科学研究水平与贡献
发布时间:2022-02-22
1、承担的主要科研项目
序号 | 项目名称 | 编号 | 负责人 | 起止时间 | 经费(万元) | 类别 |
1 | 作物高产高效群体与关键生态因子的匹配及其调控 | 2015CB1504 | 张福锁 | 2015-2019 | 1200 | 973项目 |
2 | 大气重污染成因与治理-农业排放及强化治理方案 | DQGG0208 | 刘学军 | 2017-2020 | 2754 | 总理基金 |
3 | 作物专用高效复混肥料研制与产业化 | 2016YFD0200401 | 江荣风 | 2016-2020 | 2500 | 科技部 |
4 | 农作物最佳养分管理技术研究与应用 | 201103003 | 张福锁 | 2011-2016 | 3152 | 科技部 |
5 | 集约化玉米体系磷与水分互作的根土界面效应及高效利用机理 | 31330070 | 申建波 | 2014-2018 | 288 | 国家自然科学基金重点项目 |
6 | 中国北方旱作农田土壤氧化亚氮产生过程及主要控制因素 | 41830751 | 巨晓棠 | 2019-2023 | 307 | 国家自然科学基金 |
7 | 土壤作物信息快速采集技术研究 | 2016YFD0200403-4 | 袁会敏 | 2016-2020 | 200 | 国家重点研发项目 |
8 | 主要生态区农作物体系氮肥绿色增产增效的综合调控途径 | 2017YFD0200108 | 范明生 | 2017-2021 | 315 | 国家重点研发项目 |
9 | 曲周潮土土壤肥力演变和培肥技术研究与示范 | 201203030-03-06 | 张宏彦 | 2012-2016 | 170 | 公益性行业专项 |
10 | 肥料磷在北方土壤中的迁移扩散规律 | 2017YFD0200201-4 | 袁会敏 | 2017-2020 | 90 | 国家重点研发项目 |
2、重要获奖清单
序号 | 获奖类型 | 成果名称 | 完成人 | 所获奖项 | 奖项级别 | 备注 |
1 | 农业推广 | “教科推”有机结合支撑小麦玉米快越是发展 | 李晓林等 | 河北省农业技术推广奖 | 一等奖 | 2014年 |
2 | 个人类 | 植物营养理论和技术创新与应用 | 张福锁 | 何梁何利奖 | 科学与技术成就奖 | 2017年 |
3 | 个人类 | 创造性的田间化肥管理实现了土壤改良、粮食增产 | 崔振岭 | 世界粮食奖 | 青年奖 | 2017年 |
4 | 个人类 | 科技小院精准扶贫 | 张福锁 | 全国脱贫攻坚奖 | 创新奖 | 2018年 |
5 | 教学类 | 依托“科技小院”培养农科应用型研究生的模式改革与实践 | 李晓林等 | 国家级教学成果 | 二等奖 | 2014年 |
6 | 部门奖 | 科技小院 | 张福锁等 | 三农创新榜样 | 第一名 | 2016年 |
7 | 教育部 | Producing more grain with lower environmental costs《Nature》2014年 | 张福锁、陈新平等 | 中国高校十大科技进展 | 中国高校十大科技进展 | 2014年 |
8 | 教育部 | Pursuing sustainable productivity with millions of smallholder farmers《Nature》2018年 | 张福锁、崔振岭等 | 中国高校十大科技进展 | 中国高校十大科技进展 | 2018年 |
注:选取有代表性的成果提交,数量不超过10项。
3、主要科研论文或著作清单
序号 | 名称 | 完成人 | 刊物、出版社或授权单位名称 | 年份,卷号(期号),页码 |
1 | Producing more grain with lower environmental costs | XP Chen, ZL Cui, MS Fan et al. | Nature | 2014, 514(23):486-489 |
2 | Closing yield gaps in China by empowering smallholder farmers | WF Zhang, GX Cao, XL Li,et al. | Nature | 2016, 537(7622):671 |
2 | Pursuing sustainable productivity with millions of smallholder farmers. | ZL Cui, HY Zhang, XP Chen,et al | Nature | 2018,555(7696) |
4 | Reduced nitrogen dominated nitrogen deposition in the US, but its contribution to nitrogen deposition in China decreased | XJ Liu, W Xu, EZ Du, et al. | PNAS | 2016,113 (26): E3590-E3591 |
5 | Enhanced-efficiency fertilizers are not a panacea for resolving the nitrogen problem | TY Li, WF Zhang, J Yin, et al. | Global Change Biology | 2017, 00:1–11 |
6 | Nitrous Oxide Emissions Increase Exponentially When Optimum Nitrogen Fertilizer Rates Are Exceeded in the North China Plain | XT Song, M Liu, XT Ju, et al. | Environmental Science & Technology | 2018 |
7 | Strengthening Agronomy Research for Food Security and Environmental Quality | ZL Cui, PM Vitousek, FS Zhang, et al. | Environmental Science & Technology | 2016, 50:1639-1641 |
8 | Evidence for a historic change occurring in China | XJ Liu, P Vitousek, Y H Chang, et al. | Environmental Science & Technology | 2016, 50(2): 505-506 |
9 | Life cycle assessment of wheat-maize rotation system emphasizing high crop yield and high resource use efficiency in Quzhou County | C Wang, XL Li, TT Gong, et al. | Journal of Cleaner Production | 2014, 68:56-63 |
10 | Chinese coastal seas are facing heavy atmospheric nitrogen deposition | XS Luo, AH Tang, K Shi, et al. | Environmental Research Letters | 2014,9: 095007 |
11 | Spatial–temporal patterns of inorganic nitrogen air concentrations and deposition in eastern China | W Xu, L Liu,MM Cheng, et al. | Atmos. Chem. Phys. | 2018, 18: 10931- 10954 |
12 | Role of a urease inhibitor Limus in decreasing ammonia volatilization and improving maize nitrogen utilization in North China Plain | QQ Li, XQ Cui,XJ Liu, et al. | Scientific Reports | 2017, 7: 43853 |
13 | Using maize hybrids and in-season nitrogen management to improve grain yield and grain nitrogen concentrations | Yan P , Yue S , Qiu M , et al. | Field Crops Research | 2014, 166:38-45. |
14 | Elucidating population establishment associated with N management and cultivars for wheat production in China | Lu D , Lu F , Yan P , et al. | Field Crops Research | 2014, 163:81-89 |
15 | The effects of cultivar and nitrogen management on wheat yield and nitrogen use efficiency in the North China Plain | Lu D , Lu F , Pan J , et al. | Field Crops Research | 2015, 171:157-164. |
16 | Integrated crop-N system management to establish high wheat yield population | Lu D , Yue S , Lu F , et al. | Field Crops Research | 2016:S0378429016300417. |
17 | Plant growth patterns in a tripartite strip relay intercrop are shaped by asymmetric aboveground competition | Huang C , Liu Q , Gou F , et al. | Field Crops Research | 2017, 201(Complete):41-51. |
18 | Optimised sowing date enhances crop resilience towards size-asymmetric competition and reduces the yield difference between intercropped and sole maize | CD Huang, QQ Liu, et al. | Field Crops Research | 2018, 217:125-133 |
19 | Promoting potassium allocation to stalk enhances stalk bending resistance of maize (Zea mays L.) | Z Xu, TZ Lai, et al. | Field Crops Research | 2018, 215:200-206 |
20 | Effect of a new urease inhibitor on ammonia volatilization and nitrogen utilization in wheat in north and northwest China | QQ Li AL Yang,ZH Wang, et al. | Field Crops Research | 2015,175: 96-105 |
21 | An effective strategy to improve grain zinc concentration of winter wheat, Aphids prevention and farmers’ income | XZ Wang, DY Liu, et al. | Field Crops Research | 2015, 184:74-79 |
22 | Zinc uptake and accumulation in winter wheat relative to changes in root morphology and mycorrhizal colonization following varying phosphorus application on calcareous soil | W Zhang, DY Liu, YM Liu, et al. | Field Crops Research | 2016, 197:74-82 |
23 | An effective strategy to improve grain zinc concentration of winter wheat, Aphids prevention and farmers’ income | XZ Wang, DY Liu, W Zhang, et al. | Field Crops Research | 2015, 184: 74-79 |
24 | Zinc accumulation and remobilization in winter wheat as affected by phosphorus application | W Zhang, DY Liu, C Li, et al. | Field Crops Research | 2015, 184:155-161 |
25 | The role of phosphorus supply in maximizing the leaf area, photosynthetic rate, coordinated to grain yield of summer maize | W Zhang, XX Chen, YM Liu et al. | Field Crops Research | 2018, 219:113-119 |
26 | Enhanced crown root number and length confers potential for yield improvement and fertilizer reduction in nitrogen-efficient maize cultivars | ZG Liu, Y Zhao, S Guo, et al. | Field Crops Research | 2019, 241 |
27 | Effects of nitrogen management on root morphology and zinc translocation from root to shoot of winter wheat in the field | YF Xue, W Zhang, DY Liu, et al. | Field Crops Research | 2014, 161: 38-45 |
28 | Estimated reactive nitrogen losses for intensive maize production in China | Wang G , Chen X , Cui Z , et al. | Agriculture, Ecosystems and Environment | 2014, 197:293-300 |
29 | Long-term optimization of crop yield while concurrently improving soil quality | Pan J , Zhang L , He X , et al. | Land Degradation & Development | 2019. |
30 | Agronomic approach of zinc biofortification can increase zinc bioavailability in wheat flour and thereby reduce zinc deficiency in humans | DY Liu, YM Liu, W Zhang, et al. | Nutrients | 2017. 9: 465. |
31 | Dynamic Zinc Accumulation and Concentrations of Pre- and/or Post- Silking Zinc Uptake to Grain Zinc of Maize as Affected by Nitrogen Supply | YF Xue, SC Yue, DY Liu, et al. | Front. Plant Sci. | 2019, 10:1203. |
32 | Atmospheric nitrogen emission, deposition and air quality impacts in China: An overview | XJ Liu, W XU, L Duan,et al. | Current Pollution Reports | 2017,3: 65-77 |
33 | Zinc uptake, translocation, and remobilization in winter wheat as affected by soil application of Zn fertilizer | DY Liu, YM Liu, W Zhang, et al. | Frontiers in Plant Science | 2019.10: 426. |
34 | Harvesting more grain zinc of wheat for human health | XP Chen, YQ Zhang, YP Tong, et al. | Scientific Reports | 2017, 7(1):7016 |
35 | The impact of alternative cropping systems on global warming potential, grain yield and groundwater use | B Gao, XT Ju, Q Meng, et al. | Agriculture, Ecosystems & Environment | 2015,203, 46-54 |
36 | Effects of Nitrogen on the Distribution and Chemical Speciation of Iron and Zinc in Pearling Fractions of Wheat Grain | YF Xue, T Eagling, JB He, et al. | J. Agric. Food Chem. | 2014, 62: 4738-4746 |
37 | Simultaneous Biofortification of Wheat with Zinc, Iodine, Selenium, and Iron through Foliar Treatment of a Micronutrient Cocktail in Six Countries | CQ Zou, YF Du, A Rashid, et al. | J. Agric. Food Chem. | 2019,67:8096-8106 |
38 | Overuse of phosphorus fertilizer reduces the grain and flour protein contents and zinc bioavailability of winter wheat (Triticum aestivum L.) | W Zhang, DY Liu, YM Liu et al. | Journal of Agricultural and Food Chemistry | 2017, 65(8):1473-1482 |
39 | Accumulation, partitioning, and bioavailability of micronutrients in summer maize as affected by phosphorus supply | W Zhang, DY Liu, C Li, et al. | European Journal of Agronomy | 2017, 86:48-59 |
40 | Zinc nutrition of wheat in response to application of phosphorus to a calcareous soil and an acid soil | XX Chen, W Zhang, Q Wang, et al. | Plant and Soil | 2019, 434: 139-150 |
41 | Zinc uptake by roots and accumulation in maize plants as affected by phosphorus application and arbuscular mycorrhizal colonization | W Zhang, XX Chen, YM Liu, et al. | Plant and Soil | 2017, 413(1):59-71 |
42 | Effects of zinc application rate and zinc distribution relative to root distribution on grain yield and grain Zn concentration in wheat. | DY Liu, W Zhang, LL Pang,et al. | Plant and Soil | 2017.411: 167-178 |
43 | Soil application of zinc fertilizer could achieve high yield and high grain zinc concentration in maize | DY Liu, W Zhang, P Yan,et al. | Plant and Soil | 2017.411: 47-55 |
44 | A high plant density reduces the ability of maize to use soil nitrogen | Yan P , Pan J , Zhang W , et al. | PLoS ONE | 2017, 12(2):e0172717 |
45 | Economic Performance and Sustainability of a Novel Intercropping System on the North China Plain | Huang C , Liu Q , Heerink N , et al. | PLoS ONE | 2015, 10(8):e0135518. |
46 | Economic Performance and Sustainability of a Novel Intercropping System on the North China Plain | CD Huang, QQ Liu, et al. | PLoS ONE | 2015, 10(8): e0135518 |
47 | Overuse of phosphorus fertilizer reduces the grain and flour protein and zinc bioavailability of winter wheat (Triticum aestivum L.) | W Zhang, DY Liu, YM Liu, et al. | J. Agr. Food. Chem. | 2017, 65:1473-1482 |
48 | Characteristics of ammonia, acid gases and PM2.5 for three typical land use types in the North China Plain | W Xu, QH Wu, XJ Liu,et al. | Environmental Science and Pollution Research | 2016,23: 1158-1172 |
49 | Zinc, Iron, Manganese and Copper Uptake Requirement in Response to Nitrogen Supply and the Increased Grain Yield of Summer Maize | YF Xue, SC Yue, W Zhang, et al. | PLoS ONE | 2014, 9(4): e93895 |
50 | High-Yield Maize Production in Relation to Potassium Uptake Requirements in China | Wu L , Cui Z , Chen X , et al | Agronomy Journal | 2014, 106(4):1153. |
51 | An Understanding of the Accumulation of Biomass and Nitrogen is Benefit for Chinese Maize Production | Yan P , Yue S , Meng Q , et al | Agronomy Journal | 2016, 108(2):895. |
52 | In-Season Nitrogen Management to Increase Grain Yields in Maize Production | Junxiao P , Qingfeng M , Riyuan C , et al. | Agronomy Journal | 2017, 109(5):2063- |
53 | Manure Limits Wheat Yield Losses Due to Delayed Seeding | DJ Lu, FF Lu, JX Pan, et al. | Agronomy Journal | 2015,107(6):2294 |
54 | Interaction between plant density and nitrogen management strategy in improving maize grain yield and nitrogen use efficiency on the North China Plain | Yan P , Zhang Q , Shuai X F , et al. | The Journal of Agricultural Science | 2016, 154(06):978-988. |
55 | Interaction between plant density and nitrogen management strategy in improving maize grain yield and nitrogen use efficiency on the North China Plain | Yan P , Zhang Q , Shuai X F , et al. | The Journal of Agricultural Science | 2016, 154(06):978-988. |
56 | Nutritional Composition of Iron, Zinc, Calcium, and Phosphorus in Wheat Grain Milling Fractions as Affected by Fertilizer Nitrogen Supply | YF Xue, W Zhang, DY Liu, et al. | Cereal Chem. | 2016, 93(6):543–549 |
57 | Effect of intercropping on maize grain yield and yield components | CD Huang, QQ Liu, et al. | Journal of Integrative Agriculture | 2019, 18(8): 1690–1700 |
58 | 华北平原不同生产模式设施蔬菜生命周期环境影响评价 | 徐强,胡克林,李季等 | 环境科学 | 2018,39(05):2480-2488 |
59 | 华北地区有机种植和常规种植模式下土壤重金属含量及污染评价 | 姜瑢, 吕贻忠,申思雨 | 中国生态农业学报 | 2015, 23(7):877-885 |
60 | 长期肥料施用对华北大田玉米土壤丛枝菌根真菌群落结构的影响 | 刘玮, 姜姗姗, 张运龙等 | 菌物学报 | 2017, 36(7), 914-932 |
61 | 华北平原长期施肥和耕作对土壤氨挥发的影响 | 李凡,李江叶,郝晋珉等 | 土壤通报 | 2018,49(06):1405-1414 |
62 | 蚯蚓与菌根提高玉米生长和氮磷吸收的互补效应 | 李欢, 王冲, 汪顺义等 | 植物营养与肥料学报 | 2015, 21(4):920-926 |
63 | 追氮方式对夏玉米土壤N2O和NH3排放的影响 | 刘敏, 张翀, 何彦芳等. | 植物营养与肥料学报 | 2016(1):19-29 |
64 | 基于无人机可见光遥感的夏玉米氮素营养动态诊断参数研究 | 张玲, 陈新平, 贾良良 | 植物营养与肥料学报 | 2018, 24:261-269 |
65 | 河北省曲周县农田生态系统碳循环及碳效率研究 | 尹钰莹,郝晋珉,牛灵安等 | 资源科学 | 2016,38(5):918-928 |
66 | 不同施氮水平对冬小麦群体性状及产量的影响 | 魏素君, 刘全清, 张宏彦等 | 河北农业科学 | 2014(2):32-35 |
67 | 夏玉米生长后期主要病虫害发生及其原因分析 | 张晓宁等 | 现代农业科技 | 2014 |
68 | 华北平原小农户冬小麦春灌时间与产量关系初探——以曲周县为例 | 田英豪, 张宏彦, 陈广锋等 | 现代农村科技 | 2017(10):74-75. |
69 | 冬小麦倒伏的影响因素 ——基于曲周县农户调查和试验数据分析 | 章余, 张宏彦, 陈广锋等 | 河北农业科学 | 2017(6). |
70 | 中国间套作的时空变化及在现代农业中优化途径分析 | 李海朋等 | 中国农业大学 | 2016 |
71 | 春草秋治对麦田杂草的防治效果 | 胡芙蓉, 彭学可, 赵鹏飞等 | 河北农业科学 | 2014, 18(6):62-64. |
72 | 华北平原小农户经营模式下冬小麦高产高效技术示范效果评价初报——以河北省曲周县“三八”科技小院为例 | 胡芙蓉, 赵鹏飞, 刘全清等 | 现代农村科技 | 2015(19). |
73 | 技术培训对农民追肥行为的影响 | 田净, 曹国鑫, 刘全清, 等 | 河北农业科学 | 2014(2):83-85 |
74 | “三八”科技小院针对我国农村妇女的创新农业技术推广之路 | 田净, 刘全清, 张宏彦 | 河北农业科学 | 2015(2):95-98. |
75 | 农村规模化非农产业兴衰对农用土地流转的影响——以轮胎翻新专业村曲周县席庄村为例 | 刘晴, 王欢, 章余等 | 现代农业科技 | 2016(18):294-294. |
76 | 冬小麦配方肥和宽幅播种技术综合应用效果评估 | 程亮, 卢殿君, 崔振岭等 | 中国农技推广 | 2015, 31(9). |
77 | 小麦高产与养分高效利用协同实现的技术途径 | 赵伟丽等 | 河北农业科学 | 2015 |
78 | 灌溉条件下覆膜对冬小麦根系分布及抗倒性状的影响 | 蔡永强, 牛新胜, 焦小强等 | 华北农学报 | 2014(S1):328-332. |
79 | 华北平原小农户冬小麦春灌时间与产量关系初探——以曲周县为例 | 田英豪, 张宏彦, 陈广锋等 | 现代农村科技 | 2017(10):74-75. |
80 | 农化服务信息化的现状及问题探讨 | 李增源, 刘家欢, 徐洋等 | 中国农业信息 | 2018, 30(04):68-80. |
81 | 养分优化管理促进间作小麦高产群体的构建 | 张艺, 黄成东, 廖丹等 | 中国农学通报 | 2018, v.34;No.484(13):7-13. |
82 | 盐渍化区域土壤系统培肥研究 | 牛灵安 | 中国农业大学出版社 | 2018.9 978-7-5655-2101-0) |
83 | 中国农业大学有机农业丛书:有机蔬菜生产技术指南 | 杨合法,李季 | 中国农业大学出版社 | 2018 |
84 | 高产高效养分管理技术创新与应用 | 张福锁,张朝春 | 中国农业大学出版社 | 2017 |
85 | 作物绿色增产增效 | 张福锁,张宏彦 | 中国农业大学出版社 | 2016 |
86 | 中国三大粮食作物区域大配方与施肥建议 | 陈新平,吴良泉,张福锁 | 中国农业出版社 | 2016 |
87 | 一种农田灌排两用装置 | 牛灵安;吕振宇;周震;郝晋珉;王绍雷 | 中华人民共和国国家知识产权局 | CN201820098420.1 |
88 | 一种畜禽粪污中磷素高效回收的调控方法 | 张涛;江荣风;方慈;李平 | 中华人民共和国国家知识产权局 | ZL 2014 1 0009174.4 |