(1) 张守仁, 高荣孚 1998. 白杨派新无性系气孔生理生态特性的研究. 生态学报, 18(4):358-363
(2) 张守仁. 1999. 叶绿素荧光参数及其意义讨论. 植物学通报, 16(4):444-448
(3) 张守仁, 高荣孚. 1999. 介绍一种改进的研究气孔运动的方法. 植物学通报, 16(1):89-92
(4) 张守仁, 高荣孚. 1999. 光胁迫下植物光合生理生态研究进展. 见: 植物科学进展, 第二卷 (李承森主编), 北京: 高等教育出版社; 海德堡: 施普林格出版社. 152-164
(5) 张守仁 2000. 光合机构对光诱导的响应. 中国科学院建院50周年博士后文集, 科学出版社. 152-152
(6) 张守仁, 高荣孚.2001)光诱导下杂种杨无性系的叶角和叶绿体运动. 生态学报, 21(1):68-74
(7) 张守仁, 高荣孚.2000)光胁迫下杂种杨无性系光合生理生态特征的研究. 植物生态学报, 24(5):528-533
(8) Zhang Shouren, Ma Keping. 2000. Gas exchange and leaf orientation of Acer ginnala in relation to acclimation and avoidance of light stress. Proceedings of international symposium on forest ecosystem: ecology, conservation and sustainable management, Chengdu, Sichuan.
(9) Zhang Shouren, Gao Rongfu.2000)Effects of light stress on oxygen evolution and photochemical energy storage of hybrid poplar clones determined by photoacoustic technique. Journal of Integrative Plant Biology, 42(8):818-823
(10) Zhang Shouren, Gao Rongfu.2000)Non-uniform stomatal closure of poplar hybrid clones under light stress determined by scanning electron microscopy and modification of intercellular CO2 concentration. Trees: Structure and Function, 14(7): 376-383
(11) Zhang Shouren, Gao Rongfu 1999. Diurnal changes of gas exchange, chlorophyll fluorescence and stomatal aperture of hybrid poplar clones subjected to midday light stress. Photosynthetica, 37(4): 559-571
(12) Zhang Shouren, Li Qingkang, Ma Keping, Chen Linzhi 2001. Temperature-dependent gas exchange and stomatal/non-stomatal limitation to CO2 assimilation of Quercus liaotungensis under midday high irradiance. Photosynthetica, 39 (3): 383-388
(13) Zhang Shouren, Ma Keping, Chen Linzhi 2002. Tempo-Spatial Variations in Stomatal Conductance, Aperture and Density of Ligustrum sinense Acclimated to Different Light Environments. Journal of Integrative Plant Biology, 44(10): 1225-1232
(14) Zhang Shouren, Ma Keping, Chen Linzhi 2002. Photosynthetic gas-exchange and leaflet movement of Robinia pseudoacacia in relation to changing light environments. Journal of Integrative Plant Biology, 44(7): 858-863
(15) Zhang Shouren, Ma Keping, Chen Linzhi. 2003. Effects of Varying Light Environments on Photosynthetic Plasticity of Paeonia suffruticosa. Environmental and Experimental Botany,49: 121-133
(16) 张守仁, 高荣孚,王连军 2004. 杂种杨无性系光系统II放氧活性、光合色素及叶绿体超微结构对光胁迫的响应. 植物生态学报, 28 (2): 143-149.
(17) Zhang Shouren, Dang Qing-La.2004) Soil temperature interacted with CO2 in influencing the photosynthetic functions of black spruce. Acta Physiologiae Plantarum, 26 ( 3 )Supplement:244.
(18) Zhang Shouren, Dang Qing-Lai 2005. Effects of soil temperature and elevated atmospheric CO2 concentration on gas exchange, in vivo carboxylation and chlorophyll fluorescence in jack pine and white birch seedlings. Tree Physiology 25:609–617.
(19) 陈兰,张守仁*2006. 增强UV-B辐射对暖温带落叶阔叶林土庄绣线菊水分生理生态特征、叶氮素含量及形态特性的影响. 植物生态学报, 30(1):47-56
(20) Zhang Shouren, Dang Qing-Lai, Yu Xiaoguang 2006. Nutrient and [CO2] elevation had synergistic effects on biomass production but not on biomass allocation of white birch seedlings. Forest Ecology and Management 234:238-244
(21) Zhang Shouren, Dang Qing-Lai 2006. Effects of carbon dioxide concentration and nutrition on photosynthetic functions of white birch seedlings. Tree Physiology 26:1457–1467
(22) Cao Bing, Dang Qing-Lai, Zhang Shouren 2007. Relationship between photosynthesis and leaf nitrogen concentration under ambient and elevated [CO2] in white birch (Betula papyrifera) seedlings. Tree Physiology, 27, 891–899.
(23) Zhang Shouren, Dang Qing-Lai 2007. Interactive effects of soil temperature and [CO2] on morphological and biomass traits in seedlings of four boreal tree species. Forest Science 53: 453-460.
(24) 张守仁, 樊大勇, Strasser RJ 2007. 植物生理生态学研究中的控制实验和测定仪器新进展. 植物生态学报, 31(5):982-987.
(25) Cao, B., Q.L. Dang, X.G. Yu and S.R. Zhang. 2008. Effects of [CO2] and nitrogen on morphological and biomass traits of white birch (Betula papyrifera) seedlings. Forest Ecology and Management, 254: 217-224.
(26) 徐新武, 樊大勇, 谢宗强, 张守仁, 张想英. 2009. 不同冲洗液对毛白杨和油松枝条水力导度和抵抗空穴化能力测定值的影响. 植物生态学报 , 33 (1): 150-160.
(27) 吴茜, 丁佳, 闫慧, 张守仁*,方腾,马克平 2011. 模拟降水变化和土壤施氮对浙江古田山5个树种幼苗生长和生物量的影响. 植物生态学报,35(3): 256-267.
(28) 丁佳, 吴茜, 闫慧, 张守仁* 2011. 微地形和土壤特性对亚热带常绿阔叶林内植物功能性状的影响.生物多样性研究,19(2): 158-167.
(29) 祝介东, 孟婷婷, 倪健, 苏宏新, 谢宗强, 张守仁, 郑元润, 肖春旺. 2011. 不同气候带间成熟林植物叶性状间异速生长关系随功能型的变异.植物生态学报, 35 (7): 687–698
(30) Da-Yong Fan, Sheng-Lin Jie, Chang-Cheng Liu, Xiang-Ying Zhang, Xin-Wu Xu,Shou-Ren Zhang, Zong-Qiang Xie. 2011. The trade-off between safety and efficiency in hydraulicarchitecture in 31 woody species in a karst area. Tree Physiology, 31: 865–877.
(31) Hao Hai-Ping, Jiang Chuang-Dao, Zhang Shou-Ren, Tang Yu-Dan, Shi Lei 2012. Enhanced thermal-tolerance of photosystem II by elevating root zone temperature in Prunus mira koehne seedlings. Plant Soil, 353:367-378.
(32) 闫慧, 吴茜, 丁佳, 张守仁* 2013. 不同降水及氮添加对浙江古田山4种树木幼苗光合生理生态特征与生物量的影响. 生态学报,33(14):4226-4236.
(33) 闫慧, 董心亮, 张守仁*,MucciardiA. (2013) 古田山亚热带常绿阔叶林粗根空间分布特征及影响因子分析—探地雷达途径. 中国科学, 43(9):788-798.
(34) Zhang Shouren, Dang Qing-Lai. 2013. CO2 elevation improves photosynthetic performance in progressive warming environment in white birch seedlings. F1000Research 2:13 (doi: 10.3410/f1000research.2-13.v1)
(35) Zhang Shouren, Dang Qing-Lai, Cao Bing. 2013. Nutrient supply has greater influence than sink strength on photosynthetic adaptation to CO2 elevation in white birch seedlings. Plant Science ,203/204, 56-62
(36) Zhang S, Fan D, Xu X, Wu Q, Yan H. 2013. Eco-physiological adaptation of dominant tree species at two contrasting karst habitats in southwestern China. F1000 Research, 2:122;
(37) 闫慧, 董心亮,张守仁*. 2014. 古田山亚热带常绿阔叶林粗根生物量分布特征研究. 科学通报,59: 2416-2425
(38) Kr?ber W, Zhang S, Ehmig M, Bruelheide H. 2014. Linking xylem hydraulic conductivity and vulnerability to the leaf economics spectrum -A cross-species study of 39 evergreen and deciduous broadleaved subtropical tree species. PLOS One, 9(11): e109211. doi:10.1371/journal.pone.0109211
(39) Dayong Fan, Shouren Zhang, Hui Yan, Qian Wu, Xinwu Xu and Xiangping Wang. 2018. Do karst woody plants control xylem tension to avoid substantial xylem cavitation in the wet season? Forest Ecosystems, 5:40