甘肃黄土丘陵区侧柏人工幼林的碳密度及分配特征

摘要/Abstract

摘要： [目的] 以甘肃黄土丘陵区宁县人工林地为研究区,探讨侧柏人工林碳密度及其分配特征,为黄土丘陵区人工林生态效益评估提供理论依据。[方法] 以不同林龄侧柏人工林(7,10,12和14年生)为研究对象,每个林龄分别设置3块样地,分乔木层、灌木层、草本层和枯落物层进行调查取样,然后在每块样地采集0~100 cm土层的土样,用元素分析仪LiquiTOCⅡ测定植物和土壤碳含量,研究甘肃黄土丘陵区侧柏人工幼林的碳含量、碳密度及其分配特征。[结果] 侧柏不同器官碳含量为447.51~513.93 g·kg^-1,表现为果实>树叶>树干>粗枝>细枝>细根>根桩>树皮>粗根>大根>中根>小根; 灌木层和草本层均以根的碳含量最低,枯落物层未分解层碳含量高于半分解层,且各组分碳含量差异显著; 土壤层(0~100 cm)碳含量为23.31~96.08 g·kg^-1,且随林龄增加而增大,随土壤深度增加而下降; 侧柏人工林生态系统中,乔木层碳密度占植被层碳密度比例最大,高于灌木层、草本层和枯落物层; 0~100 cm土层土壤碳密度占整个生态系统碳密度比例最大,且随着林龄增加而增大,且差异显著; 7,10,12和14年生侧柏人工幼林生态系统碳密度分别为37.56,44.67,50.87和56.34 t·hm^-2,乔木层、林下植被层、枯落物层和土壤层的碳密度均随林龄增加而增大。[结论] 黄土丘陵区7,10,12和14年生侧柏人工幼林的乔木层不同器官碳含量差异显著(P<0.05),相同器官碳含量差异不显著(P>0.05); 侧柏人工林生态系统碳库表现为土壤层>乔木层>草本层>枯落物层>灌木层; 侧柏人工林各层的碳密度都随林龄增加而增大; 乔木层、灌木层、草本层和枯落物层碳密度分配比例随林龄增加而增大,而土壤层碳密度比例随林龄增加而减少。

关键词: 侧柏, 人工林, 林龄, 碳密度, 碳密度组分, 甘肃黄土丘陵区

Abstract: [Objective] The purpose of this paper is to explore carbon density and its allocation in young plantation of Platycladus orientalis at different ages using hilly loess in Ning County of Gansu Province as the study area, with an expectation to provide the theoretical basis for evaluation on the ecological benefit of artificial forest in the hilly Loess Plateau.[Method] P. orientalis plantation at different ages of 7, 10, 12 and 14 years were used for this study. Three sample-plots were set up for every stand age, then samples were individually taken from tree, shrub, herb and litter layers, and soil was sampled at a depth of 0-100 cm in each plot. The carbon contents of plant and soil samples were determined by using elemental analyzer Liqui TOCⅡ, the carbon density and its allocation were analyzed in young plantations of P. orientalis in the hilly Loess Plateau in Gansu Province. [Result] The results showed that the carbon content in different organs of P. orientalis ranged from 447.51 to 513.93 g·kg^-1, with an order of cone > leaf > stem > thick-branch > fine-branch > fine-root > stump > bark > thick-root > large-root > medium-root > small-root. The carbon content of root was the lowest in shrub and herb layers, and the carbon content of un-decomposed layer in litter was higher than that of semi-decomposed layer. Significant difference in carbon content was observed among different layers of the ecology system of P.orientalis plantation at different ages. The carbon content in the soil layer (0-100 cm) ranged from 23.31 to 96.08 g·kg^-1, and increased with the increase of stand age but decreased with the increase of soil depth. The carbon density of the tree layer in the vegetation was higher than that of shrub, herb and litter layers. The carbon density in 0-100 cm soil layer was the largest in the ecosystem, showing significant difference with the increase of age. The carbon densities in the ecosystem of P. orientalis plantation at ages of 7, 10, 12 and 14 years were 37.56, 44.67, 50.87and 56.34 t·hm^-2, respectively. All the carbon densities in tree, shrub, herb, humus , and soil layer increased with the increase of stand age. [Conclusion] The carbon content of tree layer of P. orientalis plantation showed significant(P<0.05)difference among organs of the trees, but no significant difference was observed for the same organ at different ages(P>0.05). Carbon stocks in different layers of the P. orientalis plantation ecosystems were found in the order of soil>tree>herb>litter>shrub. The carbon density of different layers of P. orientalis plantation increased with the increase of age, and the proportion of carbon distribution of tree, shrub, herb, and litter layers increased while that of soil layer decreased with increase of stand ages.

Key words: Platycladus orientalis, plantation, stand age, carbon density, carbon density components, the hilly loess region in Gansu Province

中图分类号:

S718.5

李彦华, 张文辉, 申家朋, 周建云, 郭有燕. 甘肃黄土丘陵区侧柏人工幼林的碳密度及分配特征[J]. 林业科学, 2015, 51(6): 1-8.

Li Yanhua, Zhang Wenhui, Shen Jiapeng, Zhou Jianyun, Guo Youyan. Carbon Density and Its Allocation Characteristics of Young Plantation of Platycladus orientalis in the Hilly Loess Region of Gansu Province, China[J]. Scientia Silvae Sinicae, 2015, 51(6): 1-8.

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