广东主要乡土阔叶树种含年龄和胸径的单木生物量模型

doi:10.11707/j.1001-7488.20190210

摘要/Abstract

摘要： [目的]建立樟树、木荷和枫香3个树种以胸径、年龄为自变量的单木地上生物量模型，为精准估计森林生物量和碳储量变化规律提供理论、实践支撑和技术支持。[方法]基于每个树种按10个径阶均匀分配的90株伐倒木数据（3个树种共270株伐倒木），使用破坏性试验和树干解析分别获取生物量和年龄，采用哑变量方法区分起源，分别建立和比较3个树种不同起源（天然林和人工林）含胸径、年龄和2种常用的含胸径、树高单木地上生物量模型，并通过联立方程组总量控制法解决地上部分各组分（干材、树皮、树枝、树叶）的模型相容性问题。[结果]3个树种3个地上生物量模型修正的确定系数（R_adj²）在0.89~0.94之间，使用含胸径、年龄的生物量模型（1）估计地上生物量是可行的，模型具有良好的估计效果且方便使用。增加哑变量后，3个树种3个地上生物量模型的R_adj²均达0.90以上，模型（4）可以进一步提高模型精度，细化模型应用条件；基于B-D-T的相容性生物量模型系统（7）3个树种树干生物量模型的R_adj²在0.90~0.95之间，树皮生物量模型的R_adj²在0.84~0.94之间，树枝生物量模型的R_adj²在0.73~0.91之间，树叶生物量模型的R_adj²在0.63~0.75之间；构建含有哑变量的B-D-T相容性生物量模型系统（8），树干生物量模型的R_adj²在0.88~0.97之间，树皮生物量模型的R_adj²在0.82~0.93之间，树枝生物量模型的R_adj²在0.84~0.90之间，树叶生物量模型的R_adj²在0.62~0.69之间，表明含胸径、年龄的生物量模型比含胸径、树高的生物量模型效果更好，满足估计需求。[结论]含胸径、年龄的单木地上生物量模型（1）和分起源的单木地上生物量哑变量模型（4）拟合精度均高于2种常用的含胸径、树高的单木地上生物量模型（2）和（3）以及分起源的单木地上生物量模型（5）和（6），含哑变量的非线性联立方程组（8）比B-D-T模型系统（7）精度更高，同时含胸径、年龄的哑变量非线性联立方程组（8）精度指标也优于含胸径、树高的哑变量联立方程组（9）和（10），联立方程组（8）不仅可保证不同起源各分量生物量之间的相容性，还能得到更优化的参数估计。含胸径、年龄的单木生物量模型（1）和考虑起源的地上生物量模型（4）、模型系统（7）中的含胸径、年龄的地上各组分生物量相容性方程组以及考虑起源的地上各组分生物量相容性方程组（8）比2种常用的含胸径、树高的地上生物量模型拟合精度高，实践中更适用于人工阔叶林和碳汇造林项目的碳汇计量、监测和评估。

关键词: 立木年龄, 生物量模型, 哑变量, 联立方程组, 相容性, 起源

Abstract: [Objective] In order to improve the monitoring efficiency and precisely calculate forest carbon sequestration in afforestation projects in Guangdong Province,this study selected major broad-leaved tree species in Guangdong,such as Cinnamomum camphora,Schima superba and Liquidambar formosana,and established aboveground biomass models with age and diameter as independent variables.[Method] All 270 sample trees with 90 sample trees for each tree species were obtained according to 10 diameter classes during the process of modeling,using destructive experiments and stem analysis method to obtain tree biomass and age data.Using the dummy variable method to distinguish the different origins (natural forests and plantations),single tree biomass models with the diameter of breast height (DBH) and age were established for the three species.Also the aboveground biomass components (stem wood and bark,branches,foliage) were established for natural forests and plantations based on dummy variable method.The additivity or compatibility of the components of the aboveground parts was solved by the nonlinear simultaneous equation systems.[Result] The determination coefficients R_adj² of the three above-ground biomass models of the three tree species are between 0.89 and 0.94.It is feasible to use biomass model (1) with DBH and age to estimate tree above-ground biomass.Model (1) has good estimation result and is easy to use.After adding the dummy variable,the three above-ground biomass models R_adj² of the three tree species all reached 0.90 or more.Model (4) can further improve biomass estimate accuracy and refine the model application conditions;for the B-D-T based compatible biomass model system (7) there are good performances in 3 tree species.R_adj² of stem biomass model is between 0.90 and 0.95,R_adj² of bark biomass model is between 0.84 and 0.94,and R_adj² of branch biomass model is between 0.73 and 0.91.The R_adj² of the leaf biomass model is between 0.63 and 0.75,and a compatible B-D-T biomass model system (8) with dummy variables is constructed.The stem biomass equation R_adj² is between 0.88 and 0.97,and the bark biomass equation R_adj² is between 0.82 and 0.93,the branch biomass equation R_adj² is between 0.84 and 0.90,and the leaf biomass equation R_adj² is between 0.62 and 0.69.The result further indicate that the biomass model with DBH and age is more effective than the DBH and tree height biomass models.[Conclusion] This study established the aboveground biomass model with diameter and age for three major native broad-leaved tree species in Guangdong Province.The biomass compatibility model of each component in the aboveground biomass part was established by simultaneous equations.The single tree aboveground biomass model with the DBH and age model (1) have higher fitting accuracy than the commonly used two DBH and height model (2) and (3) and the model (4) with dummy variable also have higher fitting accuracy than model (5) and (6).The precision of nonlinear simultaneous equations (8) with dummy variables is higher than that of model system (7) with B-D-T.Meanwhile,the precision index of the dummy variable simultaneous equations (8) with the DBH and age variable is also better than that of the dummy variables simultaneous equations (9) and (10) with the DBH high variable.The simultaneous equations (8) not only ensure the compatibility between the aboveground biomass of each component,but also obtain more optimal parameter estimates from different origins.The single-wood biomass model with DBH and age (1) and the aboveground biomass model considering the origin (4),the model system (7),the biomass compatibility equations for the above-ground components with the DBH and age,and considerations the above-ground biomass compatibility equations (8) have higher fitting precision than the commonly used above-ground biomass models of DBH and tree height,and are more suitable for artificial broad-leaved forest and carbon sink afforestation projects (arbon sink measurement,monitoring and evaluation) in practice.

Key words: tree age, biomass model, dummy variable, simultaneous system of equations, compatibility, origin

中图分类号:

S784

薛春泉, 徐期瑚, 林丽平, 何潇, 罗勇, 赵菡, 曹磊, 雷渊才. 广东主要乡土阔叶树种含年龄和胸径的单木生物量模型[J]. 林业科学, 2019, 55(2): 97-108.

Xue Chunquan, Xu Qihu, Lin Liping, He Xiao, Luo Yong, Zhao Han, Cao Lei, Lei Yuancai. Biomass Models with Breast Height Diameter and Age for Main Nativetree Species in Guangdong Province[J]. Scientia Silvae Sinicae, 2019, 55(2): 97-108.

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