不同林龄及径级樟子松径向生长对干旱事件的响应

doi:10.13287/j.1001-9332.202411.004

摘要/Abstract

摘要： 为探究樟子松径向生长对干旱事件的响应,以塞罕坝自然保护区不同林龄(30、40年)、不同径级(大径级20～24.9 cm,中径级15～19.9 cm,小径级10～14.9 cm)的樟子松人工林为研究对象,基于树木年轮宽度指数(RWI),分析径向生长与气候因子的相关性,研究其对干旱事件的生态韧性。结果表明: 30年生小径级樟子松RWI与前一年9—12月和当年2月标准化降水蒸发散指数(SPEI)呈显著正相关;30年生大径级和中径级樟子松RWI与前一年9月至当年6月SPEI呈正相关,但不显著。40年生大径级樟子松RWI与前一年10月和当年6月的月均最高温及当年6月均温呈显著负相关;40年生中径级樟子松RWI与前一年10月的月均最高温、月均温呈显著负相关,与当年7月SPEI呈显著正相关;40年生小径级樟子松RWI与前一年9月至当年6月SPEI呈显著正相关。不同林龄樟子松径向生长对4次干旱事件的抵抗力(40年生显著高于30年生)及恢复弹力整体呈显著下降趋势,但恢复力整体呈显著上升趋势(40年生显著低于30年生)。同一林龄不同径级樟子松对干旱事件的响应存在差异。40年生大径级及中径级樟子松对4次干旱事件的抵抗力及恢复弹力均显著高于40年生小径级樟子松,但其恢复力无显著差异;30年生不同径级樟子松对干旱事件的抵抗力、恢复力和恢复弹力均无显著差异。不同林龄及径级的樟子松径向生长受到不同程度的干旱胁迫,其恢复弹力显著下降,40年生樟子松呈现出高抵抗力,而30年生樟子松呈现出高恢复力,小径级樟子松受干旱胁迫最严重。

关键词: 樟子松, 径向生长, 气候因子, 生态韧性, 干旱

Abstract: We explored the differences in the impacts of drought events on Pinus sylvestris var. mongolica of different ages (30 and 40 years) and different diameter classes (large 20-24.9 cm, medium 15-19.9 cm, small 10-14.9 cm) in the Saihanba Nature Reserve. Based on the tree ring width index (RWI), we analyzed the correlation between radial growth and climatic factors and their ecological resilience to drought events. The results showed that the RWI of 30-year-old small-diameter trees was significantly positively correlated with standardized precipitation evapotranspiration index (SPEI) from September to December of the previous year and February of the current year. RWI of 30-year-old large-diameter and medium-diameter trees was correlated with SPEI from September of the previous year to June of the current year, but the correlation was statistically non-significant. The RWI of 40-year-old large-diameter trees was significantly negatively correlated with the maximum mean temperature in October of the previous year and June of the current year, as well as the mean temperature in June of the current year. The RWI of 40-year-old medium-diameter trees was significantly negatively correlated with the maximum mean temperature and mean temperature in October of the previous year and significantly positively correlated with SPEI in July of the current year. The RWI of 40-year-old small-diameter trees was significantly positively correlated with SPEI from September of the previous year to June of the current year. The resistance of radial growth of trees with different ages to four drought events (40 years old significantly higher than 30 years old) and the resilience exhibited a significant downward trend, while the recovery showed a significant upward trend (40 years old significantly lower than 30 years old). Within the same age group, the responses of P. sylvestris var. mongolica with different diameter classes to drought events were different. The resistance and resilience of large and medium diameter classes of 40-year-old trees were significantly higher than those of small diameter class trees, but their recovery showed no significant difference. For 30-year-old trees, there were no significant differences in resistance, recovery, or resilience among different diameter classes. P. sylvestris var. mongolica of different ages and diameter classes experienced varying degrees of drought stress, resulting in a significant decrease in resilience. The 40-year-old trees exhibited high resistance, while the 30-year-old trees showed high recovery capability. Small diameter class trees were most severely affected by drought stress.

Key words: Pinus sylvestris var. mongolica, radial growth, climate factor, ecological resilience, drought

孙昊慷, 韩佳轩, 贾建恒, 张子航, 付立华, 张岩, 郭明明. 不同林龄及径级樟子松径向生长对干旱事件的响应[J]. 应用生态学报, 2024, 35(11): 2942-2950.

SUN Haokang, HAN Jiaxuan, JIA Jianheng, ZHANG Zihang, FU Lihua, ZHANG Yan, GUO Mingming. Radial growth responses of Pinus sylvestris var. mongolica with different stand ages and diameter classes to drought events.[J]. Chinese Journal of Applied Ecology, 2024, 35(11): 2942-2950.

参考文献

[1] 张雅婷, 叶旺敏, 熊德成, 等. 杉木幼树光合特性与生长的季节变化及其对土壤增温的响应. 应用生态学报, 2024, 35(1): 195-202
[2] 苟晓霞, 张同文, 袁玉江, 等. 阿尔泰山主要针叶树种树木径向生长及其对气候变化的响应. 应用生态学报, 2021, 32(10): 3594-3608
[3] IPCC. Climate Change 2022: Mitigation of Climate Change. Working Group Ⅲ Contribution to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge, UK: Cambridge University Press, 2022
[4] Allen CD, Macalady AK, Chenchouni H, et al. A glo-bal overview of drought and heat-induced tree mortality reveals emerging climate change risks for forests. Forest Ecology and Management, 2010, 259: 660-684
[5] 廉泓林, 李卫, 冯金超, 等. 科尔沁沙地典型固沙人工林地土壤水分时空特征及其对环境因子的响应. 生态学报, 2021, 41(20): 8256-8265
[6] 薛世玉, 崔之益, 徐谙为, 等. 海南不同降雨量地区桉树人工林与天然林及其他经济林分植被多样性差异研究. 热带作物学报, 2023, 44(5): 1039-1051
[7] 曹新光, 胡红兵, 李颖俊, 等. 亚热带人工和天然马尾松、杉木林生长对干旱的生态弹性差异. 应用生态学报, 2021, 32(10): 3531-3538
[8] Jiang L, Liu B, Guo H, et al. Assessing vegetation resilience and vulnerability to drought events in Central Asia. Journal of Hydrology, 2024, 634: 131012
[9] Lloret F, Keeling EG, Sala A. Components of tree resilience: Effects of successive low-growth episodes in old ponderosa pine forests. Oikos, 2011, 120: 1909-1920
[10] Wu X, Liu H, Li X, et al. Differentiating drought legacy effects on vegetation growth over the temperate Nor-thern Hemisphere. Global Change Biology, 2018, 24: 504-516
[11] Serra-Maluquer X, Mencuccini M, Martínez-Vilalta J. Changes in tree resistance, recovery and resilience across three successive extreme droughts in the northeast Iberian Peninsula. Oecologia, 2018, 187: 343-354
[12] 丁晓东, 华建春. 气候变化对塞罕坝地区天然华北落叶松径向生长的影响分析. 安徽农学通报, 2022, 28(11): 49-56
[13] 张子航, 王恒, 贾建恒, 等. 不同密度华北落叶松径向生长对干旱事件的响应. 应用生态学报, 2024, 35(5): 1169-1176
[14] 马志远, 高露双, 郭静, 等. TSAP软件和COFECHA软件交叉定年差异研究: 以长白山阔叶红松林优势树种红松为例. 四川农业大学学报, 2014, 32(2): 141-147
[15] 赵守栋, 江源, 焦亮, 等. ARSTAN程序和R语言dplR扩展包进行树轮年表分析的比较研究. 生态学报, 2015, 35(22): 7494-7502
[16] 中华人民共和国国家质量监督检验检疫总局, 中国国家标准化管理委员会. 气象干旱等级(GB/T20481—2017). 北京: 中国标准出版社, 2017
[17] 解萍萍, 张博奕, 董一博, 等. 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, 2023, 34(7): 1779-1786
[18] Briggs DG, Kantavichai R. Effects of thinning on ring mass growth along stem of Douglas fir in four Coastal Pacific Northwest sites. Forest Science, 2018, 64: 139-148
[19] Kunz J, Löffler G, Bauhus J. Minor European broadleaved tree species are more drought-tolerant than Fagus sylvatica but not more tolerant than Quercus petraea. Forest Ecology and Management, 2018, 414: 15-27
[20] 侯德乐, 李金宽, 彭剑峰, 等. 秦岭东缘龙池曼华山松径向生长对多源数据气候因子的响应. 生态学报, 2024, 44(3): 1191-1202
[21] 李镇江, 于晨一, 刘升云, 等. 伏牛山南坡3种针叶树径向生长对气候变化的响应. 应用生态学报, 2023, 34(5): 1178-1186
[22] 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
[23] 王婷, 于丹, 李江风, 等. 树木年轮宽度与气候变化关系研究进展. 植物生态学报, 2003, 27(1): 23-33
[24] Toledo M, Poorter L, Peña-Claros M, et al. Climate is a stronger driver of tree and forest growth rates than soil and disturbance. Journal of Ecology, 2011, 99: 254-264
[25] 任启文, 王玉忠, 徐振华, 等. 基于水量平衡的华北落叶松人工林承载密度研究. 北京林业大学学报, 2024, 46(7): 1-8
[26] 靖娟利, 孙佳荟, 赵婷, 等. 西南地区植被NPP对多尺度气象干旱的响应. 水土保持学报, 2024, 38(3): 335-344
[27] 李祥友, 王兆鹏, 张冬有, 等. 气候因子对塔河樟子松径向生长的边际效应. 安徽农学通报, 2024, 30(5): 56-61
[28] 张晓, 吴梦婉, Kwon S, 等. 不同林龄樟子松人工林径向生长对气候及地下水位变化的响应. 生态学报, 2022, 42(16): 6827-6837
[29] Li JT, Xie YY, Wulan TY, et al. Drought resilience of Mongolian Scotch pine (Pinus sylvestris var. mongolica) at the southernmost edge of its natural distribution: A comparison of natural forests and plantations. Forest Ecology and Management, 2023, 542: 121104
[30] Wang B, Chen T, Li CJ, et al. Radial growth of Qinghai spruce (Picea crassifolia Kom.) and its leading influencing climate factor varied along a moisture gradient. Forest Ecology and Management, 2020, 476: 118474
[31] Phillips NG, Ryan MG, Bond BJ, et al. Reliance on stored water increases with tree size in three species in the Pacific Northwest. Tree Physiology, 2003, 23: 237-245
[32] 申佳艳, 李帅锋, 黄小波, 等. 金沙江流域不同海拔处云南松生态弹性及生长衰退过程. 林业科学, 2020, 56(6): 1-11
[33] Chen M, Zhang X, Li M, et al. Climate-growth pattern of Pinus tabuliformis plantations and their resilience to drought events in the Loess Plateau. Forest Ecology and Management, 2021, 499: 119642
[34] Bennett AC, McDowell NG, Allen CD, et al. Larger trees suffer most during drought in forests worldwide. Nature Plants, 2015, 1: 15139
[35] Rowland L, Da Costa ACL, Galbraith DR, et al. Death from drought in tropical forests is triggered by hydraulics not carbon starvation. Nature, 2015, 528: 119-122
[36] Matusick G, Ruthrof KX, Fontaine JB, et al. Eucalyptus forest shows low structural resistance and resilience to climate change-type drought. Journal of Vegetation Science, 2016, 27: 493-503
[37] 阎弘, 孙滢洁, 周婉莹, 等. 大兴安岭不同纬度兴安落叶松生长对干旱适应性及生长衰退的差异. 生态学报, 2023, 43(10): 3958-3970
[38] Lévesque M, Siegwolf R, Saurer M, et al. Increased water-use efficiency does not lead to enhanced tree growth under xeric and mesic conditions. New Phytologist, 2014, 203: 94-109