Meta-analysis on responses of soil particulate organic carbon and mineral-associated organic carbon to climate change

Chen Xiaohui; Li Yan; Li Yueyang; Yu Xinpeng; Qu Jiuqi; Yang Guang; Wang Mingxiao; Liu Lin

doi:10.13961/j.cnki.stbctb.2025.02.028

您当前的位置：

首页 >

文章列表页 >

Meta-analysis on responses of soil particulate organic carbon and mineral-associated organic carbon to climate change

- Meta-analysis on responses of soil particulate organic carbon and mineral-associated organic carbon to climate change
- Bulletin of Soiland Water Conservation Vol. 45, Issue 2, Pages: 272-282(2025)
- 作者机构：
  
  山东师范大学地理与环境学院,山东,济南,250000
- 作者简介：
- 基金信息：
- DOI：10.13961/j.cnki.stbctb.2025.02.028
  CLC： S153.6
- Online First：16 May 2025，
  
  Published：2025
- 稿件说明：
移动端阅览
Chen Xiaohui, Li Yan, Li Yueyang, et al. Meta-analysis on responses of soil particulate organic carbon and mineral-associated organic carbon to climate change[J]. Bulletin of Soiland Water Conservation, 2025, 45(2): 272-282.
DOI：

Chen Xiaohui, Li Yan, Li Yueyang, et al. Meta-analysis on responses of soil particulate organic carbon and mineral-associated organic carbon to climate change[J]. Bulletin of Soiland Water Conservation, 2025, 45(2): 272-282. DOI： 10.13961/j.cnki.stbctb.2025.02.028.

摘要

[目的

]

探究气候变化与土壤固碳能力的关系，揭示气温、二氧化碳(CO

)浓度和降水增减对土壤有机碳及其组分碳库的影响，为全球气候变化背景下土壤碳汇能力的提高提供理论依据。[方法

]

采用Meta分析方法，共筛选44篇相关文献，收集281个样本数据，利用颗粒有机碳(particulate organic carbon，POC)和矿质结合态有机碳(mineral associated organic carbon， MAOC)表征土壤活性与惰性有机碳组分，分析气候变化对土壤碳储量及其稳定性的影响。[结果

]

①大气CO

浓度与土壤POC和MAOC含量呈显著负相关(p＜0.05)；气温升高使土壤POC含量降低，而土壤MAOC含量略有升高，POC对气温变化更为敏感；土壤POC与降水量增加呈正相关，与降水量减少呈负相关，而土壤MAOC含量则与之相反。②气温，CO

浓度增加和降水量减少会伴随土壤总有机碳含量降低，而降水量增加则会导致总土壤有机碳含量增加。③土层深度和地类对土壤有机碳及组分对气候变化因子的响应有重要影响。[结论

]

不同气候因子对土壤有机碳及其组分含量的影响存在明显差异，其变化会降低土壤有机碳库储量或其稳定性，削弱土壤固碳能力。

Abstract

[Objective] The relationship between climate change and soil carbon sequestration capacity to reveal the effects of temperature

carbon dioxide (CO2) concentration

and precipitation on soil organic carbon and its component pool were explored

in order to provide a theoretical basis for improving soil carbon sequestration capacity in the context of global climate change. [Methods] Using a Meta-analysis

44 relevant studies were screened

and 281 research sample data were collected. Active and inert soil organic carbon components were characterized by particulate organic carbon (POC) and mineral-associated organic carbon (MAOC)

respectively. The effects of climate change on soil carbon stocks and soil stability were analyzed. [Results] ① Atmospheric CO2 concentration and soil POC and MAOC content showed a significantly negative correlation (p<0.05). POC content decreased with rising air temperature

whereas MAOC content increased slightly. POC was more sensitive to changes in air temperature than MAOC. Soil POC was positively correlated with an increase in precipitation and negatively correlated with a decline in precipitation

whereas soil MAOC content showed the opposite trend. ② The increase in air temperature and CO2 concentration as well as the decrease in precipitation reduced the concentration of the soil total organic carbon

whereas the rise in precipitation increased the concentration of the soil total organic carbon. ③ The response of soil organic carbon and its components to changes in climatic factors was affected by soil depth and soil type. [Conclusion] The influence of climatic factors on the soil's organic carbon and its component content is clearly different. Moreover

changes in climatic factors reduce the storage or stability of the soil organic carbon pool and weaken the soil carbon sequestration capacity.

关键词

Keywords

references

Sanderman J, Hengl T, Fiske G J. Soil carbon debt of 12000 years of human land use [J]. Proceedings of the National Academy of Sciences of the United States of America, 2017,114(36):9575-9580.

Cotrufo M F, Soong J L, Horton A J, et al. Formation of soil organic matter via biochemical and physical pathways of litter mass loss [J]. Nature Geoscience, 2015,8(10):776-779.

金鑫鑫,汪景宽,孙良杰,等.稳定

C同位素示踪技术在农田土壤碳循环和团聚体固碳研究中的应用进展[J].土壤,2017,49(2):217-224. Jin Xinxin, Wang Jingkuan, Sun Liangjie, et al. Progress of carbon cycle in farmland and sequestration in soil aggregates revealed by stable

C isotope [J]. Soils,2017,49(2):217-224.

Rocci K S, Lavallee J M, Stewart C E, et al. Soil organic carbon response to global environmental change depends on its distribution between mineral-associated and particulate organic matter: A Meta-analysis [J]. Science of the Total Environment, 2021,793:148569.

Bossio D A, Cook-Patton S C, Ellis P W, et al. The role of soil carbon in natural climate solutions [J]. Nature Sustainability, 2020,3(5):391-398.

Lu Xiaofei, Hou Enqing, Guo Jieyun, et al. Nitrogen addition stimulates soil aggregation and enhances carbon storage in terrestrial ecosystems of China: A meta-analysis [J]. Global Change Biology, 2021,27(12):2780-2792.

Cotrufo M F, Ranalli M G, Haddix M L, et al. Soil carbon storage informed by particulate and mineral-associated organic matter [J]. Nature Geoscience, 2019,12(12):989-994.

Feng Wenting, Plante A F, Aufdenkampe A K, et al. Soil organic matter stability in organo-mineral complexes as a function of increasing C loading [J]. Soil Biology and Biochemistry, 2014,69:398-405.

蓝家程,王俊贤,王莎莎,等.喀斯特石漠化治理措施对土壤颗粒有机碳与团聚体有机碳的影响[J].中国岩溶,2022,41(5):773-783. Lan Jiacheng, Wang Junxian, Wang Shasha, et al. Impact of controlling karst rocky desertification on soil particulate organic carbon and aggregate-associated organic carbon [J]. Carsologica Sinica, 2022,41(5):773-783.

章晓芳,郑生猛,夏银行,等.红壤丘陵区土壤有机碳组分对土地利用方式的响应特征[J].环境科学,2020,41(3):1466-1473. Zhang Xiaofang, Zheng Shengmeng, Xia Yinhang, et al. Responses of soil organic carbon fractions to land use types in hilly red soil regions, China [J]. Environmental Science, 2020,41(3):1466-1473.

Six J, Callewaert P, Lenders S, et al. Measuring and understanding carbon storage in afforested soils by physical fractionation [J]. Soil Science Society of America Journal, 2002,66(6):1981-1987.

张睿博,汪金松,王全成,等.土壤颗粒态有机碳与矿物结合态有机碳对气候变暖响应的研究进展[J].地理科学进展,2023,42(12):2471-2484. Zhang Ruibo, Wang Jinsong, Wang Quancheng, et al. Responses of soil particulate and mineral-associated organic carbon to climate warming: A review [J]. Progress in Geography, 2023,42(12):2471-2484.

Jia Juan, Liu Zongguang, Haghipour N, et al. Molecular

C evidence for contrasting turnover and temperature sensitivity of soil organic matter components [J]. Ecology Letters, 2023,26(5):778-788.

Feyissa A, Yang Fan, Feng Jiao, et al. Soil labile and recalcitrant carbon and nitrogen dynamics in relation to functional vegetation groups along precipitation gradients in secondary grasslands of South China [J]. Environmental Science and Pollution Research International, 2020,27(10):10528-10540.

He Nianpeng, Chen Quansheng, Han Xingguo, et al. Warming and increased precipitation individually influence soil carbon sequestration of Inner Mongolian grasslands, China [J]. Agriculture,Ecosystems & Environment, 2012,158:184-191.

Jastrow J D, Miller R M, Matamala R, et al. Elevated atmospheric carbon dioxide increases soil carbon [J]. Global Change Biology, 2005,11(12):2057-2064.

Carney K M, Hungate B A, Drake B G, et al. Altered soil microbial community at elevated CO

leads to loss of soil carbon [J]. Proceedings of the National Academy of Sciences of the United States of America, 2007,104(12):4990-4995.

Carrillo Y, Dijkstra F, Lecain D, et al. Elevated CO

and warming cause interactive effects on soil carbon and shifts in carbon use by bacteria [J]. Ecology Letters, 2018,21(11):1639-1648.

Crowther T W, Todd-Brown K O, Rowe C W, et al. Quantifying global soil carbon losses in response to warming [J]. Nature, 2016,540(7631):104-108.

Chen Ying, Feng Jiguang, Yuan Xia, et al. Effects of warming on carbon and nitrogen cycling in alpine grassland ecosystems on the Tibetan Plateau: A meta-analysis [J]. Geoderma, 2020,370:114363.

Chen Ying, Han Mengguang, Yuan Xia, et al. Warming has a minor effect on surface soil organic carbon in alpine meadow ecosystems on the Qinghai-Tibetan Plateau [J]. Global Change Biology, 2022,28(4):1618-1629.

Allard V, Newton P C D, Lieffering M, et al. Increased quantity and quality of coarse soil organic matter fraction at elevated CO

in a grazed grassland are a consequence of enhanced root growth rate and turnover [J]. Plant and Soil, 2005,276(1):49-60.

Lichter J, Barron S H, Bevacqua C E, et al. Soil carbon sequestration and turnover in a pine forest after six years of atmospheric CO

enrichment [J]. Ecology, 2005,86(7):1835-1847.

Walker T W N, Kaiser C, Strasser F, et al. Microbial temperature sensitivity and biomass change explain soil carbon loss with warming [J]. Nature Climate Change, 2018,8(10):885-889.

Nottingham A T, Meir P, Velasquez E, et al. Soil carbon loss by experimental warming in a tropical forest [J]. Nature, 2020,584(7820):234-237.

Guan Song, An Na, Zong Ning, et al. Climate warming impacts on soil organic carbon fractions and aggregate stability in a Tibetan alpine meadow [J]. Soil Biology and Biochemistry, 2018,116:224-236.

Schmidt M W I, Torn M S, Abiven S, et al. Persistence of soil organic matter as an ecosystem property [J]. Nature, 2011,478(7367):49-56.

高静,徐明岗,李然,等.整合分析生物炭施用对土壤pH的影响[J].中国农业科技导报,2023,25(9):186-196. Gao Jing, Xu Minggang, Li Ran, et al. Effects of biochar application on soil pH: A Meta-analysis [J]. Journal of Agricultural Science and Technology, 2023,25(9):186-196.

Hijmans R J, Cameron S E, Parra J L, et al. Very high resolution interpolated climate surfaces for global land areas [J]. International Journal of Climatology, 2005,25(15):1965-1978.

Zhou Zhenghu, Wang Chuankuan, Zheng Mianhai, et al. Patterns and mechanisms of responses by soil microbial communities to nitrogen addition [J]. Soil Biology and Biochemistry, 2017,115:433-441.

Hedges L V, Gurevitch J, Curtis P S. The meta-analysis of response ratios in experimental ecology [J]. Ecology, 1999,80(4):1150.

张广立,岑柏霆,龙新宪,等.粪肥施用对土壤团聚体的影响:Meta分析[J].土壤,2024,56(3):610-622. Zhang Guangli, Cen B T, Long Xinxian, et al. Responses of soil aggregates to manure application: A meta-analysis [J]. Soils, 2024,56(3):610-622.

蒋发辉,钱泳其,郭自春,等.基于Meta分析评价东北黑土地保护性耕作与深耕的区域适宜性:以作物产量为例[J].土壤学报,2022,59(4):935-952. Jiang Fahui, Qian Yongqi, Guo Zichun, et al. Evaluating the regional suitability of conservation tillage and deep tillage based on crop yield in the black soil of NorthEast China: A Meta-analysis [J]. Acta Pedologica Sinica, 2022,59(4):935-952.

安海涛,孙彩彩,董全民,等.青藏高原土壤微生物生物量对放牧强度响应的Meta分析[J].草地学报,2024,32(6):1913-1922. An Haitao, Sun Caicai, Dong Quanmin, et al. Meta-analysis of soil microbial biomass response to grazing intensity in the Qinghai-Tibetan Plateau [J]. Acta Agrestia Sinica, 2024,32(6):1913-1922.

朵莹.冬季及生长季增温对草地生态系统碳氮过程及地上生物量的影响:基于meta分析与控制实验[D].陕西杨凌:西北农林科技大学,2022. Duo Ying. Effects of warming in winter and growing season on carbon and nitrogen processes and aboveground biomass of grassland ecosystem: Based on Meta-analysis and control experiments [D]. Yangling, Shaanxi: Northwest A & F University, 2022.

Lugato E, Lavallee J M, Haddix M L, et al. Different climate sensitivity of particulate and mineral-associated soil organic matter [J]. Nature Geoscience, 2021,14(5):295-300.

Rasmussen C, Torn M S, Southard R J. Mineral assemblage and aggregates control carbon dynamics in a

California conifer

forest [J]. Soil Science Society of America Journal, 2005,69(6):1711-1721.

Jensen K H, Grandy A S, Sparks J P. Elevated atmospheric CO

drives decreases in stable soil organic carbon in arid ecosystems: Evidence from a physical fractionation and organic compound analysis [J]. Global Change Biology, 2024,30(2):e17175.

司马鑫琪,李彦生,于镇华,等.大气CO

浓度和温度升高对玉米农田黑土碳库及细菌群落的影响[J].土壤与作物,2024,13(4):428-438. Sima Xinqi, Li Yansheng, Yu Zhenhua, et al. Effects of elevated atmospheric CO

concentration and warming on soil carbon pool and microbial community composition in a maize-grown mollisol [J]. Soils and Crops, 2024,13(4):428-438.

Peplau T, Schroeder J, Gregorich E, et al. Long-term geothermal warming reduced stocks of carbon but not nitrogen in a subarctic forest soil [J]. Global Change Biology, 2021,27(20):5341-5355.

Amelung W, Flach K W, Zech W. Lignin in particle-size fractions of native grassland soils as influenced by climate [J]. Soil Science Society of America Journal, 1999,63(5):1222-1228.

Sokol N W, Sanderman J, Bradford M A. Pathways of mineral-associated soil organic matter formation: Integrating the role of plant carbon source, chemistry, and point of entry [J]. Global Change Biology, 2019,25(1):12-24.

Bai Tongshuo, Wang Peng, Hall S J, et al. Interactive global change factors mitigate soil aggregation and carbon change in a semi-arid grassland [J]. Global Change Biology, 2020,26(9):5320-5332.

Jaman M S, Wu Honghui, Yu Qiang, et al. Contrasting responses of plant above and belowground biomass carbon pools to extreme drought in six grasslands spanning an aridity gradient [J]. Plant and Soil, 2022,473(1):167-180.

胡坤,张红雪,郭力铭,等.烟秆炭基肥对薏苡土壤有机碳组分及微生物群落结构和丰度的影响[J].中国生态农业学报(中英文),2021,29(9):1592-1603. Hu Kun, Zhang Hongxue, Guo Liming, et al. Effects of tobacco stalk biochar-based fertilizer on the organic carbon fractions and microbial community structure of adlay soil [J]. Chinese Journal of Eco-agriculture, 2021,29(9):1592-1603.

蒿廉伊.控制降水对黄土高原西部荒漠草原土壤有机碳组分及其稳定性的影响[D].甘肃兰州:西北师范大学,2022. Hao Lianyi. Effects of controlled precipitation on soil organic carbon composition and its stability in desert steppe of Western Loess Plateau [D]. Lanzhou, Gansu: Northwest Normal University, 2022.

Pisani O, Frey S D, Simpson A J, et al. Soil warming and nitrogen deposition alter soil organic matter composition at the molecular-level [J]. Biogeochemistry, 2015,123(3):391-409.

陈栋,郁红艳,邹路易,等.大气CO

浓度升高对不同层次水稻土有机碳稳定性的影响[J].应用生态学报,2018,29(8):2559-2565. Chen Dong, Yu Hongyan, Zou Luyi, et al. Effects of elevated atmospheric CO

concentration on the stability of soil organic carbon in different layers of a paddy soil [J]. Chinese Journal of Applied Ecology, 2018,29(8):2559-2565.

Cardon Z G, Hungate B A, Cambardella C A, et al. Contrasting effects of elevated CO

on old and new soil carbon pools [J]. Soil Biology and Biochemistry, 2001,33(3):365-373.

Zhang Xianzhou, Shen Zhenxi, Fu Gang. A meta-analysis of the effects of experimental warming on soil carbon and nitrogen dynamics on the Tibetan Plateau [J]. Applied Soil Ecology, 2015,87:32-38.

Luo Yiqi, Su Bo, Currie W S, et al. Progressive nitrogen limitation of ecosystem responses to rising atmospheric carbon dioxide [J]. BioScience, 2004,54(8):731.

Views

下载量

CSCD

Alert me when the article has been cited

提交

Tools

Publicity Resources

Effects of hydrochar from sunflower straw on soil organic carbon and its mineralization characteristics

Precise measurement and caculation of carbon sink on check dams in Loess Plateau——A case study at Gaoxigou small watershed， Yulin City， Shaanxi Province

Characteristics and influencing factors of soil organic carbon at Picea crassifolia forests in middle part of Qilian Mountains

Spatial Heterogeneity and Pattern of Black Soil Organic Carbon of Sloping Field

Effects of Elevated CO_2 on Soil Organic Carbon and Nitrogen of Wetlands in Sanjiang Plain

Related Author

Wang Xueren

Zhang Puhe

Yao Jia

Zhao Shixiang

Huo Shaofeng

Zhao Mengfan

Wang Jian

Li Rongrong

Related Institution

Key Laboratory of Agricultural;Ecological Safety and Green Development of Autonomous Region in Higher Education

Inner Mongolia Key Laboratory of Soil Quality and Nutrient Resource， College of Resources and Environment，Inner Mongolia Agricultural University

College of Forestry， Northwest A&F University， Yangling

College of Soil and Water Conservation Science and Engineering， Northwest A&F University， Yangling

Gansu Qilian Mountain National Nature Reserve Management Center

⁰