张先亮,1985年生,山东菏泽人,中共党员,校聘教授,博士,博士生/硕士生导师,哈佛大学、北京大学、不列颠哥伦比亚大学访问学者,河北省林草科技创新青年拔尖人才,中国地理学会树轮分会委员会委员、中国林学会林业气象专业委员会常务委员。主要从事气候生态学方面的研究,主持与参与国家自然科学基金2项,其他省市级基金5项。目前在Nature Communications, Global Change Biology, Agricultural and Forest Meteorology等国际著名生态学、林学及气候学期刊上发表论文以第一作者/通讯作者发表论文42篇(中科院分区一区论文15篇)。研究成果受到国内外同行关注,关于兴安落叶松的研究成果被美国地球物理学会(AGU)新闻报道,关于樟子松的研究成果被中国科学报报道。担任《Journal of Plant Ecology》、《林业科学》、《河北农业大学学报》青年编委及《林业与生态科学》编委。
教育经历:
访问学者:2012/09-2023/07 北京大学 合作导师:刘鸿雁教授
访问学者:2017/09-2018/09 哈佛大学 合作导师:Neil Pederson
博士:2011/09-2014/07 中国科学院大气物理研究所 专业:大气物理学与大气环境,导师:延晓冬教授 研究方向:气候变化及其分析
硕士:2008/09-2011/07 中国科学院沈阳应用生态研究所 专业:生态学, 导师:陈振举教授 研究方向:树木年轮与气候变化
本科:2004/09-2008/07 沈阳农业大学 专业:林学, 导师:刘明国教授
工作经历:
2019/05至今,河北农业大学 林学院 校聘教授
2014/10-2019/04,沈阳农业大学林学院 讲师
主要承担课程:
1.本科课程:《生态学研究方法》、《森林气象学》
2.研究生课程:《科技英文写作》
3.博士生课程:《森林生物学》《森林培育学》
研究方向和领域:
1.树木年轮生态学
2.气候变化背景下的森林稳定性及森林恢复潜力
3.森林经营措施与树木生长变化
主要科研/教学项目:
1、 国家自然科学基金区域创新发展联合基金重点项目课题,U24A20353,环境变化对植物、土壤的长效作用及人工林的适应性,2025/01-2028/12,在研,主持。
2、 河北省林业和草原局揭榜挂帅项目课题,2025JBGS0002-4,蒙古栎结构及树种调控技术研究,2025/01-2027/12,在研,主持
3、 国家重点研发计划专题,2023YFD220040101,水热变化对典型人工林不同林龄期木质部生长的影响,2023/12-2028/12,在研,骨干(排名第二)
4、 西藏自治区自然科学基金重点项目,XZ202501ZR010,拉萨南北山困难立地高固碳造林树种的固碳增汇速率及其驱动机制,2025/01-2027/12,在研,共同执行人(排名第二,技术负责人)
5、 国家自然科学基金青年项目,41601045,快速升温对东北地区樟子松生长响应差异的影响研究,2017/01-2019/12,已结题,主持
6、 中央引导地方科技发展项目,226Z6801G,塞罕坝华北落叶松人工林饱和碳储量及驱动机制,2022/07-2024/12, 已结题,主持
7、 河北省高等学校青年拔尖人才项目,BJ202025, 燕山山区森林稳定性评估及恢复潜力,2020/01-2022/06, 已结题,主持
8、 河北农业大学引进人才项目,YJ201918, 2019/02-2024/12, 已结题,主持
主要科研论文、著作:
2025年
[45] Wu, Y., …, & Zhang, X.* Balancing Individual Growth and Stand Carbon Dynamics: Optimizing age-dependent density management for Larix principis-rupprechtii plantations in semi-humid to semiarid regions. Journal of Forestry Research. 2025
[44] Deng, R., Liao, J., Rademacher, T., Xu, Z., Du, M., Zheng, J., Fu, L. & Zhang, X.* Species-specific influences of competition and tree size on drought sensitivity and resistance for three planted conifers in northern China. Forest Ecosystems. 2025. 100295
[43] Liao, J., Zhang, X.*, Rademacher, T., Xu, C., Du, M., Guo, F., Li, W., Zheng, J., Wu, Y. & Manzanedo, R.D. Slope mediates drought sensitivity but does not affect drought recovery for young trees along elevation gradients in temperate planted larch forests. Forest Ecosystems. 2025. 100371
[42] Han, X., Gao, L.*, Zhang, X., Fang, K., Li, S., Cui, K., Guo, M. & Zhao, X. The negative effects of competition on tree resilience weakened as drought severity intensified. Agricultural and Forest Meteorology. 2025. 110544
[41] Wang, Y., Liu, X.*, Jin, H., Zeng, X., Zhang, X., Kang, H., Kang, S., Li, Y. & Zhang, Q. Climate-induced permafrost degradation exerts species-specific impacts on pine and larch growth in the Da Xing’anling Mountains, Northeast China. Agricultural and Forest Meteorology. 2025. 110665
2024年
[40] Zhang, Y., Liao, J., Xu, C., Du, M. & Zhang, X.* Optimizing variables selection of random forest to predict radial growth of Larix gmelinii var. principis-rupprechtii in temperate regions. Forest Ecology and Management. 2024. 122159
[39] Du, M., Xu, C., Wang, A., Lv, P., Xu, Z., Zhang, X.*, (2024). Different drought recovery strategy between Larix spp. and Quercus mongolica in temperate forests. Science of The Total Environment 938, 173521.
[38] Zhang, X., Liu, H.*, & Rademacher, T. (2024). Higher latewood to earlywood ratio increases resistance of radial growth to severe droughts in larch. Science of The Total Environment, 912. (中科院一区,IF=9.8, 科普文章:https://mp.weixin.qq.com/s/D1y576Co_d6CYLcAsqFgLw)
2023年
[37] Zhang, X., Rademacher, T., Liu, H., Wang, L., & Manzanedo, R. D. (2023). Fading regulation of diurnal temperature ranges on drought-induced growth loss for drought-tolerant tree species. Nature Communications, 14(1), 6916. doi:10.1038/s41467-023-42654-z (Nature 子刊,IF=16.6, 科普文章:http://www.ecology.pku.edu.cn/index/news_cont/id/1410.html)
[36] 董一博, 解萍萍, 刘洋, 孙冰喆, & 张先亮*. 2023. 太岳山不同年龄油松早材树脂道面积 对气候变化的响应. 应用生态学报 34.
[35] 解萍萍, 张博奕, 董一博, 吕鹏程, 杜明超, 张先亮*. 2023. 华北落叶松和白杄径向生长对干旱的生态弹性差异. 应用生态学报 34.
[34] D’Orangeville L, St-Laurent M-H, Boisvert-Marsh L, Zhang X, Bastille-Rousseau G & Itter M. Current symptoms of climate change on trees and wildlife of the boreal forest. In: Boreal forests in the face of climate change: Sustainable management. 2023. Springer. (关于北方森林的专著)
2022年
[33] Zhang, X., Yu, P., Wang, D., Xu, Z.*, 2022. Density- and age- dependent influences of droughts and intrinsic water use efficiency on growth in temperate plantations. Agricultural and Forest Meteorology 325. (中科院一区,IF=6.4).
[32] Zhang, X., Manzanedo, R.D., Lv, P., Xu, C., Hou, M., Huang, X., Rademacher, T., 2022. Reduced diurnal temperature range mitigates drought impacts on larch tree growth in North China. Science of The Total Environment 848. (中科院一区,IF=10.8)
[31] Lv, P., Rademacher, T., Huang, X.*, Zhang, B., Zhang, X.,* 2022. Prolonged drought duration, not intensity, reduces growth recovery and prevents compensatory growth of oak trees. Agricultural and Forest Meteorology 326. (中科院一区,IF=6.4).
[30] Li, W., Yue, F., Wang, C., Liao, J., Zhang, X.*, 2022. Climatic influences on intra-annual stem variation of Larix principis-rupprechtii in a semi-arid region. Frontiers in Forests and Global Change. (中科院二区,IF=4.3)
[29] Xu, C., Zhang, X.*, Hernandez-Clemente, R., Lu, W., Manzanedo, R.D., 2022. Global Forest Types Based on Climatic and Vegetation Data. Sustainability 14, 634.
[28] 汪椿凯,黄选瑞,李雪,姜雨,王小雪,张先亮*.2022.不同林分类型林缘华北落叶松细胞特征.应用生态学报. 33 (5): 1191-1198.
2021年以前
[27]. Zhang X*, Lv P, Xu C, Huang X, Rademacher T (2021) Dryness decreases average growth rate and increases drought sensitivity of Mongolia oak trees in North China. Agricultural and Forest Meteorology, 308-309, 108611.https://doi.org/10.1016/j.agrformet.2021.108611(科普文章:http://wap.sciencenet.cn/home.php?mod=space&uid=260773&do=blog&id=1301568)(中科院1区,IF=5.7)
[26]. Zhang X*, Li X, Rubén DM et al.(2021) High risk of growth cessation of planted larch under extreme drought. Environmental Research Letters.16 014040https://doi.org/10.1088/1748-9326/abd214(科普文章:人工林干旱危机http://blog.sciencenet.cn/blog-260773-1261947.html)(2区,IF=6.8)
[25]. Xu C, Hou M, Yan X, Zhang X* (2021) Temporal variability of seasonal warming rates in China. International Journal of Climatology ,41, E1597-E1607.https://doi.org/10.1002/joc.6793(科普文章:中国变暖速率研究http://blog.sciencenet.cn/blog-260773-1249780.html)(2区,IF=4.0)
[24]. Zhang X*, Manzanedo RD, Xu C, Hou M, Huang X (2021) How to select climate data for calculating growth-climate correlation. Trees, 35, 1199-1206.https://doi.org/10.1007/s00468-021-02108-9(2区,IF=2.2)
[23]. 李雪,黄选瑞,张先亮*.不同去趋势方法对树轮气候信号识别的影响.生态学报.2021.41(5):1970-1978
[22]. Zhang X*, Li J, Liu X, Chen Z* (2020) Improved EEMD-based standardization method for developing long tree-ring chronologies. Journal of Forestry Research, 31, 2217-2224.D OI: 10.1007/s11676-019-01002-y
[21]. Zhang X*, Manzanedo RD, D'orangeville L et al. (2019) Snowmelt and early to mid-growing season water availability augment tree growth during rapid warming in southern Asian boreal forests. Global Change Biology, 25, 3462-3471.https://doi.org/10.1111/gcb.14749 (该文章的研究结果被中国科学报报道,http://news.sciencenet.cn/htmlnews/2019/7/428230.shtm)(1区,IF=10.1)
[20]. Zhang X*, Bai X, Hou M, Chen Z*, Manzanedo RD (2019) Warmer winter ground temperatures trigger rapid growth of dahurian larch in the permafrost forests of northeast China. Journal of Geophysical Research: Biogeosciences,124, 1088-1097.DOI: 10.1029/2018JG004882 (该文章被美国AGU新闻报道,报道链接:https://news.agu.org/press-release/climate-change-is-giving-old-trees-a-growth-spurt/,科普文章:http://blog.sciencenet.cn/blog-260773-1167162.html)
[19]. Zhang X*,Huang X (2019) Human disturbance caused stronger influences on global vegetation change than climate change. PeerJ,7, e7763.
[18]. Zhang X, Bai X, Hou M, Chang Y, Chen Z*(2018) Reconstruction of the regional summer ground surface temperature in the permafrost region of Northeast China from 1587 to 2008. Climatic Change, 1-13. (2区, IF=4.168)
[17]. Zhang X, Yan X*(2018) Criteria to evaluate the validity of multi‐model ensemble methods. International Journal of Climatology, 38, 3432-3438.DOI:10.1002/joc.5486(2区,IF=3.601)
[16]. Zhang X, Zou F, Chen Z*(2017) Climate-Induced Tree Growth Variations under the RCP 2.6 Scenario: A Case Study on the Southeastern Tibetan Plateau. Forests, 8, 359. doi:10.3390/f8100359(2区,IF=2.116)
[15]. Zhang X*, Xiong Z, Zhang X, Shi Y, Liu J, Shao Q, Yan X*(2017) Simulation of the climatic effects of land use/land cover changes in eastern China using multi-model ensembles. Global and Planetary Change,154, 1-9.(2区,IF=4.1)
[14]. Zhang X, Yan X, Chen Z*(2017) Geographic distribution of global climate zones under future scenarios. International Journal of Climatology,37, 4327-4334.(2区,IF=3.601)
[13]. Zhang X, Wu S, Yan X*, Chen Z*(2017) A global classification of vegetation based on NDVI, rainfall and temperature. International Journal of Climatology,37, 2318-2324.(2区,IF=3.601)
[12]. Zhang X, Chen Z*(2017) A new method to remove the tree growth trend based on ensemble empirical mode decomposition. Trees,31, 405-413.(2区,IF=1.8)
[11]. Zhang X, Bai X, Chang Y, Chen Z*(2016) Increased sensitivity of Dahurian larch radial growth to summer temperature with the rapid warming in Northeast China. Trees,30, 1799-1806.(2区,IF=1.8)
[10]. Zhang X, Yan X, Chen Z*(2016) Reconstructed Regional Mean Climate with Bayesian Model Averaging: A Case Study for Temperature Reconstruction in the Yunnan–Guizhou Plateau, China. Journal of Climate,29, 5355-5361.(1区,IF=4.805)
[9]. Zhang X*, Yan X* (2016) Deficiencies in the simulation of the geographic distribution of climate types by global climate models. Climate Dynamics,46, 2749-2757.(1区,IF=4.048)
[8]. Zhang X, Xiong Z, Zhang X, Shi Y, Liu J, Shao Q, Yan X* (2016) Using multi-model ensembles to improve the simulated effects of land use/cover change on temperature: A case study over northeast China. Climate Dynamics,46, 765-778.(1区,IF=4.048)
[7]. Zhang X*, Yan X (2015) A new statistical precipitation downscaling method with Bayesian model averaging: a case study in China. Climate Dynamics,45, 2541-2555.(1区,IF=4.048)
[6]. Zhang X*, Yan X (2014) Spatiotemporal change in geographical distribution of global climate types in the context of climate warming. Climate Dynamics,43, 595-605.(1区,IF=4.048)
[5]. Zhang X*, Yan X (2014) A novel method to improve temperature simulations of general circulation models based on ensemble empirical mode decomposition and its application to multi-model ensembles. Tellus A: Dynamic Meteorology and Oceanography,66, 24846.(3区,IF=2.0)
[4]. Zhang X*,Yan X (2014) Temporal change of climate zones in China in the context of climate warming. Theoretical and applied climatology,115, 167-175.
[3]. Zhang X*, He X, Li Jet al.(2011) Temperature reconstruction (1750–2008) from Dahurian larch tree-rings in an area subject to permafrost in Inner Mongolia, Northeast China. Climate Research,47, 151-159.
[2]. 张先亮,何兴元,陈振举*,崔明星,黎娜,陈玮. 2011.大兴安岭山地樟子松径向生长对气候变暖的响应———以满归地区为例.应用生态学报.22(12):3101-3108.
[1]. 张先亮,崔明星,马艳军,吴涛,陈振举*,丁玮航. 2010.大兴安岭库都尔地区兴安落叶松年轮宽度年表及其与气候变化的关系.应用生态学报.21(10): 2501-2507.
技术规程:
1.张先亮等. 华北落叶松人工林地上碳储量优化经营技术规程. 河北省地方标准. 2025
2.刘强、黄选瑞、荣秋菊、…、张先亮等. 冀北山地石质山地造林技术规程. 河北省地方标准. 2023
3.黄选瑞…、张先亮等. 中国森林认证非木质林产品经营认证操作指南. 中国林业行业标准. 2024
大学生创新创业项目:
1.河北农业大学大学生创新创业国家级项目:塞罕坝不同海拔华北落叶松树脂道对气候胁迫的响应差异(2022070480129);
2.河北农业大学大学生创新创业省级项目:干旱对华北落叶松年轮细胞形成的影响机制(s202310086033);
写给考生的话
气候变化给陆地生态系统带来了极大的冲击。植物生存依赖于气候等周围环境,而动物生存依赖于植物。维持稳定而健康的森林是人类长期稳定健康生存的根本。探索自然的奥秘,揭秘森林如何稳定健康存在,实现自然资源的永续利用是我们孜孜追求的目标。欢迎具有奉献精神,热爱大自然,热爱林业的同学加入我们团队。在带领你领略大自然风光的同时,让你了解更多森林的秘密。
硕士招生专业:林学(森林经理方向)
博士招生专业:林学
联系方式:zhxianliang85@gmail.com, lxzhxl@hebau.edu.cn
个人科学研究网页:
ResearchGate:https://www.researchgate.net/profile/Xianliang_Zhang/contributions
ORCID:http://orcid.org/0000-0002-2870-3504
GOOGLE:https://sc.panda321.com/citations?user=JXH7N5EAAAAJ&hl=zh-CN&oi=ao
