillage in arid environments[j]. journal of agricultural science, 2016, 8(4): 26-42.
[35] cai zhao, qiang chai*, yanhua zhao, yanping mu, yan zhang, aizhong yu, fuxue feng, chang liu, wen yin, falong hu. interspecific competition and complementation is a function of n management in maize-pea intercropping systems[j]. crop science, 2016, 56:3286-3294.
[36]falong hu, qiang chai*, wen yin, aizhong yu, hongyan cui, yantai gan. less carbon emissions of wheat–maize intercropping under reduced tillage in arid areas[j]. agronomy for sustainable development, 2015, 35: 701-711.
[37] wen yin, aizhong yu, qiang chai*, falong hu, fuxue feng, yantai gan. wheat and maize relay-planting with straw covering increases water use efficiency up to 46%[j]. agronomy for sustainable development, 2015, 35: 815-825.
[38] caihong yang, qiang chai*, guang li, fuxue feng, li wang. water use efficiency of controlled alternate irrigation on wheat/faba bean intercropping[j]. african journal of agricultural research, 2015, 10(48): 4348-4355.
[39]guodong chen, qiang chai*, gaobao huang, aizhong yu, fuxue feng, yanpin mu, xuefu kong, peng huang. belowground interspecies interaction enhances productivity and water use efficiency in maize/pea intercropping systems[j]. crop science, 2015, 55: 420-428.
[40] yumei jiang, shunyu han, shenggui zhang, jixin li, gaobao huang, yang bi, qiang chai*. improved properties by hydrogen bonding interaction of poly(lactic acid)/palygorskite nanocomposites for agricultural products packaging[j]. polymer composites, 2014, 35(3): 468-476.
[41] yantai gan, chang liang, qiang chai*, reynald l lemke, con a. campbell, robert p zentner. improving farming practices reduce the carbon footprint of spring wheat production[j]. nature communications, 2014, 12: 1-11.
[42] hongwei chen, anzhen qin, qiang chai*, yantai gan, zhandong liu. quantification of soil water competition and compensation using soil water differences between strips of intercropping[j]. agriculture research, 2014, 3(4): 321-330.
[43]qiang chai*, yantai gan, neil c. turner, renzhi zhang, chao yang, yining niu, kadambot h.m. siddique. water-saving innovations in chinese agriculture[j]. advances in agronomy, 2014, 126: 149-202.
[44]qiang chai*, anzhen qin, yantai gan*, aizhong yu. higher yield and lower carbon emission by intercropping maize with rape, pea, and wheat in arid irrigation areas[j]. agronomy for sustainable development, 2014, 34: 106-117
[45]yamei wang, qiang chai*, hengjia zhang. effect of water deficit at tuber initiation on potato (solanum tuberosum) tuber yield and efficiency of water use[j]. advanced materials research, 2013, 864-867: 2061-2064.
[46]yanpin mu, qiang chai*, aizhong yu, caihong yang, wanhai qi, fuxue feng, xuefu kong. performance of wheat/maize intercropping is a function of belowground interspecies interactions[j]. crop science, 2013, 53(5): 2186-2194.
[47] jian ma, gaobao huang, delong yang, qiang chai*. dry matter remobilization and compensatory effects in various internodes of spring wheat under water stress[j]. crop science, 2013, 53(6): 2221-2299.
[48] zhilong fan, qiang chai*, gaobao huang aizhong yu, peng huang, caihong yang, zhiqiang tao, hailiang liu. yield and water consumption characteristics of wheat/maize intercropping with reduced tillage in an oasis region[j]. european journal of agronomy, 2013, 45: 52-58.
[49] shoubao liu, qiang chai*, gaobao huang. relationships among soil respiration, soil temperature and dry matter accumulation for wheat-maize intercropping systems in an arid environment[j]. canadian journal of plant science, 2013, 93(4): 715-724.
[50] anzhen qin, gaobao huang, qiang chai*, aizhong yu, peng huang. grain yield and soil respiratory response to intercropping systems on aridland[j]. field crops research, 2013, 144: 1-10.
[51] yantai gan, kadambot h m siddique, neil c turner, xiaogang li, junyi niu*, chao yang, liping liu, qiang chai*. ridge-furrow mulching systems-an innovative technique for boosting crop productivity in semiarid rain-fed environments[j]. advances in agronomy, 2013, 125: 429-476.
[52] gaobao huang, qiang chai*, fuxue feng. effects of different tillage systems on soil properties, root growth, grain yield, and water use efficiency of winter wheat (triticum aestivum l.) in arid northwest china[j]. journal of integrative agriculture, 2012, 11(8): 1286-1296.
[53] caihong yang, gaobao huang, qiang chai*, zhaoxia luo. water use and yield of wheat/ maize intercropping under alternate irrigation in the oasis field of northwest china[j]. field crops research, 2011, 124: 426-432.
[54] fuxue feng, gaobao huang, aizhong yu, qiang chai. tillage and straw management impacts on soil properties, root growth and grain yield of winter wheat in northwestern china[j]. crop science, 2010, 50(4):1465-1473
[55] caihong yang, qiang chai, gaobao huang. root distribution and yield responses of wheat/maize intercropping to alternate irrigation in the arid areas of northwest china[j]. plant soil and environment, 2010, 56(6): 253-262.
3.代表性专著和教材
(1) 张宗舟,柴强,赵紫平,编著.《生物质资源再利用》.北京:清华大学出版社.2016.03. isbn978-7-302 -42879-4
(2) 杨彩红,柴强,编著.《交替灌溉间作节水理论与实践》.北京:中国农业出版社.2016.01. isbn978-7-109-21126-1
(3) 李军主编,王龙昌,柴强副主编.《农作学》北京:科学出版社.2016.03. isbn978-7-03-046634-1
(4) 晋小军主编,李崇霄,吕文军,柴强副主编.《尾菜利用技术与研究》. 北京:中国农业出版社, 2015.05. isbn 978-7-109-20415-5
(5) 李国学主编,柴强参编.《中国循环农业理论与实践研究进展》.北京:中国农业大学出版社.2014.12 isbn 978-7-5655-1141-7
(6) chai qiang, vice editor. systems research helping to meet the needs and managing the trade-offs of a changing world. proceedings of the4th international symposium for farming systems design. gansu science and technology press, august 19-22, 2013, lanzhou, china. isbn 978-7-5424-0961-1
(7) 黄高宝、柴强主编《作物生产类实验实习指导》.北京:化学工业出版社,20120901. isbn:978-7-1221-4309-9
(8) 高旺盛主编,张海林,隋鹏,柴强,副主编.《中国保护性耕作制》.北京:中国农业出版社,20110301.isbn: 978-7-5655-0258-3
(9) 陈阜主编,柴强参编.《农业生态学》.北京:中国农业出版社,20110801.isnb: 978-7-5655-0338-2
(10) 陈阜主编,柴强参编.《中国农作制发展优先序研究》.北京:中国农业大学出版社,20101001,isbn: 978-7-1091-5140-6
4.指导研究生及学位论文
序号
姓名
论文题目
毕业时间
备注
1
罗照霞
绿洲灌区交替灌溉小麦间作玉米的水分利用特征及其影响因素
2008
硕士
2
刘海亮
绿洲灌区小麦//玉米田间水分的蒸散特性及主要影响因素
2009
3
齐万海
绿洲灌区小麦间作玉米的耗水特性及其与根系时空分布的关系
4
张 辉
不同供水条件下小麦间作蚕豆复合群体对化感物质的响应
硕士二导
5
赵光毅
外源水杨酸、一氧化氮对盐胁迫下油葵叶片膜脂抗过氧化能力的影响
6
陶志强
少耕留茬覆盖小麦间作玉米的水分利用特征及其主要影响因素
2010
7
史中欣
绿洲灌区玉米//豌豆的肥水利用效率对带型和施氮量的响应机制
8
杨彩红
交替灌溉对间作群体水分利用特征的影响及其机理
博士二导
9
代 晋
供水和种间互作对玉米豌豆根系特性和水分利用的影响
2011
11
魏震泽
少耕覆盖小麦间作玉米土壤co2排放特征研究
2012
12
朱 静
玉米密度对间作豌豆“氮阻遏”的调控效应及机制
13
冯 海
中西部地区农户玉米生产技术需求优先序研究
14
刘惠娟
施氮对玉米间作豌豆农田温室气体排放的影响及机制
15
周海燕
施氮量及带型对玉米/豌豆氮肥利用特征的影响
16
牟彦萍
不同供氮水平下间作玉米对豌豆氮阻遏的调控效应及机理
2013
17
石多琴
水氮互作对全膜覆盖玉米的水分传输特征的影响
18
胡合生
覆盖及播量对玉米间作花葵水分利用效益的影响
19
吴玉鼎
玉米植株碳累积和耗水量的相关性研究
20
于爱忠
供水与地膜覆盖对玉米农田土壤水热特征及水分利用效率的影响
博士
21
秦安振
绿洲典型间作模式的土壤呼吸特征及其成因
22
马 剑
小麦非结构性碳水化合物(nsc)转运对灌浆期干旱胁迫的响应
23
刘守宝
绿洲典型多熟种植系统土壤水分的互补利用机制
24
孔学夫
根间作用与间作群体水分利用的关系
25
武进普
不同覆膜及灌溉条件下玉米农田的碳足迹量算
2014
26
张 妍
玉米∥豌豆氮素竞争补偿利用对施氮制度的响应
27
李文娟
水氮运筹下玉米花后非结构性碳水化合物运转研究
28
王建康
间距对玉米间作豌豆氮素竞争互补的调控效应研究
29
张 平
张掖市高效生态农业可持续发展模式与机制研究
30
王雅梅
小麦非结构性碳水化合物累积分配和光合生理对水分胁迫的响应
31
何春雨
冬小麦辉县红高感条锈病后源流库变化动态及其基础光合生理特性研究
32
赵 财
一膜两年覆盖农田土壤水热特性及水分利用效率研究
2015
33
谢军红
旱作粮饲兼用玉米产量和饲用品质的补灌效应
34
陈红卫
玉米大豆间作氮素补偿利用的密度调控机理研究
35
樊志龙
密度调控玉米间作豌豆氮素利用效率的cn平衡机理
36
陈国栋
小麦间作玉米水分竞争互补利用的生态位分离机制
37
秦亚洲
根冠互作对小麦间作玉米水分利用效率的影响
38
史倩倩
少耕秸秆覆盖对小麦间作玉米农田土壤碳排放的协同作用
39
肖 凯
覆膜与灌溉对玉米水分生理生态特性的协同效应
40
乔寅英
间距对玉米间作豌豆受光结构和氮肥利用率的影响
41
杨晓燕
水分胁迫对三种药用植物耗水规律的影响
2016
专硕
42
陈新文
秸秆还田方式和施n水平对春小麦复种油菜群体结构和经济效益影响
43
赵 洋
玉米间作豌豆密植增效关键影响因子排序
44
赵良霞
一膜二年覆盖玉米间作豌豆水分利用特征研究
45
郑德阳
绿洲灌区地膜秸秆二元覆盖玉米农田的水热效应
46
王彦武
民勤绿洲荒漠过渡带固沙林土壤保育效应研究
2017
47
王利立
施氮量及密度对大麦间作豌豆氮素利用的调控机理
48
殷 文
秸秆地膜交替带状覆盖小麦间作玉米的水分竞争互补利用机制
49
胡发龙
氮肥后移与禾/豆间作对土壤温室气体减排的协同效应
50
滕园园
免耕密植玉米间作豌豆农田生态系统碳平衡特征研究
51
王巧梅
地膜玉米茬免耕轮作小麦的节水减排效应研究
52
魏廷邦
水氮耦合滴灌玉米密植的主要生理生态基础
53
谈 燕
玉米间作豌豆生理生态特征对免耕密植的响应机制
54
蔡丽娟
一膜二年覆盖玉米间作豌豆水分高效利用的驱动机制
55
王一帆
地上地下互作提高小麦间作玉米水分利用效率的机理研究
2018
56
郭 瑶
地膜玉米田免耕轮作小麦的水氮运筹效应研究
57
张乃旭
免耕及灌水量对玉米间作豌豆水分竞争互补的调控效应
58
任旭灵
免耕密植对玉米间作豌豆农田碳足迹的影响
59
张喜军
水氮运筹滴灌玉米密植的光合生理生态基础
2019
60
杜进勇
小麦间作玉米耐密的光合生理生态机制
61
程 晖
绿洲灌区适宜麦后复种绿肥模式筛选及其施氮制度研究
62
田雪梅
地膜玉米免耕轮作小麦的水氮高效管理模式筛选
63
马 蕾
豌豆干物质和氮累积对水分胁迫和接种根瘤菌的生理响应
联系电话:0931-7631104
email: chaiq@gsau.edu.cn
通讯地址:甘肃省兰州市安宁区营门村1号甘肃农业大学农学院,邮编:730070
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