1988年，北京农业大学硕士研究生毕业；

1994年，北京农业大学博士研究生毕业；

1988-今，中国农业大学任教。

1.本科生课程：主讲《作物栽培学》；参讲《现代作物生产原理与技术》

2.硕土研究生课程：主讲《高级作物生理学》；参讲《现代作物生产科学与技术》、《作物栽培与耕作研究技术》

3.博士研究生课程：主讲《作物光合、产量与品质生理专题》；参讲《作物科学进展》

1.小麦栽培理论与技术；

2.作物生态生理；

3.农田节水技术

1.主持农业公益性行业专项项目：“北方主要作物抗旱节水综合技术研究与区域示范”(2009-2013)

2.国家小麦产业技术体系岗位专项----干旱区栽培(2007-2015)

3.参加“973”项目：“主要作物高产栽培与资源高效利用基础研究”(2008-2013)

　　主持和参加完成“973”、“863”、国家支撑计划课题、公益性行业专项课题、国家自然科学基金项目、北京市自然科学基金项目、河北省科技成果转化基金项目、市校合作项目等多项。

近年主要论文著作：

1. Modelling to increase the eco-efficiency of a wheat-maize double cropping system.Agriculture, Ecosystems and Environment.2015, 210:36-46

2. A reappraisal of the critical nitrogen concentration of wheat and its implications on crop modeling. Field Crops Research. 2014, 164:66-73

3. Accuracy of root modelling and its impact on simulated wheat yield and carbon cycling in soil. Field Crops Research. 2014, 165:99-110

4. Remobilization of water soluble carbohydrates in non-leaf organs and contribution to grain yield in winter wheat under reduced irrigation. International Journal of Plant Production. 2013, 7(1): 97-

5. Is grain zinc concentration in wheat limited by source? Australian Journal of Crop Science. 2014, 8(11): 1534-1541

6. iTRAQ-based quantitative proteome and phosphoprotein characterization reveals the central metabolism changes involved in wheat grain development. BMC Genomics. 2014, 15:1029

7. Effect of source-sink manipulation on photosynthetic characteristics of flag Leaf and the remobilization of dry Mass and nitrogen in vegetative organs of wheat. Journal of Integrative Agriculture, 2014, 13(8): 1680-1690

8. Grain yield and water use efficiency in extremely-late sown winter wheat cultivars under two irrigation regimes in the North China Plain. PLoS ONE, 2016, 11(4): e0153695. doi:10.1371/journal.pone.015369

9. Characteristics of canopy structure and contributions of non-leaf organs to yield in winter wheat under different irrigated conditions. Field Crops Research,2011，123(1)：187-195

10. Phosphoenolpyruvate carboxylase activity in ear organs is related to protein concentration in grains of winter wheat. Journal of Cereal Science, 2008,47 (1)：386-391

11. Recovery of Residual Fertilizer-Nitrogen by Wheat in a Winter Wheat–Summer Maize Rotation in the North China Plain: A Soil Column Study. Agronomy Journal, 2009,101:925-932

12. The nitrate leached below maize root zone is available for deep-rooted wheat in winter wheat-summer maize rotation in the North China Plain. Environmental Pollution, 2008,152 (2)：723-730

13. Roles of carbohydrate supply and ethylene polyamines in maize kernel set. Journal of Integrative Plant Biology, 2011, 53 (5)：388-398

14. Characteristics of water consumption in water-saving winter wheat and effects on the utilization of subsequent summer rainfall in the North China Plain. International Journal of Plant Production, 2011，5(2)：167-180

15. Photosynthetic characteristics of non-leaf organs of winter wheat cultivars differing in ear type and their relationship with grain weight per ear. Photosynthetica，2001，39（2）：239-244

16. Effect of heat stress during grain filling on photosynthetic Characteristics of different green organs in winter wheat. Acta Bot Sin, 2001, (5)：571-577

17. Effect of soil drought on C4 photosynthesis enzyme activities of flag leaf and ear in wheat. Scientia Agricultura Sinica. 2003,2(4): 413-417

18. Effect of heat stress on activities of Phosphoenolpyruvate Carboxylase and Ribulose-1, 5-bisphosphate Carboxylase in different green organs of winter wheat during grain filling. Photosynthetica,2004，42(2):317-320

19. Performance of temperate aerobic rice under different water-regimes in North China. Agricultural Water Management 2005,74:107-122

20. Performance of aerobic rice varieties under irrigated conditions in North China. Field Crops Research, 2006,97:53-65

21. Effects of sucrose and ammonium nitrate on phosphoenolpyruvate carboxylase and ribulose-1,5-bisphosphate carboxylase activities in wheat ears. Australian Journal of Crop Science. 2012，6(5):822-

22. Effect of source-sink manipulation on accumulation of micronutrients and protein in wheat grains. Journal of Plant Nutrition and Soil Science. 2012,175(4)：1-8

23. 华北地区冬小麦-夏玉米种植体系土壤硝态氮的残留与再利用研究I.夏玉米生育期土壤硝态氮的动态与残留积累.生态学报2005，25(7)：1620-1625

24. 华北地区冬小麦-夏玉米种植体系土壤硝态氮的残留与再利用研究II.节水栽培冬小麦对下层土壤残留氮素的利用.生态学报2005，25(8)：1869-1873

25. 不同供水条件下冬小麦叶与非叶绿色器官光合日变化特征.生态学报，2011，31(5)：1312-1322

26. 限水灌溉冬小麦冠层氮分布与转运特征及其对供氮的响应. 生态学报，2011，31(17)：4941-4950

27. 春灌模式对晚播冬小麦水分利用及产量形成的影响.生态学报，2009.29(4):2035-2043

28. 不同水分条件对冬小麦根系时空分布、土壤水利用和产量的影响.生态学报，2010.30(19):5296-5305

29. 不同供水条件下小麦不同绿色器官的气孔特性研究.作物学报2006，32(1)：70-75

30. 冬小麦节水栽培三种灌溉模式的水氮利用与产量形成.作物学报,2009,35(11)：2045-2054

31. 不同水分供给对小麦叶与非叶器官叶绿体结构和功能的影响. 作物学报, 2008.34(7)：1213-1219

32. 春玉米叶面积系数动态特征的密度效应.作物学报,2009,35(6):1097  

33. 源库调节对小麦不同品种籽粒微量元素及蛋白质含量的影响.作物学报, 2008.34(9)：1629-1636

34. 基于控制授粉技术的玉米籽粒建成与碳_氮供应关系.作物学报，2011,37(8)：1415-1422

35. 基于控制授粉技术的玉米籽粒生育特性与建成机制.作物学报，2011,37(9):1605-1615

36. 土壤干旱对小麦绿色器官光合电子传递和光合磷酸化活力的影响.作物学报2004，30(5)：26.487-490

37. 小麦不同绿色器官光合速率与碳同化酶活性及其基因型差异研究.作物学报2007，33(9)：1426-1431

38. 野生一粒麦与普通栽培小麦不同绿色器官光合特性与叶绿体结构特征. 作物学报，2002.28(3)：351-354

39. 开花后水分胁迫对小麦不同器官C4光合酶活性的影响.中国农业科学，2003，36（5）：508-512

40. 冬小麦节水高产栽培群体光合特征.中国农业科学，2003. 36(10)：1143-1149

41. 15_N标记和土柱模拟的夏玉米氮肥利用特性研究. 中国农业科学，2011,44(12)：2446-2453

42. 论作物生产系统产量分析理论模式及其发展.中国农业大学学报, 2009.14(1)：1-7

43. 窄行匀播对晚播冬小麦群体环境、个体性状和物质生产的影响. 生态学报, 2015, 35(16): 1-14

44. 有限供水下冬小麦全程耗水特征定量研究. 生态学报, 2014, 34(10): 2567-2580

45. 灌浆期高温对小麦旗叶与非叶器官光合和抗氧化酶活性的影响. 作物学报, 2015, 41(1): 136-144

46. 冬小麦节水栽培群体穗叶比及其与产量和水分利用的关系. 生态学报, 2013, 33(12): 3657-3667

47. 夏玉米不同施氮水平土壤硝态氮累积及对后茬冬小麦的影响. 中国农业科学, 2013, 46(6): 1182-1190