Response of fiber anatomical characteristics of Fraxinus mandshurica to climate change in Maoershan, Northeast China

doi:10.13287/j.1001-9332.202511.005

Abstract

Abstract: Fraxinus mandshurica is a native high-quality timber species in Northeast China. The anatomical characteristics of its wood fibers are crucial indicators of wood performance. In the progeny test forest of F. mandshurica in Maoershan Experimental Forest, we investigated the response of fiber anatomical characteristics of whole ring, early-wood, and latewood to climate change by dendrochronology and wood anatomy methods. The results showed that juvenile F. mandshurica experienced a rapid growth period of approximately 10 years. From 2003 onwards, the ring width, fiber cell number, and total fiber cell area showed fluctuating increases, reaching peak values in 2011. At 2011, the ring width was 3749.59 μm, fiber cell number was 3750, and total fiber cell area was 760388.85 μm². There was a consistent overall correlation among the anatomical characteristics of fibers in the whole ring, earlywood, and latewood. The ring width was significantly positively correlated with both fiber cell number and total fiber cell area. The ring width, fiber cell number, and total fiber cell area of earlywood were primarily constrained by precipitation. These characteristics showed a significant negative correlation with precipitation in March, a significant positive correlation with precipitation in April, and negative correlation with temperature in June. The ring width, fiber cell number, and total fiber cell area of latewood were significantly negatively correlated with the minimum temperature and precipitation in September, and significantly positively correlated with maximum temperature in September. Under the low-temperature event, ring width, fiber cell number, and total fiber cell area decreased significantly by 19.7%, 24.2%, and 22.0%, respectively. Following the event, the resilience was 1.14, 1.14, and 1.26. Both temperature and precipitation jointly affected ring width of earlywood and latewood and fiber cell growth. The low-temperature event could significantly reduce both fiber cell number and total fiber cell area, thereby inhibiting radial growth. In response to the low-temperature event, F. mandshurica showed a significant capacity for recovery.

Key words: Fraxinus mandshurica, fiber anatomical characteristics, climate change, low temperature event

LIU Ye, WANG Xigang, ZENG Fansuo, ZHAN Yaguang, ZHAO Haifeng, TANG Ying, XIN Ying. Response of fiber anatomical characteristics of Fraxinus mandshurica to climate change in Maoershan, Northeast China[J]. Chinese Journal of Applied Ecology, 2025, 36(11): 3277-3286.

References

[1] Allen CD, Breshears DD, McDowell NG. On underestimation of global vulnerability to tree mortality and forest die-off from hotter drought in the Anthropocene. Ecosphere, 2015, 6: 1-55
[2] 谢韶青, 卢楚翰. 近16 a来冬季欧亚大陆中纬度地区低温事件频发及其成因. 大气科学学报, 2018, 41(3): 423-432
[3] 郑勤莹, 张国帅, 赵彬清, 等. 不同坡位水曲柳木质部解剖特征及其与气候关系. 应用生态学报, 2021, 32(10): 3428-3436
[4] 朱良军, 李善尧, 王晓春. 基于树木年轮重建伊春1790年以来2—3月最低温度变化. 第四纪研究, 2015, 35(5): 1175-1184
[5] 王恒, 王小雪, 贾建恒, 等. 华北落叶松径向生长对升温突变的响应. 应用生态学报, 2023, 34(10): 2629-2636
[6] Fonti P, von Arx G, Garcia-Gonzalez I, et al. Study in global change through investigation of the plastic responses of xylem anatomy in tree rings. New Phytologist, 2010, 185: 42-53
[7] 徐有明. 木材学. 北京: 中国林业出版社, 2006: 62-64
[8] Naji HR, Nia MF, Kiaei M, et al. Effect of intensive planting density on tree growth, wood density and fiber properties of maple (Acer velutinum Boiss.). Iforest-Biogeosciences and Forestry, 2016, 9: 325-329
[9] 白雨鑫. 东北3种桦木木质部解剖特征对气候变化的响应. 硕士论文. 哈尔滨: 东北林业大学, 2023
[10] 马荟, 陈满菊, 张晨晨, 等. 小兴安岭地区水曲柳纤维解剖特征对低温的响应[EB/OL]. (2025-04-15) [2025-07-25]. 森林工程. http://kns.cnki.net/kcms/detail/23.1388.s.20250415.1053.012.html
[11] 韩晓敏, 延军平. 气候暖干化背景下东北地区旱涝时空演变特征. 水土保持通报, 2015, 35(4): 314-318
[12] 杨康, 徐晓萱, 孙海龙, 等. 修枝强度对水曲柳人工林生长和干形的影响. 东北林业大学学报, 2024, 52(11): 10-16
[13] 汲昌昊, 杨妮, 郭超, 等. 不同针叶树混交对水曲柳吸收根和运输根形态与生物量垂直分布的影响. 东北林业大学学报, 2024, 52(7): 25-30
[14] 杜英军, 李士杰, 王丽, 等. 东北地区帽儿山种源实验林区不同种源水曲柳径向生长对气候的响应. 应用生态学报, 2024, 35(5): 1159-1168
[15] 杜恒文, 叶茂. 塔里木河下游胡杨年轮径向生长对极端低温的响应研究. 生物学杂志, 2020, 37(4): 50-53
[16] 胡义成, 袁玉江, 魏文寿, 等. 用树木年轮重建阿勒泰东部6—7月平均温度序列. 中国沙漠, 2012, 32(4): 1003-1009
[17] Jokanovic D, Cirkovic-Mitrovic T, Jokanovic VN, et al. Wood fibre characteristics of pedunculate oak (Quercus robur L.) growing in different ecological conditions. Drvna Industrija, 2022, 73: 317-325
[18] 闫伯前, 林万众, 刘琪璟, 等. 秦岭鳌山太白红杉径向生长对气候因子的响应. 南京林业大学学报: 自然科学版, 2018, 42(6): 61-67
[19] 靳雨婷. 大兴安岭北部落叶松早晚材的分配特征及气候敏感性. 硕士论文. 沈阳: 沈阳农业大学, 2019
[20] 张乐, 焦亮, 薛儒鸿, 等. 祁连山祁连圆柏年内径向生长对水热因素的响应[EB/OL]. (2025-08-20) [2025-08-25]. 植物生态学报. https://link.cnki.net/urlid/11.3397.Q.20250820.1052.002
[21] 贾汉森, 高峻, 张劲松, 等. 太行山南麓不同径级栓皮栎生长对气候要素及干旱事件的响应. 应用生态学报, 2021, 32(8): 2857-2865
[22] 韦小练, 范泽鑫, Kaewmano A, 等. 热带季节雨林多花白头树年内径向生长动态及其对环境因子的响应. 应用生态学报, 2021, 32(10): 3567-3575
[23] Duan JP, Zhang QB, Lyu LX, et al. Regional-scale winter-spring temperature variability and chilling damage dynamics over the past two centuries in southeastern China. Climate Dynamics, 2012, 39: 919-928
[24] 梁龙玥, 张建军, 李阳, 等. 晋西黄土区油松人工林径向生长对气候变化的响应. 北京林业大学学报, 2025, 47(5): 59-71
[25] 侯鑫源, 史江峰, 李玲玲, 等. 湖北神农架巴山冷杉径向生长对气候的响应. 应用生态学报, 2015, 26(3): 689-696
[26] Pompa-García M, Paredes CJ, FuléP Z. Variation in radial growth of Pinus cooperi in response to climatic signals across an elevational gradient. Dendrochronologia, 2013, 31: 198-204
[27] 梁振满, 李奇, 李金豹, 等. 川西高原青杨径向生长对气候变化的响应[EB/OL]. (2025-08-27) [2025-09-13]. 应用生态学报. https://doi.org/10.13287/j.1001-9332.202510.003
[28] Cai Q, Liu Y. Climatic response of three tree species growing at different elevations in the Lüliang Mountains of northern China. Dendrochronologia, 2013, 31: 311-317
[29] 鲍安, 杨立学, 刘滨辉. 老爷岭红松和胡桃楸径向生长对气候变化的响应. 东北林业大学学报, 2019, 47(12): 16-21
[30] 齐妍, 刘滨辉, 苏远航, 等. 不同径级红松生长对气候变化响应稳定性和极端干旱适应性分析. 森林工程, 2025, 41(4): 691-703
[31] 王晓兵, 李慧, 郜忠川, 等. 核桃青皮多酚对哈密瓜果实采后苯丙烷代谢的影响. 食品科技, 2025, 50(3): 25-30
[32] Oberhuber W, Stumbock M, Kofler W. Climate-tree growth relationships of scots pine stands (Pinus sylvestris L.) expodted to soil dryness. Trees-Structure and Function, 1998, 13: 19-27
[33] 高娜, 李书恒, 白红英, 等. 秦岭牛背梁自然保护区巴山冷杉(Abies fargesii)树轮宽度对气候变化响应的分离效应. 生态学杂志, 2016, 35(8): 2056-2065
[34] Begum S, Kudo K, Rahman MH, et al. Climate change and the regulation of wood formation in trees by temperature. Trees-Structure and Function, 2018, 32: 3-15
[35] Lenz A, Hoch G, Körner C. Early season temperature controls cambial activity and total tree ring width at the alpine treeline. Plant Ecology and Diversity, 2013, 6: 365-375
[36] 刘昊, 刘威帆, 万猛虎, 等. 基于PLUS-InVEST-OPGD模型的宁夏回族自治区碳储量时空演变分析及预测[EB/OL]. (2025-08-22) [2025-08-30]. 环境科学. https://doi.org/10.13227/j.hjkx.202504166
[37] 雷自然, 王欣, 余新晓, 等. 庐山针阔混交林优势种水分利用来源季节变化及对降水的响应. 应用生态学报, 2024, 35(4): 886-896
[38] 李君, 刘泽, 王牌, 等. 西藏珠峰地区乔松径向生长对气候变化的响应. 应用生态学报, 2024, 35(5): 1205-1213
[39] 李钦渊, 周泽圆, 李廷山, 等. 北京百花山华北落叶松天然次生林的资源利用效率生长季动态变化及影响因素. 林业科学, 2025, 61(4): 69-80
[40] 毛晓宁. 高原两种柳树无性系幼苗在干旱和低温胁迫下的生理响应. 硕士论文. 西宁: 青海师范大学, 2024
[41] Heide OM, Prestrud AK. Low temperature, but not photoperiod, controls growth cessation and dormancy induction and release in apple and pear. Tree Physiology, 2005, 25: 109-114