Spatial Stability Analysis of Surface Soil Carbon,Nitrogen,and Phosphorus Densities in Alpine Grasslands in the Sanjiangyuan Region

doi:10.11733/j.issn.1007-0435.2023.09.019

Acta Agrestia Sinica ›› 2023, Vol. 31 ›› Issue (9): 2748-2758.DOI: 10.11733/j.issn.1007-0435.2023.09.019

Spatial Stability Analysis of Surface Soil Carbon,Nitrogen,and Phosphorus Densities in Alpine Grasslands in the Sanjiangyuan Region

SHU Min^1,2,3,4,5, CHEN Dong-dong^1,2,3,4, LI Qi^1,2,3,4, ZHANG Li^1,2,3,4, HE Fu-quan^1,2,3,4, ZHANG Yu-kun^1,2,3,4, PAN Si-chen^1,2,3,4,5, ZHAO Liang^1,2,3,4

1. Qinghai Sanjiangyuan Grassland Ecosystem National Field Scientific Observation and research Station, Xining, Qinghai Province 810008, China;
2. Key Laboratory of Plateau Adaptation and Evolution, Chinese Academy of Sciences, Xining, Qinghai Province 810008, China;
3. Sanjiangyuan National Park Research Institute, Chinese Academy of Sciences, Xining, Qinghai Province 810008, China;
4. Northwest Institute of Plateau Biology, Chinese Academy of Sciences, Qinghai Province 810008, China;
5. University of Chinese Academy of Sciences, Beijing 100049, China

Received:2023-02-22 Revised:2023-03-21 Online:2023-09-15 Published:2023-10-07

三江源区高寒草地表层土壤碳、氮、磷密度空间稳定性分析

舒敏^1,2,3,4,5, 陈懂懂^1,2,3,4, 李奇^1,2,3,4, 张莉^1,2,3,4, 贺福全^1,2,3,4, 张煜坤^1,2,3,4, 潘思辰^1,2,3,4,5, 赵亮^1,2,3,4

1. 青海三江源草地生态系统国家野外科学观测研究站, 青海西宁 810008;
2. 中国科学院高原生物适应与进化重点实验室, 青海西宁 810008;
3. 中国科学院三江源国家公园研究院, 青海西宁 810008;
4. 中国科学院西北高原生物研究所, 青海西宁 810008;
5. 中国科学院大学, 北京 100049

通讯作者: 赵亮,E-mail:lzhao@nwipb.cas.cn
作者简介:舒敏(1997-),女,汉族,四川南充人,硕士研究生,主要从事陆地碳循环方面研究,E-mail:shumin20@mails.ucas.ac.cn
基金资助:
科技基础资源调查专项(2021-FY-100705)；青海省基础研究项目(2021-ZJ-761)；2022年青海省中青年科技人才托举工程资助

Abstract

Abstract: It is of great significance to study the spatial stability of soil carbon,nitrogen and phosphorus density in the surface layer (0~10 cm) of the alpine grassland in the Sanjiangyuan to evaluate the nutrient cycle of the regional ecosystem. This study collected vegetation,soil and meteorological data from 13 counties/towns in the Sanjiangyuan region in August and September 2017,and analyzed the spatial stability and influencing factors of surface soil carbon,nitrogen and phosphorus density in the region. The results showed that the spatial distribution of soil surface carbon,nitrogen and phosphorus in the source area of the Sanjiangyuan region was mainly affected by altitude. The density of soil organic carbon,total nitrogen and total phosphorus increased first and then decreased with the increase of altitude,while the density of inorganic carbon decreased first and then increased. According to the results of spatial cluster analysis,the spatial stability of soil organic carbon and total nitrogen density decreased from the southeast to the northwest,while that of inorganic carbon was on the contrary direction,and that of total phosphorus in the southern region was higher than that in the northern region. The spatial stability of soil carbon,nitrogen and phosphorus densities in the Sanjiangyuan region was ranked as total phosphorus > total nitrogen > organic carbon > inorganic carbon,which was closely related to altitude,plant diversity,underground biomass,soil water content,soil pH value and other factors.

Key words: Soil organic carbon density, Soil total nitrogen density, Spatial stability, Sanjiangyuan region

摘要： 探究三江源区高寒草地表层(0~10 cm)土壤碳、氮、磷密度空间稳定性对评价区域生态系统养分循环具有重要意义。本研究于2017年8-9月对三江源区13个县/镇的植被、土壤和气象数据进行收集,分析了三江源区高寒草地表层土壤碳、氮、磷密度空间稳定性及影响因素。结果表明:三江源区土壤表层碳、氮、磷的空间分布主要受海拔影响,土壤有机碳、全氮、全磷密度随海拔增加呈先增加后降低的趋势,无机碳密度则呈先降低后增加的趋势。根据空间聚类分析的结果,土壤有机碳、全氮密度空间稳定性在三江源区内呈东南向西北递减的趋势,无机碳与之相反,全磷则为南部地区高于北部地区。三江源区土壤碳、氮、磷密度空间稳定性大小的排序为全磷>全氮>有机碳>无机碳,这主要与海拔、植被多样性、地下生物量、土壤含水量、土壤pH值等因子的密切相关。

关键词: 土壤有机碳密度, 土壤全氮密度, 空间稳定性, 三江源区

CLC Number:

S153

SHU Min, CHEN Dong-dong, LI Qi, ZHANG Li, HE Fu-quan, ZHANG Yu-kun, PAN Si-chen, ZHAO Liang. Spatial Stability Analysis of Surface Soil Carbon,Nitrogen,and Phosphorus Densities in Alpine Grasslands in the Sanjiangyuan Region[J]. Acta Agrestia Sinica, 2023, 31(9): 2748-2758.

舒敏, 陈懂懂, 李奇, 张莉, 贺福全, 张煜坤, 潘思辰, 赵亮. 三江源区高寒草地表层土壤碳、氮、磷密度空间稳定性分析[J]. 草地学报, 2023, 31(9): 2748-2758.

0
/ / Recommend

Add to citation manager EndNote|Ris|BibTeX

URL: https://manu40.magtech.com.cn/Jweb_cdxb/EN/10.11733/j.issn.1007-0435.2023.09.019

https://manu40.magtech.com.cn/Jweb_cdxb/EN/Y2023/V31/I9/2748

References

[1] 许窕孜,邹祖有,叶彩红,等. 江门市3种亚热带林分类型土壤碳氮磷储量分布特征[J]. 林业与环境科学,2022,38(3):34-38
[2] 林伟山,德科加,向雪梅,等. 天然草地植被-土壤系统碳、氮、磷(钾)库的时空分布格局研究进展[J]. 青海畜牧兽医杂志,2022,52(2):45-5168
[3] 朱玉荷,肖虹,王冰,等. 蒙古高原草地不同深度土壤碳氮磷化学计量特征对气候因子的响应[J]. 植物生态学报,2022,46(3):340-349
[4] 戚德辉,温仲明,王红霞,等. 黄土丘陵区不同功能群植物碳氮磷生态化学计量特征及其对微地形的响应[J]. 生态学报,2016,36(20):6420-6430
[5] 乔林明,韩慧,贺高航,等. 侵蚀地貌中土壤团聚体碳、氮、磷含量变化及其环境风险[J]. 水土保持学报,2022,36(3):267-273
[6] 徐兵兵. 流域特征对南苕溪溶解有机质浓度的影响[J]. 生态与农村环境学报,2021,37(1):39-48
[7] 张剑,宿力,王利平,等. 植被盖度对土壤碳、氮、磷生态化学计量比的影响——以敦煌阳关湿地为例[J]. 生态学报,2019,39(2):580-589
[8] 关伟涛,郑志荣,刁兆岩,等. 不同干扰方式下温性草甸草原土壤碳氮磷化学计量特征及其储量研究[J]. 草地学报,2022,30(11):2959-2966
[9] 赵一嬴,李月芬,王月娇,等. 草地退化演替阶段羊草叶片碳氮磷化学计量学研究[J]. 中国农学通报,2016,32(11):73-77
[10] 顾振宽,杜国祯,朱炜歆,等. 青藏高原东部不同草地类型土壤养分的分布规律[J]. 草业科学,2012,29(4):507-512
[11] BAI Y,COTRUFO M F. Grassland soil carbon sequestration:Current understanding,challenges,and solutions[J]. Science,2022,377(6606):603-608
[12] 胡理乐,林伟,罗遵兰,等. 井冈山重要森林生态系统碳密度对比[J]. 环境科学研究,2011,24(4):401-408
[13] 董锁成,周长进,王海英. "三江源"地区主要生态环境问题与对策[J]. 自然资源学报,2002,17(6):713-720
[14] 张法伟,李红琴,李文清,等. 三江源国家公园表层土壤有机碳和全氮密度的特征评估和等级区划[J]. 生态学报,2022,42(14):5593-5602
[15] 潘保田,李吉均. 青藏高原:全球气候变化的驱动机与放大器——Ⅲ.青藏高原隆起对气候变化的影响[J]. 兰州大学学报:自然科学版,1996,32(1):108-115
[16] 刘育红,魏卫东,温小成,等. 三江源区不同退化高寒草甸土壤碳分布特征研究[J]. 湖北农业科学,2015,54(02):308-312,381
[17] 张法伟,李红琴,仪律北,等. 草地退化对三江源国家公园高寒草甸表层土壤有机碳、全氮、全磷的空间驱动[J]. 生态学报,2022,42(14):5586-5592
[18] XU L,HE N,YU G. Nitrogen storage in China's terrestrial ecosystems[J]. Science of The Total Environment,2019,709:136201
[19] BATJES N H,RIBEIRO E,OOSTRUM A V. Standardised soil profile data to support global mapping and modelling (WoSIS snapshot 2019)[J]. Earth System Science Data,2020,12:299-320
[20] 王长庭,龙瑞军,曹广民,等. 三江源地区主要草地类型土壤碳氮沿海拔变化特征及其影响因素[J]. 植物生态学报,2006,30(3):441-449
[21] CHEN D,LI Q,LI C,et al. Density and Stoichiometric Characteristics of Carbon,Nitrogen,and Phosphorus in Surface Soil of Alpine Grassland in Sanjiangyuan[J]. Polish Journal of Environmental Studies,2022,31(4):3531-3539
[22] 林超峰,陈占全,薛泉宏,等. 青海三江源区植被退化对土壤养分和微生物区系的影响[J]. 应用与环境生物学报,2007,13(6):788-793
[23] 李以康,韩发,冉飞,等. 三江源区高寒草甸退化对土壤养分和土壤酶活性影响的研究[J]. 中国草地学报,2008,30(4):51-58
[24] 杨永胜,张莉,未亚西,等. 退化程度对三江源泽库高寒草甸土壤理化性质及持水能力的影响[J]. 中国草地学报,2017,39(5):54-61
[25] 贺福全,陈懂懂,李奇,等. 三江源区高寒草地营养承载力时空格局[J]. 草地学报,2021,29(12):2808-2816
[26] 周秉荣,颜亮东,校瑞香. 三江源地区太阳辐射与日照时空分布特征[J]. 资源科学,2012,34(11):2074-2079
[27] 陈懂懂,赵亮,贺福全,等. 三江源高寒草地常见可食牧草在不同分布区的营养成分分析[J]. 草原与草坪,2021,41(4):134-142
[28] 杨冲,王文颖,周华坤,等. 三江源区高寒草地植物多样性与土壤因子的耦合关系[J]. 甘肃农业大学学报,2022,57(2):125-136
[29] 王采娥,黄梅,王文银,等. 三江源区高寒坡地退化植物群落多样性和地上生物量沿海拔梯度的变化特征[J]. 生态学报,2022,42(9):3640-3655
[30] 王晓薇,牛萌楠,张丽薇,等. 不同施氮水平对温带典型草原植物地上-地下生物量分配模式的影响[J]. 河南师范大学学报:自然科学版,2021,49(6):39-46
[31] 胡冬,吕光辉,王恒方,等. 水分梯度下荒漠植物多样性与稳定性对土壤因子的响应[J]. 生态学报,2021,41(17):6738-6748
[32] MAGURRAN A E. Ecological diversity and its measurement[M]. Springer,London:Croom Helm,1988:35
[33] R CORE TEAM. R:A language and environment for statistical computing[EB/OL]. https://www.R-project.org/,2023-04-11
[34] WICKHAM H. Reshaping data with the reshape package[J]. Journal of Statistical Software,2007,21:1-20
[35] KASSAMBARA A,MUNDT F. FACTOEXTRA:Extract and visualize the results of multivariate data analyses[EB/OL]. https://rpkgs.datanovia.com/factoextra/index.html#factoextra-extract-and-visualize-the-results-of-multivariate-data-analyses,2023-04-12
[36] NAIDU D G T,ROY S,BAGCHI S. Loss of grazing by large mammalian herbivores can destabilize the soil carbon pool[J]. Proceedings of the National Academy of Sciences,2022,119(43):e2211317119
[37] CHANG X,WANG S,CUI S,et al. Alpine grassland soil organic carbon stock and its uncertainty in the Three Rivers Source Region of the Tibetan Plateau[J]. PLoS One,2014,9(5):e97140
[38] 刘淑丽,林丽,郭小伟,等. 青海省高寒草地土壤无机碳储量空间分异特征[J]. 生态学报,2014,34(20):5953-5961
[39] 张法伟,李英年,汪诗平,等. 青藏高原高寒草甸土壤有机质、全氮和全磷含量对不同土地利用格局的响应[J]. 中国农业气象,2009(3):323-326,334
[40] 冯瑞章,周万海,龙瑞军,等. 江河源区不同建植期人工草地土壤养分及微生物量磷和磷酸酶活性研究[J]. 草业学报,2007,16(6):1-6
[41] 张威,高小红,冯玲,等. 三江源区土壤有机碳空间分布及影响因素分析:以玉树县为例[J]. 环境科学与技术,2014,37(4):42-47
[42] 邱巡巡,曹广超,张卓,等. 高寒农田土壤有机碳和全氮密度垂直分布特征及其与海拔的关系[J]. 土壤通报,2022,53(3):623-630
[43] 薛晓娟,李英年,杜明远,等. 祁连山东段南麓不同海拔土壤有机质及全氮的分布状况[J]. 冰川冻土,2009(4):642-649
[44] 卢慧,丛静,刘晓,等. 三江源区高寒草甸植物多样性的海拔分布格局[J]. 草业学报,2015,24(7):197-204
[45] 廖娇娇,窦艳星,安韶山. 黄土高原不同植被群落多样性与土壤有机碳密度关系研究[J]. 水土保持研究,2022,29(4):75-82
[46] 张继平,刘春兰,郝海广,等. 基于MODIS GPP/NPP数据的三江源地区草地生态系统碳储量及碳汇量时空变化研究[J]. 生态环境学报,2015,24(1):8-13
[47] 郭曼,郑粉莉,安韶山,等. 植被自然恢复过程中土壤有机碳密度与微生物量碳动态变化[J]. 水土保持学报,2010(1):229-232238
[48] 贺斌,郭芝成,李根前,等. 克隆植物生长特征对土壤养分的响应研究概述[J]. 安徽农业科学,2009,37(31):15342-15344,15396
[49] 苏卓侠,苏冰倩,上官周平. 植物凋落物分解对土壤有机碳稳定性影响的研究进展[J]. 水土保持研究,2022,29(2):406-413
[50] 邹婧汝,赵新全. 围栏禁牧与放牧对草地生态系统固碳能力的影响[J]. 草业科学,2015,32(11):1748-1756

Spatial Stability Analysis of Surface Soil Carbon,Nitrogen,and Phosphorus Densities in Alpine Grasslands in the Sanjiangyuan Region

三江源区高寒草地表层土壤碳、氮、磷密度空间稳定性分析

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 10

Recommended Articles

Metrics

Comments

[1]	WANG Xin-jing, ZHANG Mei-ling, YANG Min-cong, SUN Qian, XU Shi-bo, XU Yu-juan, HUANG Shan-feng, GAO Zhi-wen. Simulation of Soil Organic Carbon and Analysis on its Influencing Factors in Zhangye Grassland Based on CENTURY Model [J]. Acta Agrestia Sinica, 2023, 31(4): 1173-1185.
[2]	XIAO Hai-long, MA Yuan, ZHOU Hui-cheng, ZHANG Cheng-jun, YAO Yu-jiao, CHEN Jian-gang, ZHANG De-gang. Characteristics of Soil Trace Elements and Vegetation and Their Relationships in Degraded Alpine Steppe in Sanjiangyuan Region [J]. Acta Agrestia Sinica, 2022, 30(8): 1925-1933.
[3]	LIANG Cheng-bo, WANG Jiu-li, SUN Guo, FENG Shou, ZHUO Ping-gui, LIU Dao-xin, YAN Jing-yan. The Study on Species Diversity of Bumblebees in Sanjiangyuan Region [J]. Acta Agrestia Sinica, 2022, 30(8): 2126-2134.
[4]	XING Yun-fei, WANG Xiao-li, LIU Yong-qi, HUA Re, WANG Chao, WU Jian-li, SHI Jian-jun. Characteristics of Plant Community and Soil Organic Carbon and Nitrogen in Artificial Grassland with Different Establishment Years [J]. Acta Agrestia Sinica, 2020, 28(2): 521-528.
[5]	CHEN Dong-dong, LI Qi, CHEN Xin, HE Fu-quan, ZHAO Xin-quan, XU Shi-xiao, ZHAO Liang. Response of Soil Microbial Biomass C and N,C Metabolism Characteristics of Microbes to Grass-Legume Mixtures of Annual Artificial Grassland in Sanjiangyuan Region [J]. Acta Agrestia Sinica, 2018, 26(5): 1064-1070.
[6]	HAO Li-zhuang, HAN Xiao-dong, NIU Jian-zhang, ZHANG Xiao-wei, XIANG Yang, WANG Xun, CHAI Sha-tuo, LONG Rui-jun, LIU SHU Jie. Study on Nutrient Balance of Grassland in Henan County, Sanjiang [J]. Acta Agrestia Sinica, 2018, 26(2): 520-524.
[7]	SHANG Zhan-huan, DONG Quan-min, SHI Jian-jun, ZHOU Hua-kun, DONG Shi-kui, SHAO Xin-qing, LI Shi-xiong, WANG Yan-long, MA Yu-shou, DING Lu-ming, CAO Guang-min, LONG Rui-jun. Research Progress in Recent Ten Years of Ecological Restoration for ‘Black Soil Land’ Degraded Grassland on Tibetan Plateau——Concurrently Discuss of Ecological Restoration in Sangjiangyuan Region [J]. Acta Agrestia Sinica, 2018, 26(1): 1-21.
[8]	LI Hui-mei, ZHANG An-lu. Herdsman's Perception and Influencing Factors about Grassland Ecological Environment Degradation Based on Household Investigation and Structural Equation Modeling in Sanjiangyuan Region, China [J]. Acta Agrestia Sinica, 2015, 23(4): 679-688.
[9]	LIU Wei, CHENG Ji-min, CHEN Fu-rong, GAO Yang. Characteristic of Organic Carbon Density and Organic Carbon Storage in the Natural Grassland of Center Loess Plateau [J]. , 2011, 19(3): 425-431.
[10]	ZHAO Jin-mei, GAO Chao, ZHANG De-gang. Study on the Soil Organic Carbon Density of Alpine Meadow with Different Degradation Degrees in Eastern Qilian Mountains [J]. , 2010, 18(1): 21-25.