山西暖性草地碳密度分布特征及其区域差异

doi:10.11733/j.issn.1007-0435.2019.06.025

草地学报 ›› 2019, Vol. 27 ›› Issue (6): 1667-1676.DOI: 10.11733/j.issn.1007-0435.2019.06.025

山西暖性草地碳密度分布特征及其区域差异

邢鹏飞, 李刚, 赵祥, 董宽虎

山西农业大学动物科技学院, 山西太谷 030801

收稿日期:2019-06-25 修回日期:2019-09-18 出版日期:2019-12-15 发布日期:2019-12-31
通讯作者: 赵祥,E-mail:sxndzhaox@126.com
作者简介:邢鹏飞(1994-),男,汉,山西高平人,硕士研究生,主要从事草地生态与管理研究,E-mail:sxpfxing@163.com
基金资助:
国家自然科学基金（31870438）；山西省优秀人才创新项目（201805D211018）资助

Distribution Characteristics of Carbon Density in Warm-temperate Grassland and its Regional Difference in Shanxi

XING Peng-fei, LI Gang, ZHAO Xiang, DONG Kuan-hu

College of Animal Science and Veterinary Medicine, Shanxi Agricultural University, Taigu, Shanxi Province 030801, China

Received:2019-06-25 Revised:2019-09-18 Online:2019-12-15 Published:2019-12-31

摘要/Abstract

摘要： 山西省草地是我国草地碳储量精确估测中不可忽视的部分。为探究山西省暖性草地生态系统碳密度的区域差异，本研究调查和测定了该省2个气候区（晋东南半湿润区，晋西北半干旱区）暖性草地群落特征和生态系统碳密度。结果表明：不同气候区的环境差异影响了草地植物物种多样性、生物量积累和土壤碳输入，造成2个气候区碳密度分异的主要环境因子为降水量和土壤有机碳含量；晋西北平均植物多样性指数略高于晋东南；晋西北和晋东南平均地上生物量分别为384.28 g·m^-2，522.83 g·m^-2，平均地下生物量分别为1 411.02 g·m^-2，1 643.81 g·m^-2，晋西北均低于晋东南；平均生态系统碳密度分别为7 911.48 g·m^-2，9 080.43 g·m^-2；其中植被地上部分、根系和土壤碳密度占比分别为1.4%~2.1%，12.3%~24.7%，73.6%~85.9%；晋东南地区暖性灌草丛类草地生态系统碳密度最大，为10 102.23 g·m^-2。

关键词: 山西省暖性草地, 碳密度, 区域差异

Abstract: Grassland in Shanxi Province is an important part in the accurate estimation of grassland carbon reserves in China. By investigating and measuring the community characteristics and carbon density of warm-temperate grassland in two climatic regions of Shanxi (including the semi-arid area in northwest Shanxi and the semi-humid area in southeast Shanxi),the regional differences of ecosystem carbon density of warm-temperate grassland in Shanxi were analyzed. The results showed that the environmental differences in different climatic regions affected the diversity of grassland plants,biomass accumulation and soil carbon input,and the main environmental factors causing the difference of carbon density in the two climatic regions were precipitation and soil organic carbon content. The average plant diversity index of northwest Shanxi was slightly higher than that in southeast Shanxi. The average aboveground biomass of northwest and southeast regions were 384.28 g·m^-2 and 522.83 g·m^-2,respectively,and the average belowground biomass were 1 411.02 g·m^-2 and 1643.81 g·m^-2,respectively,both of which were lower in the region of northwest than that in southeast Shanxi. The average carbon densities of ecosystems were 7 911.48 g·m^-2 and 9 080.43 g·m^-2 in northwest and southeast regions,respectively. The proportions of vegetation,root system and soil carbon density were 1.4%~2.1%,12.3%~24.7% and 73.6%~85.9%,respectively. The carbon density of the warm temperate shrub-tussock ecosystem in southeast Shanxi was the highest,at 10 102.23 g·m^-2.

Key words: Warm-temperate grassland, Carbon density, Regional difference

中图分类号:

S812

邢鹏飞, 李刚, 赵祥, 董宽虎. 山西暖性草地碳密度分布特征及其区域差异[J]. 草地学报, 2019, 27(6): 1667-1676.

XING Peng-fei, LI Gang, ZHAO Xiang, DONG Kuan-hu. Distribution Characteristics of Carbon Density in Warm-temperate Grassland and its Regional Difference in Shanxi[J]. Acta Agrestia Sinica, 2019, 27(6): 1667-1676.

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参考文献

[1] Scurlock J M O,Johnson K,Olson R J. Estimating Net Primary Productivity from Grassland Biomass Dynamics Measurements[J]. Global Change Biology,2002,8(8):736-753
[2] Schuma G E,Janzen H H,Herrick J E. Soil carbon dynamics and potential carbon sequestration by rangelands[J]. Environmental Pollution,2002,116(3):391-396
[3] 赵威,李琳. 不同草地利用方式对暖性(灌)草丛类草地固碳能力的影响[J]. 草业学报,2018,27(11):1-14
[4] Fan J,Zhong H,Harris W,et al. Carbon storage in the grasslands of China based on field measurements of above- and below-ground biomass[J]. Climatic Change,2008,86(3-4):375-396
[5] 方精云,杨元合,马文红,等. 中国草地生态系统碳库及其变化[J]. 中国科学:生命科学,2010(7):566-576
[6] 王穗子,樊江文,刘帅. 中国草地碳库估算差异性综合分析[J]. 草地学报,2017,25(5):905-913
[7] 赵威,李琳,王艳杰,等. 河南典型暖(热)性草地固碳特征及区域差异[J]. 应用生态学报,2018,29(06):1867-1875
[8] 高添,徐斌,杨秀春,等. 青藏高原草地生态系统生物量碳库研究进展[J]. 地理科学进展,2012,31(12):1724-1731
[9] Hsu J S,Powell J,Adler P B. Sensitivity of mean annual primary production to precipitation[J]. Global Change Biology,2012,18(7):2246-2255
[10] 高东,何霞红. 生物多样性与生态系统稳定性研究进展[J]. 生态学杂志,1970,29(12):2507-2513
[11] 熊定鹏,赵广帅,武建双,等. 羌塘高寒草地物种多样性与生态系统多功能关系格局[J]. 生态学报,2016,36(11):3362-3371
[12] 江世高. 贺兰山西坡不同草地类型土壤碳特征及固碳潜力[D]. 兰州:兰州大学,2014,16-19
[13] 查向浩,王玉洁,李有文,等. 草地土壤碳密度研究进展[J]. 北方园艺,2019,(09):159-163
[14] 方精云,刘国华,徐嵩龄.我国森林植被的生物量和净生产量[J]. 生态学报,1996,16(05):497-508
[15] 高树琴,赵霞,方精云. 我国草地的固碳功能[J].中国工程科学,2016,18(01):73-79
[16] 沈海花,朱言坤,赵霞,等.中国草地资源的现状分析[J].科学通报,2016,61(02):139-154
[17] 李瑞华,李晓兵,牛海鹏,等.内蒙古典型草原区土壤氮储量分布研究[J]. 干旱区资源与环境,2017,31(11):110-115
[18] 李建平,谢应忠.封育对黄土高原天然草地深层土壤碳、氮储量的影响[J]. 草业科学,2016,33(10):1981-1988
[19] 徐丽,于贵瑞,何念鹏. 1980s-2010s中国陆地生态系统土壤碳储量的变化(英文)[J]. Journal of Geographical Sciences,2019,29(01):49-66
[20] 朴世龙,方精云,贺金生,等. 中国草地植被生物量及其空间分布格局[J].植物生态学报,2004,(04):491-498.
[21] 张智袁,李刚,张宾宾,等.山西典型天然草地碳分布特征及碳储量估算[J]. 草地学报,2017,25(01):69-75
[22] Zhang X,Liu M,Zhao X,et al. Topography and grazing effects on storage of soil organic carbon and nitrogen in the northern China grasslands[J]. Ecological Indicators,2018,93:45-53
[23] 陈二萍. 山西省地面流场的气候特征及其与地形的关系[A]. 中国环境科学学会.2016中国环境科学学会学术年会论文集(第三卷)[C]. 中国环境科学学会:中国环境科学学会,2016:5
[24] 刘伟,程积民,陈芙蓉,等. 黄土高原中部草地土壤有机碳密度特征及碳储量[J]. 草地学报,2011,19(03):425-431
[25] 左小安,赵学勇,赵哈林,等.科尔沁沙质草地群落物种多样性、生产力与土壤特性的关系[J].环境科学,2007(05):945-951
[26] Long W,Yang X,Li D. Patterns of species diversity and soil nutrients along a chrono sequence of vegetation recovery in Hainan Island,South China[J]. Ecological Research,2012,27(03):561-568
[27] Perroni Ventura Y,Montana C,Garcia Oliva F. Relationship between soil nutrient availability and plant species richness in a tropical semi-arid environment[J]. Journal of Vegetation Science,2006,17(06):719-728
[28] Abramsky Z,Rosenzweig M L. Tilman's predicted productivity-diversity relationship shown by desert rodents[J]. Nature,1984,309(5964):150-151
[29] 樊江文,钟华平. 内蒙古草地样带植物群落生物量的梯度研究[J]. 植物生态学报,2006,30(04):553-562
[30] Kang M Y,Dai C,Ji W Y,et al. Biomass and its allocation in relation to temperature,precipitation,and soil nutrients in Inner Mongolia grasslands,China.[J]. Plos one,2013,8(07):e69561
[31] 孙小丽. 气候因子和土壤养分对荒漠草原物种多样性、生产力及其关系的影响[D]. 呼和浩特:内蒙古大学,2015:13-19
[32] 杨元武,周华坤,李希来,等. 高寒草甸物种多样性和生产力对养分添加的初期响应[J]. 西北农业学报,2017,26(02):159-166
[33] 贺星. 养分添加对内蒙古草原生物量和多样性的影响[D]. 呼和浩特:内蒙古大学,2014:33-34
[34] 吴会峰,王菁菁,宋丽娟,李刚,吴水娟,郝文芳.不同立地铁杆蒿化学计量特征及其与土壤养分的关系[J/OL].应用生态学报:1-11[2019-09-18].https://doi.org/10.13287/j.1001-9332.2019-08-026
[35] 周欣,左小安,赵学勇,等. 半干旱沙地生境变化对植物地上生物量及其碳、氮储量的影响[J]. 草业学报,2014,23(6):36-44
[36] 张广帅,邓浩俊,杜锟,等. 泥石流频发区山地不同海拔土壤化学计量特征——以云南省小江流域为例[J]. 生态学报,2016,36(03):675-687
[37] 王艳丽,字洪标,程瑞希,等. 青海省森林土壤有机碳氮储量及其垂直分布特征[J]. 生态学报,2019,39(11):4096-4105
[38] 王长庭,龙瑞军,王启基,等. 高寒草甸不同海拔梯度土壤有机质氮磷的分布和生产力变化及其与环境因子的关系[J]. 草业学报,2005(04):15-20
[39] Yang Y H,Fang J Y,Ma W H,et al. Soil carbon stock and its changes in northern China's grasslands from 1980s to 2000s. Global Change Biol,2010,16(11):3036-3047
[40] 陈庆美,王绍强,于贵瑞. 内蒙古自治区土壤有机碳、氮蓄积量的空间特征[J]. 应用生态学报,2003(05),14:699-704
[41] Fang J Y,Yang Y H,Ma W H,et al. Ecosystem carbon stocks and their changes in China's grasslands[J]. Science China. Life sciences,2010,53(07):757-765
[42] 赵威,李琳,王艳杰,等. 河南典型暖(热)性草地固碳特征及区域差异[J]. 应用生态学报,2018,29(06):1867-1875
[43] 陈林,辛佳宁,苏莹,等. 异质生境对荒漠草原植物群落组成和种群生态位的影响.生态学报,2019,39(17):6187-6205
[44] Loreau M. Biodiversity and Ecosystem Functioning:Current Knowledge and Future Challenges[J]. Science,2001,294(5543):804-808
[45] Kirk H,Paul J,Straka J,et al. Long-distance dispersal and high genetic diversity are implicated in the invasive spread of the common reed,Phragmites australis (Poaceae),in northeastern North America[J]. American Journal of Botany,2011,98(07):1180

山西暖性草地碳密度分布特征及其区域差异

Distribution Characteristics of Carbon Density in Warm-temperate Grassland and its Regional Difference in Shanxi

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