不同年龄阶段华北落叶松人工林生产力对林分密度的响应

doi:10.13287/j.1001-9332.202510.002

摘要/Abstract

摘要： 以塞罕坝机械林场幼龄林、中龄林和成熟林3个不同年龄阶段的华北落叶松人工纯林为研究对象,分别划分为高、中、低3个密度,探究华北落叶松人工林不同年龄阶段的适宜林分密度,分析影响华北落叶松林分生产力的关键因子。结果表明:华北落叶松人工林林分生产力受林龄和林分密度影响显著。幼龄林林分生产力随着密度减小先增大后减小,中密度和低密度林分生产力分别比高密度林分显著提高52.1%与37.2%;中龄林林分生产力随着密度减小而减小,高密度林分生产力分别比中、低密度林分显著提高32.2%与50.0%;在成熟林中,中密度林分生产力最高,分别比高密度和低密度林分显著提高27.1%与75.0%。林分生产力随着林龄的增大呈先增大后减小的趋势。林龄和林分密度的交互作用对林分生产力的影响显著。速效钾、全氮、阳离子交换量、有机碳和水解性氮是影响华北落叶松林分生产力的重要因子。塞罕坝机械林场华北落叶松人工林不同林龄的最优密度范围分别为:幼龄林1800～2100 株·hm^-2、中龄林1500～1700 株·hm^-2、成熟林700～1000 株·hm^-2。

关键词: 华北落叶松, 林龄, 林分密度, 人工林生产力

Abstract: Taking Larix principis-rupprechtii pure plantations of three age classes (young, middle-aged, and mature) and three stand density levels (high, medium, and low) in the Saihanba Mechanical Forest Farm as objects, we explored the optimal stand density across different developmental stages and identified the key factors influencing stand productivity. The results showed that stand productivity of L. principis-rupprechtii was significantly affected by both stand age and stand density. In young stands, stand productivity increased initially and then declined as decreasing stand density. Productivity in medium- and low-density stands was significantly higher than in high-density stands by 52.1% and 37.2%, respectively. In middle-aged stands, productivity declined consistently with decreasing density, with high-density stands outperforming medium- and low-density stands by 32.2% and 50.0%, respectively. In mature stands, medium-density stands showed significantly higher productivity, being 27.1% and 75.0% higher than high- and low-density stands, respectively. The productivity of forest stands tended to increase first and then decrease with the increases of forest age. The interaction between stand age and stand density had a significant effect on productivity. Available potassium, total nitrogen, cation exchange capacity, organic carbon, and hydroly-zable nitrogen were the key factors influencing stand productivity. The optimal stand density ranges for L. principis-rupprechtii plantations at different age classes in Saihanba Mechanical Forest Farm were 1800-2100 trees·hm^-2 for young stands, 1500-1700 trees·hm^-2 for middle-aged stands, and 700-1000 trees·hm^-2 for mature stands.

Key words: Larix principis-rupprechtii, stand age, stand density, productivity of plantation

张子怡, 彭道黎, 陈铭捷. 不同年龄阶段华北落叶松人工林生产力对林分密度的响应[J]. 应用生态学报, 2025, 36(10): 3017-3025.

ZHANG Ziyi, PENG Daoli, CHEN Mingjie. Response of productivity to stand density in Larix principis-rupprechtii plantations at different age stages[J]. Chinese Journal of Applied Ecology, 2025, 36(10): 3017-3025.

参考文献

[1] Zhang LB, Luo ZH, Mallon DP, et al. Biodiversity conservation status in China’s growing protected areas. Biological Conservation, 2017, 210: 89-100
[2] Malhi SS, Brandt SA, Kutcher HR, et al. Effects of broad-leaf crop frequency and fungicide application in various rotations on nitrate nitrogen and extractable phosphorus in a dark brown soil. Communications in Soil Science and Plant Analysis, 2011, 42: 2795-2812
[3] 卢婵江, 温远光, 周晓果, 等. 不同轮伐期对巨尾桉人工林碳固存的影响. 广西科学, 2018, 25(2): 149-157
[4] Kaufmann MR, Ryan MG. Physiographic, stand, and environmental effects on individual tree growth and growth efficiency in subalpine forests. Tree Physiology, 1986, 2: 47-59
[5] 尤文忠, 霍常富, 邢兆凯, 等. 辽宁冰砬山不同年龄落叶松人工林生物量和生产力的研究. 沈阳农业大学学报, 2011, 42(5): 565-569
[6] 赵匡记, 王利东, 王立军, 等. 华北落叶松蓄积量及生产力研究. 北京林业大学学报, 2015, 37(2): 24-31
[7] 丁贵杰, 王鹏程. 马尾松人工林生物量及生产力变化规律研究. Ⅱ. 不同林龄生物量及生产力. 林业科学研究, 2002, 15(1): 54-60
[8] 肖兴翠, 李志辉, 唐作钧, 等. 林分密度对湿地松人工林养分循环速率和利用效率的影响. 生态学杂志, 2013, 32(11): 2871-2880
[9] 董雪婷, 张静, 张志东, 等. 树种相互作用、林分密度和树木大小对华北落叶松生产力的影响. 应用生态学报, 2021, 32(8): 2722-2728
[10] 商添雄 ,韩海荣, 程小琴, 等. 华北落叶松人工林生长对抚育间伐的响应及其与土壤因子的关系. 林业科学研究, 2019, 32(6): 40-47
[11] Duursma RA, Marshall JD, Robinson AP, et al. Description and test of a simple process-based model of forest growth for mixed-species stands. Ecological Modelling, 2007, 203: 297-311
[12] 常伟强. 塞罕坝机械林场森林资源动态变化分析. 林业资源管理, 2018(6): 13-17
[13] 商添雄, 韩海荣, 程小琴, 等. 华北落叶松人工林生长对抚育间伐的响应及其与土壤因子的关系. 林业科学研究, 2019, 32(6): 40-47
[14] 王剑武, 徐森, 季碧勇, 等. 地形和林分空间结构对浙江省天然阔叶混交林主要先锋树种胸径生长的影响. 应用生态学报, 2024, 35(2): 298-306
[15] 常伟强. 塞罕坝生态建设历程与可持续经营作业法. 安徽农学通报, 2018, 24(20): 6-9
[16] 赵娱, 张菲, 许中旗, 等. 塞罕坝地区樟子松生长过程研究. 林业资源管理, 2017(5): 39-44
[17] Liu TR, Peng DL, Tan ZJ, et al. Do stand density and month regulate soil enzymes and the stoichiometry of differently aged Larix principis-rupprechtii plantations? Catena, 2023, 220, 106683
[18] 惠刚盈. 角尺度——一个描述林木个体分布格局的结构参数. 林业科学, 1999, 35(1): 39-44
[19] 惠刚盈. 一个新的林分空间结构参数——大小比数. 林业科学研究, 1999, 12(1): 4-9
[20] Hui GY, Zhang GG, Zhao ZH, et al. Methods of forest structure research: A review. Current Forestry Reports, 2019, 5: 142-154
[21] 胡艳波, 惠刚盈. 基于相邻木关系的林木密集程度表达方式研究. 北京林业大学学报, 2015, 37(9): 1-8
[22] 惠刚盈, 胡艳波, 赵中华, 等. 基于交角的林木竞争指数. 林业科学, 2013, 49(6): 68-73
[23] 惠刚盈, 张连金, 胡艳波, 等. 林分拥挤度及其应用. 北京林业大学学报, 2016, 38(10): 1-6
[24] 鲍士旦. 土壤农化分析. 北京: 中国农业出版社, 2000
[25] 亢新刚. 森林经理学. 北京: 中国林业出版社, 2011
[26] 全国森林资源标准化技术委员会 (SAC/TC 370). 主要树种立木生物量模型与碳计量参数: GB/T 43648—2024. 北京: 中国标准出版社, 2024
[27] 于世川, 张文辉, 尤健健, 等. 抚育间伐对黄龙山辽东栎林木形质的影响. 林业科学, 2017, 53(11): 104-113
[28] Bradford JB, Palik BJ. Comparison of thinning methods in red pine: Consequences for stand-level growth and tree diameter. Canadian Journal of Forest Research, 2009, 39: 489-496
[29] 易冠明, 李万年, 唐希远, 等. 林分密度和起源对不同年龄序列巨尾桉人工林生长及生产力的影响. 北华大学学报: 自然科学版, 2023, 24(3): 376-386
[30] 杨桂娟, 胡海帆, 孙洪刚, 等. 林分年龄、造林密度和林分自然稀疏对杉木人工林个体大小分化和生产力关系的影响. 林业科学, 2019, 55(11): 126-136
[31] 卫舒平, 梁文俊, 魏曦, 等. 不同密度华北落叶松林天然更新及其影响因子. 应用生态学报, 2022, 33(10): 2687-2694
[32] 张煜林, 刘玲娟, 刘胜龙, 等. 不同密度杉木萌生林自然恢复初期群落结构对生态系统碳密度的影响. 应用生态学报, 2024, 35(2): 289-297
[33] Zeide B. Thinning and growth: A full turnaround. Journal of Forestry, 2001, 99: 20-25
[34] 谭政, 王乾, 罗之恒, 等. 密度调控对马尾松中近熟人工林生产力和生物量的影响. 安徽农学通报, 2022, 28(7): 70-75
[35] 吴建强, 王懿祥, 杨峪, 等. 基于GIS技术的林木竞争指数计算系统的设计与开发. 西北林学院学报, 2014, 29(4): 175-181
[36] 李旭华, 于大炮, 代力民, 等. 长白山阔叶红松林生产力随林分发育的变化. 应用生态学报, 2020, 31(3): 706-716
[37] Elser JJ, Sterner RW, Gorokhova E, et al. Biological stoichiometry from genes to ecosystems. Ecology Letters, 2000, 3: 540-550
[38] Finzi AC, Canham CD. Sapling growth in response to light and nitrogen availability in a southern new England forest. Forest Ecology and Management, 2000, 131: 153-165
[39] Paoli GD, Curran LM, Slik JWF. Soil nutrients affect spatial patterns of aboveground biomass and emergent tree density in southwestern Borneo. Oecologia, 2008, 155: 287-299
[40] Luyssaert S, Schulze ED, Börner A, et al. Old-growth forests as global carbon sinks. Nature, 2008, 455: 213-215
[41] 郭晓睿, 宋涛, 邓丽娟, 等. 果园生草对中国果园土壤肥力和生产力影响的整合分析. 应用生态学报, 2021, 32(11): 4021-4028
[42] 樊星火, 葛红艳, 张参参, 等. 江西省生态公益林典型林分土壤肥力状况研究. 北京林业大学学报, 2018, 40(11): 84-92
[43] 张萌, 范秀华, 岳庆敏, 等. 吉林蛟河针阔混交林生物与非生物因素对生产力的影响. 林业科学, 2023, 59(12): 71-77
[44] 李军, 王永明, 陈波, 等. 华北落叶松人工林短周期间伐与林分生产力的关系. 中国水土保持科学, 2012, 10(5): 90-93
[45] 颜培栋, 李鹏, 杨章旗, 等. 不同造林密度马尾松人工林分化特征及其对生产力的影响. 林业科学, 2023, 59(10): 66-75
[46] 李春波, 张园, 刘雅各, 等. 长白山自然保护区总初级生产力时空变化特征及其影响因素. 应用生态学报, 2023, 34(5): 1341-1348