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人工油松林不同生长阶段深层土壤有机碳和活性碳的差异及其影响因素
Changes of Organic Carbon and Readily Oxidizable Carbon in Deep Soil at Different Developmental Stages of Artificial Pinus tabulaeformis Plantation and the Impact Factors

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文摘 研究深层土壤碳库动态对了解陆地生态系统深层碳汇潜力、应对全球CO_2升高具有重要意义。论文以黄土丘陵区人工油松林为研究对象,以撂荒地为参照,分析了不同生长阶段的人工油松林地0~200 cm土层土壤有机碳(soil organic carbon,SOC)和活性有机碳(readily oxidizable carbon,ROC)动态变化特征及其影响因素。结果表明:在0~200 cm剖面上,不同生长阶段油松林SOC含量及储量较撂荒地显著提高。浅层(0~100 cm)SOC平均含量,成熟林为撂荒地的2.03倍,提高最大;其次是中龄林,为1.85倍;最后是幼龄林,为1.59倍。深层(100~200 cm)SOC平均含量,幼龄林、中龄林和成熟林分别较撂荒地提高了1.43、1.38和1.36倍。各生长阶段油松林浅层和深层SOC储量分别占0~200 cm SOC储量的61.0%~69.8%和30.2%~39.0%,不同生长阶段间浅层SOC储量差异显著,但深层SOC储量差异不大。浅层ROC储量,幼龄林、中龄林和成熟林依次提高了54.8%、82.0%和91.6%;深层ROC储量依次提高了32.4%、40.9%和58.1%,且深层储量占0~200 cm土层的31.2%~33.3%。不仅浅层SOC和ROC含量受多个因素的影响,而且深层ROC含量也与油松高度、根系生物量以及枯落物厚度、干重呈极显著正相关。因此,人工林建设不仅显著提高浅层SOC和ROC含量,而且对深层土壤的固碳能力有一定改善。
其他语种文摘 It is not clear how plantation affect the soil organic carbon (SOC) in deep soil for terrestrial ecosystem. Based on space for time method, we studied the effect of Pinus tabulaeformis plantations at three developmental stages (young forest, middle age forest and mature forest) on the soil organic carbon (SOC) and soil readily oxidizable carbon (ROC) in 0- 200 cm soil profile. The results showed that SOC content and storage significantly increased in soils with different developmental stages of Pinus tabulaeformis plantation compared with abandoned cropland in 0-200 cm profile. In the 0-100 cm soil layer, average SOC content of mature forest, middle age forest and young forest were 2.03, 1.85 and 1.59 times more than that in abandoned cropland, respectively. SOC storage in shallow and deep soil layers contributed 61.0%-69.8% and 30.2%-39.0% to total SOC storage in the whole profile (0-200 cm) at all of the investigated developmental stages. SOC storage in shallow soil layer varied significantly among different developmental stages, however, no obvious difference of SOC storage in deep soil layer was observed at all developmental stages. Compared to that in abandoned cropland, the ROC storage in soils of young forest, middle age forest and mature forest increased 54.8%, 82.0% and 91.6% in shallow soil layer and 32.4%, 40.9% and 58.1% in deep soil layer, respectively. ROC storage in deep soil layer contributed 31.2%-33.3% to total ROC storage in the whole profile (0-200 cm) at all developmental stages. SOC and ROC content in shallow soil layer were influenced by a number of factors, furthermore, ROC content in deep soil showed significant correlations with the plant height, root biomass, litter thickness and litter biomass. In conclusion, construction of artificial forest may significantly improve the soil carbon pool in both shallow and deep soil profiles.
来源 自然资源学报 ,2016,31(8):1399-1409 【核心库】
DOI 10.11849/zrzyxb.20150917
关键词 活性有机碳 ; 深层土壤 ; 生长阶段 ; 油松林 ; 黄土高原
地址

西北农林科技大学水土保持研究所, 陕西, 杨凌, 712100

语种 中文
文献类型 研究性论文
ISSN 1000-3037
学科 农业基础科学;林业
基金 国家自然科学基金 ;  陕西省自然科学基金重点项目 ;  西北农林科技大学基本科研业务费专项
文献收藏号 CSCD:5778574

参考文献 共 39 共2页

1.  Nair P K R. Soil carbon sequestration in tropical agroforestry systems: A feasibility appraisal. Environmental Science & Policy,2009,12(8):1099-1111 CSCD被引 8    
2.  Mishra U. Tillage effects on soil organic carbon storage and dynamics in Corn Belt of Ohio USA. Soil and Tillage Research,2010,107(2):88-96 CSCD被引 16    
3.  Blair G J. Soil carbon fractions based on their degree of oxidation, and the development of a carbon management index for agricultural systems. Australian Journal of Agricultural Research,1995,46(7):1459-1466 CSCD被引 631    
4.  Biederbeck V O. Labile soil organic matter as influenced by cropping practices in an arid environment. Soil Biology and Biochemistry,1994,26(12):1647-1656 CSCD被引 117    
5.  Whitbread A M. A survey of the impact of cropping on soil physical and chemical properties in northwestern New SouthWales. Soil Research,1998,36(4):669-681 CSCD被引 88    
6.  彭文英. 黄土高原退耕还林(草)紧迫性地域分级论证. 自然资源学报,2002,17(4):438-443 CSCD被引 22    
7.  赖亚飞. 黄土高原丘陵沟壑区退耕还林(草)工程实施综合效益评价——以陕西省吴起县为例. 西北林学院学报,2009,24(3):219-223 CSCD被引 6    
8.  Niu X. Carbon sequestration potential by afforestation of marginal agricultural land in the Midwestern US. Forest Ecology and Management,2006,223(1/3):415-427 CSCD被引 19    
9.  Lal R. Forest soils and carbon sequestration. Forest Ecology and Management,2005,220(1/3):242-258 CSCD被引 209    
10.  薛萐. 黄土丘陵区人工刺槐林土壤活性有机碳与碳库管理指数演变. 中国农业科学,2009,42(4):1458-1464 CSCD被引 31    
11.  佟小刚. 碳库管理指数对退耕还林土壤有机碳库变化的指示作用. 中国环境科学,2013,33(3):466-473 CSCD被引 18    
12.  王春梅. 量化退耕还林后土壤碳变化. 北京林业大学学报,2007,29(3):112-119 CSCD被引 36    
13.  Vieira F C B. Carbon management index based on physical fractionation of soil organic matter in an Acrisol under long-term no-till cropping systems. Soil and Tillage Research,2007,96(1/2):195-204 CSCD被引 35    
14.  周莉. 土壤有机碳的主导影响因子及其研究进展. 地球科学进展,2005,20(1):99-105 CSCD被引 274    
15.  唐克丽. 子午岭林区土壤侵蚀与生态环境关系的研究内容和方法. 中国科学院水利部西北水土保持研究所集刊(土壤侵蚀与生态环境演变研究论文集),1993(1):3-10 CSCD被引 2    
16.  袁可能. 土壤有机矿质复合体研究Ⅰ.土壤有机矿质复合体中腐殖质氧化稳定性的初步研究. 土壤学报,1963,11(3):286-293 CSCD被引 73    
17.  肖瑜. 陕西省不同气候区域油松人工林生物量和生产力的比较研究. 植物生态学与地植物学学报,1990,14(3):237-246 CSCD被引 16    
18.  许文强. 干旱区三工河流域土壤有机碳储量及空间分布特征. 自然资源学报,2009,24(10):1740-1747 CSCD被引 15    
19.  邹俊亮. 小流域土壤有机碳的分布和积累及土壤水分的影响. 自然资源学报,2012,27(3):430-439 CSCD被引 13    
20.  解宪丽. 不同植被下中国土壤有机碳的储量与影响因子. 土壤学报,2004,41(5):687-699 CSCD被引 175    
引证文献 2

1 王忠禹 黄土丘陵区典型植被枯落物坡面分布及混入土壤对土壤性状的影响 自然资源学报,2018,33(11):2020-2031
CSCD被引 6

2 刘新春 晋西黄土区人工林细根与土壤水碳的耦合关系 生态学报,2019,39(21):7987-7995
CSCD被引 9

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