主持和参加的科研项目：

[1]   “西风-季风协同作用变化对碳氮循环机制的影响”，科考项目 (2019QZKK0106)，2019-2024，子专题负责人

[2]   “中国东北样带典型物种干旱生理调节与弹性”，国家自然科学基金国际合作项目 (31661143028)，2017-2019，课题负责人

[3]   “全球变化背景下玉米干旱发生发展过程及其致灾临界气象条件研究”，国家自然科学基金重点项目 (41330531)，2014-2018，课题负责人

[4]   “我国北方草原关键种对水分变化的适应过程与机制”，国家自然科学基金面上项目 (31170456)，2012-2015，项目负责人

[5]   “北方草原典型植物对土壤水分的脆弱性和阈值及其机制”，国家自然科学基金面上项目 (30470338)，2005-2007，项目负责人

[6]   “我国温带草地碳循环模型与减排增汇适应对策研究”， 国家自然科学基金重点项目(90711001)，2008-2011，课题负责人

[7]   “中国东北样带典型生态系统碳循环的过程与机理”，国家自然科学基金重点项目 (40231018)，2003-2006，课题负责人

[8]   “全球变化影响下我国主要陆地生态系统的脆弱性及适应性研究”课题“全球变化影响下自然生态系统的脆弱性及评价指标”，国家重大研究计划 (2010CB951301)，2010-2014，专题负责人

[9]   “我国主要陆地生态系统对全球变化响应与反馈的样带研究”，院知识创新工程重要方向项目(KSCX2-SW-133)，2005-2009，课题负责人

2024

1.      Liu L, Sun K, Sun RJ, Ma QH, Wang YH, Jia BR, Zhou GS, Xu ZZ,* Zhang, F*. 2024. Effects of nitrogen deposition with phosphorus addition on desert steppe plant communities. Agriculture, Ecosystems & Environment, 366: 108954. https://doi.org/10.1016/j.agee.2024.108954.

2.      Wu WJ, Sun RJ, Zhao G, Zheng ZT, He YL, Liu LR, Zhou GS, Zhang YJ, Xu ZZ. 2024. Climate shifts biomass allocation by altering plant functional group in alpine vs. temperate grasslands on both Inner Mongolian and Tibetan plateaus. CATENA, 238: 107887. https://doi.org/10.1016/j.catena.2024.107887.

2023

1.      Zhang F, Wu WJ, Li L, Liu XD, Zhou GS, Xu ZZ. 2023. Predicting community traits along an alpine grassland transect using field imaging spectroscopy. Journal of Integrative Plant Biology, 65(12): 2604-2618.

2.      Yu HY, Li L, Ma QH, Liu XD, Li YB, Wang YH, Zhou GS, Xu ZZ. 2023. Soil microbial responses to large changes in precipitation with nitrogen deposition in an arid ecosystem. Ecology 104(5): e4020. https://doi.org/10.1002/ecy.4020.

3.      Sun HR, Bond-Lamberty B, Hu TY, Li J, Jian JS, Xu ZZ, Jia BR. 2023. Forest soil carbon efflux evaluation across China: A new estimate with machine learning. Global Biogeochemical Cycles 37(8): e2023GB007761. https://doi.org/10.1029/2023GB007761.

4.      Sun K, Sun RJ, Li YB, Ji HC, Jia B, Xu ZZ. 2023. Plant economic strategies in two contrasting forests. BMC Plant Biology 23:366. https://doi.org/10.1186/s12870-023-04375-9.

5.      Ji HC, Yang G, Lv XM, Jia BR, Xu ZZ, Wang YH. 2023. Climate extremes drive the phenology of a dominant species in meadow steppe under gradual warming. Science of The Total Environment 19:161687. https://doi.org/10.1016/j.scitotenv.2023.161687.

6.      Wu WJ, Sun RJ, Liu LR, Liu XD, Yu HY, Ma QH, Qi M, Li L, Li YB, Zhou GS, Xu ZZ. 2023. Precipitation consistently promotes, but temperature inversely drives, biomass production in temperate vs. alpine grasslands. Agricultural and Forest Meteorology 329:109277. https://doi.org/10.1016/j.agrformet.2022.109277.

2022

1.      Yu HY, Chen YT, Zhou GS, Xu ZZ. 2022. Coordination of leaf functional traits under climatic warming in an arid ecosystem. BMC Plant Biology 22:439. https://doi.org/10.1186/s12870-022-03818-z.

2.      Yu HY, Liu XD, Ma QH, Li L, Wu WJ, Qi M, Li YB, Zhang F, Wang YH, Zhou GS, Xu ZZ. 2022. Nitrogen deposition drives response and recovery in the context of precipitation change and its reversal in an arid ecosystem. Journal of Geophysical Research: Biogeosciences 127(9): e2022JG006828. https://doi.org/10.1029/2022JG006828.

3.      Ma QH, Li YB, Zhu Y, Liu XD, Yu HY, Li L, Qi M, Sun HR, Yin ZT, Wang YG, Zhang F, Zhou GS, Xu ZZ. 2022. Precipitation variations, rather than N deposition, determine plant ecophysiological traits in a desert steppe in Northern China. Ecological Indicators 141:109144. https://doi.org/10.1016/j.ecolind.2022.109144.

4.      Sun HR, Xu ZZ, Jia BR. 2022. A compiled soil respiration dataset at different time scales for forest ecosystems across China from 2000 to 2018. Earth System Science Data 14:2951–2961, https://doi.org/10.5194/essd-14-2951-2022.

5.      Wu WJ, Zhou GS, Xu ZZ. 2022. Driving mechanisms of climate-plant-soil patterns on the structure and function of different grasslands along environmental gradients in Tibetan and Inner Mongolian Plateaus in China. Journal of Cleaner Production 339:130696. https://doi.org/10.1016/j.jclepro.2022.130696.

2021

1.      Liu XD, Ma QH, Yu HY, Li YB, Li L, Qi Miao, Wu WJ, Zhang F, Wang YH, Zhou GS, Xu ZZ. 2021. Climate warming-induced drought constrains vegetation productivity by weakening the temporal stability of the plant community in an arid grassland ecosystem. Agricultural and Forest Meteorology 307:108526. https://doi.org/10.1016/j.agrformet.2021.108526.

2.      Qi M, Liu XD, Li YB, Song H, Yin ZT, Zhang F, He QJ, Xu ZZ*, Zhou GS*. 2021. Photosynthetic resistance and resilience under drought, flooding and rewatering in maize plants. Photosynthesis Research 148(1-2):1–15.

3.      Xu ZZ*, Zhou GS*, He QJ. 2021. Vertical distribution of gas exchanges and their integration throughout the entire canopy in a maize field. Photosynthesis Research 147(3):269–281.

4.      Yu HY, Ma QH, Liu XD, Li YB, Li L, Qi Miao, Wu WJ, Wang YH, Xu ZZ, Zhou GS, Zhang F. 2021. Resistance, recovery, and resilience of desert steppe to precipitation alterations with nitrogen deposition. Journal of Cleaner Production 317:128434. https://doi.org/10.1016/j.jclepro.2021.128434.

5.      Jia BR*, Sun HR, Shugart HH, Xu ZZ, Zhang P, Zhou GS*. 2021. Growth variations of Dahurian larch plantations across northeast China: Understanding the effects of temperature and precipitation. Journal of Environmental Management 292:112739.

6.      Yu HY, Liu XD, Ma QH, Yin ZT, Wang YH, Xu ZZ, Zhou GS. 2021. Climatic warming enhances soil respiration resilience in an arid ecosystem. Science of The Total Environment 756:144005. https://doi.org/10.1016/j.scitotenv.2020.144005.

2020

1.      Liu XD, Ma QH, Yu HY, Li YB, Zhou L, He QJ, Xu ZZ*, Zhou GS*. 2020. Responses of plant biomass and yield component in rice, wheat, and maize to climatic warming—a meta-analysis. Planta 252(5):90. doi:10.1007/s00425-020-03495-y.

2.      Ma QH, Liu XD, Li YB, Li L, Yu HY, Qi M, Zhou GS*, Xu ZZ*. 2020. Nitrogen deposition magnifies the sensitivity of desert steppe plant communities to large changes in precipitation. Journal of Ecology 108(2):598–610.

3.      Yu HY, Xu ZZ*, Zhou GS*, Shi YH. 2020. Soil carbon release responses to long-term versus short-term climatic warming in an arid ecosystem. Biogeosciences 17(3):781–792.

4.      Sun H, Zhou G, Xu Z, Wang Y, Liu X, Yu H, Ma Q, Jia, B. 2020. Temperature sensitivity increases with decreasing soil carbon quality in forest ecosystems across northeast China. Climatic Change 160:373–384.

5.      Zhang F, Nilsson C, Xu Z, Zhou G. 2020. Evaluation of restoration approaches on the Inner Mongolian Steppe based on criteria of the Society for Ecological Restoration. Land Degradation & Development 31(3):285–296.

2019

1.      Wang H, Zhou G, Jiang Y, Shi Y, Xu Z. 2019. Effects of elevated CO₂ on Stipa baicalensis photosynthesis depend on precipitation and growth phase. Ecological Research 34(6):790-801.

2.      Li YB, Song H, Zhou L, Xu ZZ*, Zhou GS*. 2019. Vertical distributions of chlorophyll and nitrogen and their associations with photosynthesis under drought and rewatering regimes in a maize field. Agricultural and Forest Meteorology 272–273:40–54.

3.      Li YB, Song H, Zhou L, Xu ZZ*, Zhou GS*. 2019. Tracking chlorophyll fluorescence as an indicator of drought and rewatering across the entire leaf lifespan in a maize field. Agricultural Water Management 211:190–201.

2018

1.      Ma QH, Yu HY, Liu XD, Xu ZZ, Zhou GS, Shi YH. 2018. Climatic warming shifts the soil nematode community in a desert steppe. Climatic Change 150:243–258.

2.      Yu HY, Ma QH, Liu XD, Xu ZZ, Zhou GS, Shi YH. 2018. Short- and long-term warming alters soil microbial community and relates to soil traits. Applied Soil Ecology 131:22–28.

3.      Song H, Li YB, Zhou L, Xu ZZ, Zhou GS. 2018. Maize leaf functional responses to drought episode and rewatering. Agricultural and Forest Meteorology 249:57–70.

4.      Xu ZZ, Zhou GS, Han GX, Li YJ. 2018. The relationship between leaf and ecosystem CO₂ exchanges in a maize field. Acta Physiologiae Plantarum 40:156. doi:10.1007/s11738-018-2732-6.

5.      Shi YH, Zhou GS, Jiang YL, Wang H, Xu ZZ. 2018. Sensitive indicators of Stipa bungeana response to precipitation under ambient and elevated CO₂ concentration. International Journal of Biometeorology 62:141–151.

6.      Jia BR, Xu ZZ, Zhou GS, Yin XJ. 2018. Statistical characteristics of forest litterfall in China. Science China Life Sciences 61:358–360.

2017

1.      Wang H, Zhou GS, Jiang YL, Shi YH, Xu ZZ. 2017. Photosynthetic acclimation and leaf traits in Stipa bungeana in response to elevated CO₂ under five different watering conditions. Photosynthetica 55 (1):164–175.

2016及以前

1.      Xu ZZ, Jiang YL, Zhou GS. 2016. Nitrogen cycles in terrestrial ecosystems: climate change impacts and mitigation. Environmental Reviews 24:132–143.

2.      Jiang YL, Xu ZZ, Zhou GS, Liu T. 2016. Elevated CO₂ can modify the response to a water status gradient in a steppe grass: from cell organelles to photosynthetic capacity to plant growth. BMC Plant Biology 16:157. doi: 10.1186/s12870-016-0846-9.

3.      Xu ZZ, Jiang YL, Jia BR, Zhou GS. 2016. Elevated-CO₂ response of stomata and its dependence on environmental factors. Frontiers in Plant Science 7:657. doi: 10.3389/fpls.2016.00657.

4.      Xu ZZ, Hou YH, Zhang LH, Liu T, Zhou GS. 2016. Ecosystem responses to warming and watering in typical and desert steppes. Scientific Reports 6:34801. doi:10.1038/srep34801.

5.      Jia BR, Zhou GS Xu ZZ. 2016. Forest litterfall and its composition: a new data set of observational data from China. Ecology 97(5):1365. doi:10.1890/15-1604.1

6.      Shi YH, Zhou GS, Jiang YL, Wang H, Xu ZZ. 2016. Does precipitation mediate the effects of elevated CO₂ on plant growth in the grass species Stipa grandis? Environmental and Experimental Botany 131: 146–154.

7.      Liu T, Xu ZZ*, Hou YH, Zhou GS*. 2016. Effects of warming and changing precipitation rates on soil respiration over two years in a desert steppe of northern China. Plant and Soil 400:15–27.

8.      Song XL, Zhou GS, Xu ZZ, Lv XM, Wang YH. 2016. A self-photoprotection mechanism helps Stipa baicalensis adapt to future climate change. Scientific Reports 6:25839. doi:10.1038/srep25839.

9.      Song XL, Zhou GS, Xu ZZ, Lv XM, Wang YH. 2016. Detection of photosynthetic performance of Stipa bungeana seedlings under climatic change using chlorophyll fluorescence imaging. Frontiers in Plant Science 6:1254. doi: 10.3389/fpls.2015.01254.

10.   Xu ZZ, Jiang YL, Zhou GS. 2015. Response and adaptation of photosynthesis, respiration, and antioxidant systems to elevated CO₂ with environmental stress in plants. Frontiers in Plant Science 6:701. doi:10.3389/fpls.2015.00701.

11.   Shi YH, Zhou GS, Jiang YL, Wang H, Xu ZZ, Song J. 2015. Interactive effects of elevated CO₂ and precipitation change on leaf nitrogen of dominant Stipa L. species. Ecology and Evolution 5:2956–2965.

12.   Xu ZZ, Shimizu H, Ito S, Yagasaki Y, Zou CJ, Zhou GS, Zheng YR. 2014. Effects of elevated CO₂, warming and precipitation change on plant growth, photosynthesis and peroxidation in dominant species from North China grassland. Planta 239:421–435.

13.   Duan W, Yu Z, Zhang Y, Wang D, Shi Y, Xu Z. 2014. Effects of nitrogen application on biomass accumulation, remobilization, and soil water contents in a rainfed wheat field. Turkish Journal of Field Crops 19(1): 25–34.

14.   Zhang Q, Yang L, Xu Z, Zhang Y, Luo H, Wang J, Zhang W. 2014. Effects of cotton field management practices on soil CO₂ emission and C balance in an arid region of Northwest China. Journal of Arid Land 6(4):468–477.

15.   Xu ZZ, Shimizu H, Yagasaki Y, Ito S, Zheng YR, Zhou GS. 2013. Interactive effects of elevated CO₂, drought, and warming on plants. Journal of Plant Growth Regulation 32:692–707.

16.   Xu ZZ, Yu ZW, Zhao JY. 2013. Theory and application for the promotion of wheat production in china: past, present and future. Journal of the Science of Food and Agriculture 93:2339–2350.

17.   Hou YH, Zhou GS, Xu ZZ, Liu T, Zhang XS. 2013. Interactive effects of warming and increased precipitation on community structure and composition in an annual forb dominated desert steppe. PloS One 8(7), e70114.

18.   Xu ZZ, Zhou GS. 2011. Responses of photosynthetic capacity to soil moisture gradient in perennial rhizome grass and perennial bunchgrass. BMC Plant Biology 11:21, doi:10.1186/1471-2229-11-21.

19.   Xu ZZ, Zhou GS, Han GX, Li YJ. 2011. Photosynthetic potential and its association with lipid peroxidation in response to high temperature at different leaf ages in maize. Journal of Plant Growth Regulation 30:41–50.

20.   Wang D, Xu ZZ, Zhao JY, Wang YF, Yu ZW. 2011. Excessive nitrogen application decreases grain yield and increases nitrogen loss in a wheat–soil system. Acta Agriculturae Scandinavica, Section B - Soil & Plant Science 61:681–692.

21.   Xu ZZ, Zhou GS, Shimizu H. 2010. Plant responses to drought and rewatering. Plant Signaling & Behavior 5:649-654.

22.   Xu ZZ, Zhou GS, Shimizu H. 2009. Are plant growth and photosynthesis limited by pre-drought following rewatering in grass? Journal of Experimental Botany 60:3737–3749.

23.   Xu ZZ, Zhou GS, Shimizu H. 2009. Effects of soil drought with nocturnal warming on leaf stomatal traits and mesophyll cell ultrastructure of a perennial grass. Crop Science 49:1843–1851.

24.   Li YJ, Zhou L, Xu ZZ, Zhou GS. 2009. Comparison of water vapour, heat and energy exchanges over agricultural and wetland ecosystems. Hydrological Processes 23:2069–2080.

25.   Xu ZZ, Zhou GS. 2008. Responses of leaf stomatal density to water status and its relationship with photosynthesis in a grass. Journal of Experimental Botany 59:3317–3325.

26.   Xu ZZ, Zhou GS, Wang YL, Han GX, Li YJ. 2008. Changes in chlorophyll fluorescence in maize plants with imposed rapid dehydration at different leaf ages. Journal of Plant Growth Regulation 27:83–92.

27.   Han GX, Zhou GS, Xu ZZ, Yang Y, Liu JL, Shi KQ. 2007. Biotic and abiotic factors controlling the spatial and temporal variation of soil respiration in an agricultural ecosystem. Soil Biology & Biochemistry 39:418–425.

28.   Xu ZZ, Zhou GS, Wang YH. 2007. Combined effects of elevated CO₂ and soil drought on carbon and nitrogen allocation of the desert shrub Caragana intermedia. Plant and Soil 301:87–97.

29.   Xu ZZ, Zhou GS. 2007. Photosynthetic recovery of a perennial grass Leymus chinensis after different periods of soil drought. Plant Production Science 10:277–285.

30.   Han GX, Zhou GS, Xu ZZ, Yang Y, Liu JL, Shi KQ. 2007. Soil temperature and biotic factors drive the seasonal variation of soil respiration in a maize (Zea mays L.) agricultural ecosystem. Plant and Soil 291:15–26.

31.   Xu ZZ, Zhou GS. 2006. Combined effects of water stress and high temperature on photosynthesis, nitrogen metabolism and lipid peroxidation of a perennial grass Leymus chinensis. Planta 224:1080–1090.

32.   Xu ZZ, Zhou GS. 2006. Nitrogen metabolism and photosynthesis in Leymus chinensis in response to long-term soil drought. Journal of Plant Growth Regulation 25:252–266.

33.   Xu ZZ, Yu ZW, Wang D. 2006. Nitrogen translocation in wheat plants under soil water deficit. Plant and Soil 280:291–303.

34.   Xu ZZ, Yu ZW. 2006. Nitrogen metabolism in flag leaf and grain of wheat in response to irrigation regimes. Journal of Plant Nutrition and Soil Science 169:118–126.

35.   Xu ZZ, Zhou GS. 2005. Effects of water stress and nocturnal temperature on carbon allocation in the perennial grass, Leymus chinensis. Physiologia Plantarum 123:272–280.

36.   Xu ZZ, Zhou GS. 2005. Effects of water stress and high nocturnal temperature on   photosynthesis and nitrogen level of a perennial grass Leymus chinensis. Plant and Soil 269:131–139.

37.   Xu ZZ, Zhou GS. 2005. Effects of soil moisture on gas exchange, partitioning of fed ¹⁴CO₂ and stable carbon isotope composition (δ¹³C) of Leymus chinensis under two different diurnal temperature variations. Journal of Agronomy and Crop Science 191:27–34.

38.   Xu ZZ, Zhou GS. 2005. Effects of water stress on photosynthesis and nitrogen metabolism in vegetative and reproductive shoots of Leymus chinensis. Photosynthetica 43:29–35.

39.   Xu ZZ, Yu ZW. 2005. Nitrogen accumulation and translocation for winter wheat under different irrigation regimes. Journal of Agronomy and Crop Science 191:439–449.

40.   Wang D, Yu ZW, Xu ZZ. 2005. Photosynthesis, carbohydrate storage and remobilization during grain filling as affected by sulphur application in winter wheat. Agricultural Sciences in China 4:507–513.

41.   Xu ZZ, Zhou GS, Li H. 2004. Responses of chlorophyll fluorescence and nitrogen level of Leymus chinensis seedling to changes of soil moisture and temperature. Journal of Environmental Science 16:666–669.

42.   Zhou GS, Wang YH, Jiang YL, Xu ZZ. 2002. Carbon balance along northeast China transect (NECT-IGBP). Science in China (Series C) 45:18-29.

43.   李浪, 李义博, 马全会, 于鸿莹, 刘晓迪, 戚妙, 许振柱. 2020. 水分驱动下茵陈蒿)(Artemisia capillaris Thunb.)地上生物量模型与异速生长特征. 生态学杂志 39(1):337–348

44.   宋贺，蒋延玲，许振柱，周广胜．2019. 玉米光合生理参数对全生育期干旱与拔节后干旱过程的响应．生态学报 39(7): 2405–2415.

45.   李义博, 宋贺, 周莉, 许振柱, 周广胜. 2017. C₄植物玉米的光合-光响应曲线模拟研究. 植物生态学报 41(12):1289–1300.

46.   石耀辉, 周广胜, 蒋延玲, 王慧, 许振柱, 麻雪艳. 2017. 贝加尔针茅响应降水变化敏感指标及关键阈值. 生态学报 37:2620–2630.

47.   宋贺, 于鸿莹, 陈莹婷, 许振柱, 周广胜. 2016. 北京植物园不同功能型植物叶经济谱. 应用生态学报 27(6):1861–1869.

48.   吕晓敏, 王玉辉, 周广胜, 许振柱, 陈 军, 谭丽萍, 刘 涛. 2015. 温度与降水协同作用对短花针茅(Stipa breviflora)生物量及其分配的影响. 生态学报 35(3):752–760.

49.   于鸿莹, 陈莹婷, 许振柱, 周广胜. 2014. 内蒙古荒漠草原植物叶片功能性状关系及其经济谱分析. 植物生态学报 38(10):1029–1040.

50.   陈莹婷, 许振柱. 2014. 植物叶经济谱的研究进展. 植物生态学报 38(10):1135–1153.

51.   吕晓敏, 周广胜, 王玉辉, 许振柱, 陈军, 谭丽萍, 刘涛. 2014. 短花针茅(Stipa breviflora)功能性状对水热协同作用的敏感性和适应性. 科学通报 59:3378–3387.

52.   侯彦会, 周广胜, 许振柱. 2013. 基于红外增温的草地生态系统响应全球变暖的研究进展. 植物生态学报 37:1153–1167.

53.   郑成岩, 于振文, 张永丽, 王东, 石玉, 许振柱. 2013. 土壤深松和补灌对小麦干物质生产及水分利用率的影响. 生态学报 33:2260–2271.

54.   石耀辉, 周广胜, 蒋延玲, 王慧, 许振柱. 2013. CO₂浓度和降水协同作用对短花针茅生长的影响. 生态学报 33:4478–4485.

55.   刘涛, 张永贤, 许振柱, 周广胜, 侯彦会, 林 琳. 2012. 短期增温和增加降水对内蒙古荒漠草原土壤呼吸的影响. 植物生态学报 36:1043–1053.

56.   王慧, 周广胜, 蒋延玲, 石耀辉, 许振柱. 2012. 降水与CO₂浓度协同作用对短花针茅光合特性的影响. 植物生态学报 36:597–606.

57.   方东明, 周广胜, 蒋延玲, 贾丙瑞, 许振柱, 隋兴华. 2012. 基于CENTURY 模型模拟火烧对大兴安岭兴安落叶松林碳动态的影响. 应用生态学报 23:2411–2421.

58.   韩占江, 于振文, 王东, 张永丽, 许振柱. 2011. 测墒补灌对冬小麦氮素积累与转运及籽粒产量的影响. 生态学报 31:1631–1640.

59.   石玉, 谷淑波, 于振文, 许振柱. 2011. 不同品质类型小麦籽粒贮藏蛋白组分含量及相关酶活性. 作物学报 37:2030−2038

60.   姜东燕, 于振文, 许振柱. 2011. 灌溉量和施氮量对冬小麦产量和土壤硝态氮含量的影响. 应用生态学报 22:364–368.

61.   孟维伟, 褚鹏飞, 于振文, 许振柱. 2011. 灌水对不同品种小麦茎和叶鞘糖含量及产量的影响. 应用生态学报 22:2487–2494.

62.   石玉, 陈茂学, 于振文, 许振柱. 2011. 灌浆期不同阶段遮光对小麦籽粒蛋白质组分含量和加工品质的影响. 应用生态学报 22:2504–2510.

63.   王红光, 于振文, 张永丽, 王东, 石玉, 许振柱. 2011. 测墒补灌对小麦光合特性和干物质积累与分配的影响. 应用生态学报 22:2495–2503.

64.   马兴华, 王东, 于振文, 王西之, 许振柱. 2010. 不同施氮量下灌水量对小麦耗水特性和氮素分配的影响. 生态学报 30:1955–1965.

65.   平晓燕, 周广胜, 孙敬松, 许振柱. 2010. 基于功能平衡假说的玉米光合产物分配动态模拟. 应用生态学报21:129–135.

66.   郑成岩, 于振文, 张永丽, 王东, 许振柱. 2010. 不同施氮水平下灌水量对小麦水分利用特征和产量的影响. 应用生态学报 21:2799–2805.

67.   韩广轩, 周广胜, 许振柱. 2009. 玉米农田生态系统土壤呼吸作用季节动态与碳收支初步估算. 中国生态农业学报 17:874–879.

68.   王小燕, 郑成岩, 于振文, 许振柱. 2009. 水氮互作对小麦土壤水分利用和茎中果聚糖含量的影响. 应用生态学报 20:1876–1882.

69.   杨晓亚, 于振文, 许振柱. 2009. 灌水量和灌水时期对小麦耗水特性和氮素积累的影响. 生态学报 29:846–853.

70.   林祥磊, 许振柱, 王玉辉, 周广胜. 2008. 羊草(Leymus chinensis)叶片光合参数对干旱与复水的响应机理与模拟. 生态学报 28:4718–4724.

71.   韩广轩, 周广胜, 许振柱. 2008. 中国农田生态系统土壤呼吸作用研究与展望. 植物生态学报 32:719–733.

72.   韩广轩, 周广胜, 许振柱. 2008. 玉米生长季土壤呼吸的时间变异及其影响因素. 生态学杂志 27:1698–1705.

73.   祁红彦, 周广胜, 许振柱. 2008. 北方玉米冠层光合有效辐射垂直分布及影响因子分析. 气象与环境学报24:22–26.

74.   许振柱, 周广胜. 2007. 全球变化下植物的碳氮关系及其环境调节研究进展---从分子到生态系统. 植物生态学报 31:738–747.

75.   平晓燕, 贾丙瑞, 王风玉, 王玉辉, 周莉, 许振柱, 周广胜. 2007. 羊草种群生物量分配动态模拟. 应用生态学报 18:2699–2704.

76.   韩广轩, 周广胜, 许振柱, 杨扬, 刘景利, 史奎桥. 2007. 玉米地土壤呼吸作用对土壤温度和生物因子协同作用的响应. 植物生态学报 31:363–371.

77.   李祎君, 许振柱, 王云龙, 周莉, 周广胜. 2007. 玉米农田水热通量动态与能量闭合分析. 植物生态学报 31:1132–1144.

78.   许振柱, 周广胜, 肖春旺, 王玉辉. 2005. CO₂浓度倍增和土壤干旱对两种幼龄沙生灌木碳分配的影响. 植物生态学报 29:281–288.

79.   许振柱, 周广胜. 2005. 不同温度条件下土壤水分对羊草幼苗生长特性的影响. 生态学杂志 24:256–260.

80.   许振柱, 周广胜. 2005. 草原生态系统对气候变化和CO₂浓度升高的响应. 应用气象学报 16:385-395.

81.   池宏康, 周广胜, 许振柱, 肖春旺, 袁文平. 2005. 表观反射率及其在植被遥感中的应用. 植物生态学报 29:74–80.

82.   许振柱, 周广胜, 李晖. 2004. 羊草叶片气体交换参数对温度和土壤水分的响应 植物生态学报 28:300–304.

83.   许振柱, 王崇爱, 李晖. 2004. 土壤干旱对小麦叶片光合和氮素水平及其运转效率的影响. 干旱地区农业研究 22:75–91.

84.   许振柱, 周广胜, 肖春旺, 王玉辉. 2004. CO₂浓度倍增条件下土壤干旱对两种沙生灌木碳氮含量及其适应性的影响. 生态学报 24:2186–2191.

85.   许振柱, 周广胜. 2004. 植物氮代谢及其环境调节研究进展. 应用生态学报 15: 511-516.

86.   许振柱, 于振文, 王东, 张永丽. 2004. 灌溉量对小麦氮素吸收和运转的影响. 作物学报 30:1002–1007.

87.   周广胜, 许振柱, 王玉辉. 2004. 全球变化的生态系统适应性. 地球科学进展 19:642–649.

88.   周广胜, 王玉辉, 白莉萍, 许振柱, 石瑞香, 周莉, 袁文平. 2004. 陆地生态系统与全球变化相互作用的研究进展. 气象学报 62:692–707.

89.   王云龙, 许振柱, 周广胜. 2004. 水分胁迫对羊草光合产物分配及其气体交换特征的影响. 植物生态学报 28:803–809.

90.   许振柱, 周广胜, 李晖, 王玉辉, 赵敏, 袁文平. 2003. 羊草干物质积累及叶片气体交换对土壤水分的响应. 干旱区研究 20:241–246

91.   许振柱, 于振文. 2003. 灌溉条件对小麦籽粒蛋白质组分积累及品质的影响. 作物学报 29:682–687.

92.   许振柱, 于振文. 2003. 限量灌溉对冬小麦水分利用的影响. 旱地区农业研究 21:6–10.

93.   许振柱, 周广胜. 2003. 农业水分利用率及其对环境和管理活动的响应. 自然资源学报 18:294–303.

94.   许振柱, 于振文, 张永丽. 2003. 土壤水分对小麦籽粒淀粉合成和积累特性的影响. 作物学报 19:595–603.

95.   许振柱, 周广胜, 王玉辉. 2003. 植物的水分阈值与全球变化. 水土保持学报 17:155–158.

96.   周广胜, 王玉辉, 许振柱, 周莉, 蒋延玲. 2003. 中国东北样带碳循环研究进展. 自然科学进展 13:917–922.

97.   许振柱, 周广胜. 2003. 陆生植物对全球变化的适应性研究进展. 自然科学进展 13:113–119.

98.   许振柱, 于振文, 张永丽. 2002. 强筋小麦高产优质高效灌溉方案的研究. 山东农业科学 (1):20–22.

99.   许振柱, 李长荣, 陈平, 于振文, 余松烈. 2000. 土壤干旱对冬小麦生理特性和干物质积累的影响.干旱地区农业研究 18:113–118.123.

100.许振柱, 于振文, 李晖, 余松烈. 1997. 限量灌水对冬小麦光合性能和水分利用的影响. 华北农学报 12:65–70.

101.许振柱, 于振文, 董庆裕, 亓新华, 余松烈. 1997. 水分胁迫对冬小麦旗叶细胞质膜及叶肉细胞超微结构的影响. 作物学报 23:370–375.

102.许振柱, 于振文, 董庆裕, 余松烈. 1996. 不同栽培条件下旱地麦田土壤水分变化规律. 干旱地区农业研究 14:20–24.30.

103.许振柱, 于振文, 亓新华, 余松烈. 1995. 土壤干旱对冬小麦乙烯释放、多胺积累和细胞质膜的影响. 植物生理学报 21:295–301.