天目山针阔混交林结构与碳储量的关系

doi:10.13287/j.1001-9332.202308.015

摘要/Abstract

摘要： 以浙江天目山国家级自然保护区针阔混交林为研究对象,将树种分成常绿树种与落叶树种、阔叶树种与针叶树种、优势树种与非优势树种3对树种组,分析每对树种组的单木碳储量差异、碳储量的直径分布和树高分布规律,应用V_Hegyi竞争指数、全混交度和聚集指数分析空间结构与单木碳储量的关系,旨在揭示针阔混交林结构与碳储量的关系,为森林固碳增汇经营提供科学依据。结果表明: 常绿树种和落叶树种、阔叶树种和针叶树种、优势树种和非优势树种的平均单木碳储量分别为57.7和87.4 kg、54.6和74.7 kg、67.4和48.1 kg,常绿树种单木碳储量显著低于落叶树种,阔叶树种单木碳储量显著低于针叶树种,优势树种单木碳储量显著高于非优势树种。各树种组的碳储量直径分布和树高分布均服从正态分布;单木碳储量与V_Hegyi竞争指数呈显著负相关,且符合幂函数分布;单木碳储量与全混交度和聚集指数均呈显著正相关,且均符合线性函数关系,不同空间结构对单木碳储量的影响方向均具有一致性。针阔混交林结构对单木碳储量具有显著影响,在森林固碳增汇经营中,应调控不合理的森林结构,促进其向顶极群落演替,以提高森林碳储量。

关键词: 天目山, 针阔混交林, 森林结构, 碳储量

Abstract: Taking the coniferous and broad-leaved mixed forest of Tianmu Mountain National Nature Reserve in Zhejiang Province as research object, we divided the tree species into three pairs, including evergreen and deci-duous species, broad-leaved and coniferous species, dominant and non-dominant species, to compare the difference of the individual tree carbon stock of each pair and analyze the diameter distribution pattern and tree height distribution pattern of carbon stocks. The relationship between spatial structure and individual tree carbon stock was analyzed by using spatial structure indicators including V_Hegyi competition index, complete mingling and aggregation index, to reveal the relationship between the structure of coniferous and broad-leaved forests and carbon stocks, and provide a theoretical basis for management of forest carbon sequestration. The results showed that the average individual carbon stock for evergreen and deciduous species, broad-leaved and coniferous species, dominant and non-dominant species were 57.7 and 87.4 kg, 54.6 and 74.7 kg, 67.4 and 48.1 kg, respectively. The individual tree carbon stock of evergreen species was significantly lower than that of deciduous species, the individual tree carbon stock of broad-leaved species was significantly lower than that of coniferous species, and the individual tree carbon stock of dominant tree species was significantly higher than that of non-dominant tree species. The diameter distribution and height distribution of carbon stock of each species group obeyed normal distribution. The V_Hegyi competition index was significantly negatively correlated with individual tree carbon stock, and it was consistent with the power function distribution. Both complete mingling and aggregation index were linearly and positively correlated with individual tree carbon stock. The direction of influence of different spatial structures on the individual tree carbon stock was consistent. The structure of coniferous and broad-leaved mixed forest had a significant impact on individual tree carbon stock. In the management of forest carbon sequestration and sink enhancement, it is necessary to regulate the unreasonable forest structure and promote its succession to the climax community in order to improve forest carbon stock.

Key words: Tianmu Mountains, coniferous and broad-leaved mixed forest, forest structure, carbon stock.

吴登瑜, 窦啸文, 汤孟平. 天目山针阔混交林结构与碳储量的关系[J]. 应用生态学报, 2023, 34(8): 2029-2038.

WU Dengyu, DOU Xiaowen, TANG Mengping. Relationship between carbon stock and the structure of coniferous and broad-leaved mixed forest in Tianmu Mountains, China[J]. Chinese Journal of Applied Ecology, 2023, 34(8): 2029-2038.

参考文献

[1] Sun W, Huang CC. Predictions of carbon emission intensity based on factor analysis and an improved extreme learning machine from the perspective of carbon emission efficiency. Journal of Cleaner Production, 2022, 338: 130414
[2] Dixon RK, Solomon AM, Brown S, et al. Carbon pools and flux of global forest ecosystems. Science, 1994, 263: 185-190
[3] Fang JY, Guo ZD, Hu HF, et al. Forest biomass carbon sinks in East Asia, with special reference to the relative contributions of forest expansion and forest growth. Glo-bal Change Biology, 2014, 20: 2019-2030
[4] Nguyen HH, Uria-Diez J, Wiegand K. Spatial distribution and association patterns in a tropical evergreen broad-leaved forest of north-central Vietnam. Journal of Vegetation Science, 2016, 27: 318-327
[5] Aguirre O, Hui GY, Gadow KV, et al. An analysis of spatial forest structure using neighbourhood-based variables. Forest Ecology and Management, 2003, 183: 137-145
[6] 汤孟平, 唐守正, 雷相东, 等. 林分择伐空间结构优化模型研究. 林业科学, 2004, 40(5): 25-31
[7] 汤孟平, 唐守正, 雷相东, 等. 两种混交度的比较分析. 林业资源管理, 2004(4): 25-27
[8] 汤孟平. 森林空间经营理论与实践. 北京: 中国林业出版社, 2007
[9] Pretzsch H. Analysis and modeling of spatial stand structures. Methodological considerations based on mixed beech-larch stands in Lower Saxony. Forest Ecology and Management, 1997, 97: 237-253
[10] 胡艳波, 惠刚盈. 优化林分空间结构的森林经营方法探讨. 林业科学研究, 2006, 19(1): 1-8
[11] Liu N, Wang DW, Guo QX. Exploring the influence of large trees on temperate forest spatial structure from the angle of mingling. Forest Ecology and Management, 2021, 492: 119220
[12] 黎芳, 潘萍, 臧颢, 等. 赣南马尾松林分多功能经营空间结构优化模型研究. 西南林业大学学报: 自然科学, 2017, 37(6): 141-147
[13] Verly MO, Leite VR, Tavares-Junior daSI, et al. Atlantic forest woody carbon stock estimation for different successional stages using Sentinel-2 data. Ecological Indicators, 2023, 146: 109870
[14] 刘兆丹, 李斌, 方晰, 等. 湖南省森林植被碳储量、碳密度动态特征. 生态学报, 2016, 36(21): 6897-6908
[15] 刘凡胜, 韦明宝, 莫少壮, 等. 广西南丹县秃杉人工林碳储量及其分布格局. 安徽农业科学, 2022, 50(6): 98-100
[16] 雷海清, 孙高球, 郑得利. 温州市森林生态系统碳储量研究. 南京林业大学学报: 自然科学版, 2022, 46(5): 20-26
[17] 郑瞳, 牟长城, 张毅, 等. 立地类型对张广才岭天然白桦林生态系统碳储量的影响. 生态学报, 2016, 36(19): 6284-6294
[18] Arasa-Gisbert R, Vayreda J, Román-Cuesta RM, et al. Forest diversity plays a key role in determining the stand carbon stocks of Mexican forests. Forest Ecology and Management, 2018, 415-416: 160-171
[19] 程然然, 关晋宏, 张建国, 等. 甘肃省5种典型人工林生态系统固碳现状与潜力. 应用生态学报, 2017, 28(4): 1112-1120
[20] 韩福利, 田相林, 党坤良, 等. 抚育间伐对桥山林区油松林乔木层碳储量的影响. 西北林学院学报, 2015, 30(4): 184-191
[21] Zhu YH, Zhao BQ, Zhu ZT, et al. The effects of crop tree thinning intensity on the ability of dominant tree species to sequester carbon in a temperate deciduous mixed forest, northeastern China. Forest Ecology and Management, 2022, 505: 119893
[22] 王霓虹, 高萌, 李丹. 长白落叶松人工林乔木层生物量分布特征及其固碳能力研究. 植物研究, 2014, 34(4): 554-560
[23] 夏艳菊, 张静, 邹顺, 等. 南亚热带森林群落演替过程中结构多样性与碳储量的变化. 生态环境学报, 2018, 27(3): 424-431
[24] 徐建. 天目山针阔混交林竞争及其碳储量效应研究. 硕士论文. 浙江临安: 浙江农林大学, 2014
[25] 王敬. 天目山针阔混交林林木碳储量空间分布特征研究. 硕士论文. 浙江临安: 浙江农林大学, 2014
[26] 汤孟平, 周国模, 施拥军, 等. 天目山常绿阔叶林优势种群及其空间分布格局. 植物生态学报, 2006, 30(5): 743-752
[27] 张毅锋, 汤孟平. 天目山常绿阔叶林空间结构动态变化特征. 生态学报, 2021, 41(5): 1959-1969
[28] 周红敏, 惠刚盈, 赵中华, 等. 林分空间结构分析中样地边界木的处理方法. 林业科学, 2009, 45(2): 1-5
[29] 惠刚盈, 胡艳波. 混交林树种空间隔离程度表达方式的研究. 林业科学研究, 2001, 14(1): 23-27
[30] 汤孟平, 陈永刚, 施拥军, 等. 基于Voronoi图的群落优势树种种内种间竞争. 生态学报, 2007, 27(11): 4707-4716
[31] 孙儒泳. 基础生态学. 北京: 高等教育出版社, 2001
[32] Ohsawa M. Differentiation of vegetation zones and species strategies in the subalpine region of Mt. Fuji. Vegetaio, 1984, 57: 15-52
[33] Clark PJ, Evans FC. Distances to nearest neighbor as a measure of spatial relationships in populations. Ecology, 1984, 35: 445-453
[34] 汤孟平, 娄明华, 陈永刚, 等. 不同混交度指数的比较分析. 林业科学, 2012, 48(8): 46-53
[35] Hegyi F. A simulation model for managing jack-pine stands// Fries J, ed. Growth Models for Tree and Stand Simulation. Stockholm: Royal College of Forestry, 1974: 74-90
[36] 袁位高, 江波, 葛永金, 等. 浙江省重点公益林生物量模型研究. 浙江林业科技, 2009, 29(2): 1-5
[37] 陶吉兴. 浙江森林碳汇功能监测. 北京: 中国林业出版社, 2014: 260
[38] 刘申, 罗艳, 黄钰辉, 等. 鼎湖山五种植被类型群落生物量及其径级分配特征. 生态科学, 2007, 26(5): 387-393
[39] 郭纯子, 吴洋洋, 倪健. 天童国家森林公园植被碳储量估算. 应用生态学报, 2014, 25(11): 3099-3109
[40] 李黎立. 北京松山自然保护区次生林主要乔木地上碳储量及其分布. 安徽农业科学, 2014, 42(5): 1417-1420
[41] 徐明锋, 苏永新, 龚益广, 等. 粤西桉阔林乔木层碳密度及其影响因子研究. 林业与环境科学, 2022, 38(1): 1-8
[42] 唐旭利, 周国逸, 温达志, 等. 鼎湖山南亚热带季风常绿阔叶林C贮量分布. 生态学报, 2003, 23(1): 90-97
[43] 田惠玲, 周平, 贾朋, 等. 粤北不同经营措施对人工林年均固碳量的影响. 生态科学, 2018, 37(4): 211-217
[44] 温远光, 张祖峰, 周晓果, 等. 珍贵乡土树种与桉树混交对生态系统生物量和碳储量的影响. 广西科学, 2020, 27(2): 111-119
[45] 李勇. 混交比例对杉木木荷混交林生物量及碳储量的影响. 林业勘察设计, 2016, 36(3): 37-40
[46] 叶鹏, 汤孟平. 基于GIS的常绿阔叶林郁闭度与树冠重叠度分析. 林业资源管理, 2021(5): 70-79