退牧还草地土壤有机碳固持动态与驱动机制研究进展

doi:10.13287/j.1001-9332.202411.009

应用生态学报 ›› 2024, Vol. 35 ›› Issue (11): 3208-3216.doi: 10.13287/j.1001-9332.202411.009

退牧还草地土壤有机碳固持动态与驱动机制研究进展

邓蕾^1,2,3, 李继伟^1,2, 瞿晴³, 石经玮³, 上官周平^1,2,3*

¹西北农林科技大学黄土高原土壤侵蚀与旱地农业国家重点实验室, 陕西杨凌 712100;
²西北农林科技大学水土保持科学与工程学院(水土保持研究所), 陕西杨凌 712100;
³中国科学院水利部水土保持研究所, 陕西杨凌 712100

收稿日期:2024-06-26 修回日期:2024-08-28 出版日期:2024-11-18 发布日期:2025-05-18
通讯作者: *E-mail: shangguan@ms.iswc.ac.cn
作者简介:邓蕾, 男, 1986年生, 研究员。主要从事区域生态恢复及固碳效应研究。E-mail: leideng@ms.iswc.ac.cn
基金资助:
国家自然科学基金项目(42277471)

Dynamics and driving mechanisms of soil organic carbon sequestration in grasslands after grazing exclusion: A review.

DENG Lei^1,2,3, LI Jiwei^1,2, QU Qing³, SHI Jingwei³, SHANGGUAN Zhouping^1,2,3*

¹State Key Laboratory for Soil Erosion and Dryland Farming on the Loess Plateau, Northwest A&F University, Yangling 712100, Shaanxi, China;
²College of Soil and Water Conservation Science and Engineering (Institute of Soil and Water Conservation), Northwest A&F University, Yangling 712100, Shaanxi, China;
³Institute of Soil and Water Conservation, Chinese Academy of Science and Ministry of Water Resources, Yangling 712100, Shaanxi, China

Received:2024-06-26 Revised:2024-08-28 Online:2024-11-18 Published:2025-05-18

摘要/Abstract

摘要： 退牧还草被认为是恢复退化草地结构和功能的最有效措施,在提高生态系统固碳能力方面发挥着重要作用。阐明退牧还草后土壤有机碳的固持动态及其驱动机制,是全球变化下碳循环研究的热点和前沿问题。本文综述了退牧还草地土壤有机碳固定动态及其驱动机制,剖析了退牧还草地土壤有机碳固持动态,探讨了退牧还草地植物碳输入和微生物群落对土壤有机碳固持的影响机制,分析了光合碳输入和凋落物分解对土壤有机碳固持的影响,以及植物和微生物残体碳对土壤有机碳固持的贡献。长期退牧还草通过增加植被碳输入,改善微生物的结构和功能,提升土壤稳定性有机碳(如矿物结合态有机碳、植物和微生物残体碳等)含量或比例,进而减少土壤有机碳矿化效率和提高微生物碳利用效率,从而促进土壤有机碳库的积累。退牧还草受初始有机碳水平的影响,土壤有机碳固定整体呈“增加、稳定”和“降低、增加、稳定”两种变化趋势。未来应加强在土壤有机碳组分动态、土壤有机碳输入的碳流过程、土壤有机碳的分解过程及其微生物驱动机制等方面的研究。

关键词: 固碳动态, 草地, 植物碳输入, 土壤有机碳, 土壤微生物, 植被恢复

Abstract: Grazing exclusion is the most effective measure to restore the structure and function of degraded grasslands, and plays a crucial role in increasing ecosystem carbon (C) sequestration capacity. The dynamics and dri-ving mechanisms of soil organic carbon (SOC) after grazing exclusion have attracted great concerns, especially in the context of global change. By reviewing the current research on the SOC sequestration dynamics and its driving mechanisms after grazing exclusion, we aimed to clarify the SOC sequestration dynamics, explore the influencing mechanisms of plant C input and microbial community on SOC, analyze the driving mechanisms of photosynthetic C input and litter decomposition on SOC sequestration, and explore the contribution of plant and microbial necromass C to SOC sequestration after grazing exclusion. Long-term grazing exclusion improve the structure and function of soil microorganisms by increasing plant carbon inputs, and increase the content and proportion of soil stable organic C (such as mineral-associated organic C, plant and microbial necromass C, etc.), reducing mineralization efficiency of SOC and improving microbial C utilization efficiency, and consequently promoting SOC accumulation. In addition, SOC sequestration shows two trends of “first increasing and then stabilizing” and “first decreasing, following increasing and then stabilizing”, which are affected by the initial SOC level. Future studies should be strengthened in the SOC fraction dynamics, the C flow of SOC input, the decomposition process of SOC, and the microbial dri-ving mechanism after grazing exclusion.

Key words: carbon sequestration dynamics, grassland, plant carbon input, soil organic carbon, soil microorga-nism, vegetation restoration

邓蕾, 李继伟, 瞿晴, 石经玮, 上官周平. 退牧还草地土壤有机碳固持动态与驱动机制研究进展[J]. 应用生态学报, 2024, 35(11): 3208-3216.

DENG Lei, LI Jiwei, QU Qing, SHI Jingwei, SHANGGUAN Zhouping. Dynamics and driving mechanisms of soil organic carbon sequestration in grasslands after grazing exclusion: A review.[J]. Chinese Journal of Applied Ecology, 2024, 35(11): 3208-3216.

参考文献

[1] Dacidson EA, Janssens IA. Temperature sensitivity of soil carbon decomposition and feedbacks to climate change. Nature, 2006, 440: 165-173
[2] Jiang ZY, Hu ZM, Lai DYF, et al. Light grazing facilitates carbon accumulation in subsoil in Chinese grassland: A meta-analysis. Global Change Biology, 2020, 26: 7186-7197
[3] Hu ZM, Li SG, Guo Q, et al. A synthesis of the effect of grazing exclusion on carbon dynamics in grasslands in China. Global Change Biology, 2016, 22: 1385-1393
[4] Deng L, Shangguan ZP, Bell SM, et al. Carbon in Chinese grasslands: Meta-analysis and theory of grazing effects. Carbon Research, 2023, 2: 19
[5] Abdalla M, Hastings A, Chadwick DR, et al. Critical review of the impacts of grazing intensity on soil organic carbon storage and other soil quality indicators in extensively managed grasslands. Agriculture, Ecosystems and Environment, 2018, 25: 62-81
[6] Deng L, Shangguan ZP, Wu GL, et al. Effects of gra-zing exclusion on carbon sequestration in China’s grassland. Earth-Science Reviews, 2017, 173: 84-95
[7] Li JW, Shangguan ZP, Deng L. Free particulate organic carbon plays critical roles in carbon accumulations during grassland succession since grazing exclusion. Soil and Tillage Research, 2022, 220: 105380
[8] Atere CT, Gunina A, Zhu Z, et al. Organic matter stabilization in aggregates and density fractions in paddy soil depending on long-term fertilization: Tracing of pathways by ¹³C natural abundance. Soil Biology and Biochemistry, 2020, 149: 107931
[9] Deng L, Zhang ZN, Shangguan ZP. Long-term fencing effects on plant diversity and soil properties in China. Soil & Tillage Research, 2014, 137: 7-15
[10] Qu Q, Deng L, Gunina A, et al. Grazing exclusion increases soil organic C through microbial necromass of root-derived C as traced by ¹³C labelling photosynthate. Biology and Fertility of Soil, 2024, 60: 407-420
[11] Li JW, Li MY, Dong LB, et al. Plant productivity and microbial composition drive soil carbon and nitrogen sequestrations following cropland abandonment. Science of the Total Environment, 2020, 744: 140802
[12] Qu Q, Zhang J, Hai XY, et al. Long-term fencing alters the vertical distribution of soil δ¹³C and SOC turnover rate: Revealed by MBC-δ¹³C. Agriculture, Ecosystems and Environment, 2022, 339: 108119
[13] Srivastava P, Singh R, Bhadouria R, et al. Temporal change in soil physicochemical, microbial, aggregate and available C characteristic in dry tropical ecosystem. Catena, 2020, 190: 104553
[14] Yu L, Chen Y, Sun W, et al. Effects of grazing exclusion on soil carbon dynamics in alpine grasslands of the Tibetan Plateau. Geoderma, 2019, 353: 133-143
[15] Golluscio RA, Austin AT, Martinez GC, et al. Sheep grazing decreases organic carbon and nitrogen pools in the Patagonian steppe: Combination of direct and indirect effects. Ecosystems, 2009, 12: 686-697
[16] Shrestha G, Stahl PD. Carbon accumulation and storage in semi-arid sagebrush steppe: Effects of long-term gra-zing exclusion. Agriculture, Ecosystems and Environment, 2008, 125: 173-181
[17] Reeder JD, Schuman GE. Influence of livestock grazing on C sequestration in semi-arid mixed-grass and short-grass rangelands. Environmental Pollution, 2002, 116: 457-463
[18] Qu Q, Deng L, Shangguan ZP, et al. Belowground C sequestrations response to grazing exclusion in global grasslands: Dynamics and mechanisms. Agriculture, Ecosystems and Environment, 2024, 360: 108771
[19] Savadogo P, Sawadogo L, Tiveau D. Effects of grazing intensity and prescribed fire on soil physical and hydrological properties and pasture yield in the savanna woodlands of Burkina Faso. Agriculture, Ecosystems and Environment, 2007, 118: 80-92
[20] Wu GL, Liu ZH, Zhang L, et al. Long-term fencing improved soil properties and soil organic carbon storage in an alpine swamp meadow of western China. Plant and Soil, 2010, 332: 331-337
[21] Deng L, Sweeney S, Shangguan ZP. Long-term effects of natural enclosure: Carbon stocks, sequestration rates and potential for grassland ecosystems in the Loess Pla-teau. Clean-Soil Air Water, 2014, 42: 617-625
[22] Nelson JDJ, Schoenau JJ, Malhi SS. Soil organic carbon changes and distribution in cultivated and restored grassland soils in Saskatchewan. Nutrient Cycling in Agroecosystems, 2008, 82: 137-148
[23] Talore DG, Tesfamariam EH, Hassen A, et al. Long-term impacts of grazing intensity on soil carbon sequestration and selected soil properties in the arid Eastern Cape, South Africa. Journal of the Science of Food and Agriculture, 2016, 96: 1945-1952
[24] Speed JD, Martinsen V, Mysterud A, et al. Long-term increase in aboveground carbon stocks following exclusion of grazers and forest establishment in an alpine ecosystem. Ecosystems, 2014, 17: 1138-1150
[25] Lehmann J, Kleber M. The contentious nature of soil organic matter. Nature, 2015, 528: 60-68
[26] Sokol NW, Bradford MA. Microbial formation of stable soil carbon is more efficient from belowground than aboveground input. Nature Geoscience, 2019, 12: 46-53
[27] Cotrufo MF, Ranalli MG, Haddix ML, et al. Soil carbon storage informed by particulate and mineral-associated organic matter. Nature Geoscience, 2019, 12: 989-994
[28] 瞿晴. 放牧草地土壤有机碳固持对禁牧的响应机制. 博士论文. 北京: 中国科学院大学, 2024
[29] Georgiou K, Jackson RB, Vindušková O, et al. Global stocks and capacity of mineral-associated soil organic carbon. Nature Communications, 2022, 13: 3797
[30] Qin S, Kou D, Mao C, et al. Temperature sensitivity of permafrost carbon release mediated by mineral and microbial properties. Science Advances, 2021, 7: eabe3596
[31] Powers JS, Schlesinger WH. Geographic and vertical patterns of stable carbon isotopes in tropical rain forest soils of Costa Rica. Geoderma, 2022, 109: 141-160
[32] Bai XJ, Guo ZH, Huang YM, et al. Root cellulose drives soil fulvic acid carbon sequestration in the grassland restoration process. Catena, 2020, 191: 104575
[33] Dong L, Zheng Y, Martinsen V, et al. Effect of grazing exclusion and rotational grazing on soil aggregate stabi-lity in typical grasslands in Inner Mongolia, China. Frontiers in Environmental Science, 2022, 10: 844151
[34] 葛体达, 王东东, 祝贞科, 等. 碳同位素示踪技术及其在陆地生态系统碳循环研究中的应用与展望. 植物生态学报, 2020, 44(4): 360-372
[35] Shahzad T, Chenu C, Genet P, et al. Contribution of exudates, arbuscular mycorrhizal fungi and litter depositions to the rhizosphere priming effect induced by grassland species. Soil Biology and Biochemistry, 2015, 80: 146-155
[36] Liang C, Schimel JP, Jastrow JD. The importance of anabolism in microbial control over soil carbon storage. Nature Microbiology, 2017, 2: 17105
[37] Ebrahimi A, Or D. Microbial community dynamics in soil aggregates shape biogeochemical gas fluxes from soil profiles: Upscaling an aggregate biophysical model. Global Change Biology, 2016, 22: 3141-3156
[38] Angst G, Mueller KE, Gel-Knabner I, et al. Aggregation controls the stability of lignin and lipids in clay-sized particulate and mineral associated organic matter. Biogeochemistry, 2017, 132: 307-324
[39] Gentile R, Vanlauwe B, Six J. Litter quality impacts short-but not long-term soil carbon dynamics in soil aggregate fraction. Ecological Applications, 2011, 21: 695-703
[40] Guo XW, Luo ZK, Sun QJX. Long-term litter type treatments alter soil carbon composition but not microbial carbon utilization in a mixed pine-oak forest. Biogeochemistry, 2021, 152: 327-343
[41] Dijkstra FA, Zhu B, Cheng W. Root effects on soil organic carbon: A double-edged sword. New Phytologist, 2021, 230: 60-65
[42] Jex CN, Pate GH, Blyth AJ, et al. Lignin biogeoche-mistry: From modern processes to Quaternary archives. Quaternary Science Reviews, 2014, 87: 46-59
[43] Sokol NW, Sanderman J, Bradford MA. Pathways of mineral-associated soil organic matter formation: Integrating the role of plant carbon source, chemistry, and point of entry. Global Change Biology, 2019, 25: 12-24
[44] Xia S, Song Z, Wang W, et al. Patterns and determinants of plant-derived lignin phenols in coastal wetlands: Implications for organic C accumulation. Functional Ecology, 2023, 37: 1067-1081
[45] Finn D, Kopittke PM, Dennis PG, et al. Microbial energy and matter transformation in agricultural soils. Soil Biology and Biochemistry, 2017, 111: 176-192
[46] Zhang C, Li J, Wang J, et al. Decreased temporary turnover of bacterial communities along soil depth gra-dient during a 35-year grazing exclusion period in a semi-arid grassland. Geoderma, 2019, 351: 49-58
[47] Bahn M, Lattanzi FA, Hasibeder R, et al. Responses of belowground carbon allocation dynamics to extended shading in mountain grassland. New Phytologist, 2013, 198: e126
[48] Marian F, Brown L, Sandmann D, et al. Roots, mycorrhizal fungi and altitude as determinants of litter decomposition and soil animal communities in tropical montane rainforests. Plant and Soil, 2019, 438: 1-18
[49] Morales-Londoño DM, Meyer E, Kunze A, et al. Are microbial activity and arbuscular mycorrhizal fungal community influenced by regeneration stages? A case study in Southern Brazil coastal Atlantic Rain Forest. Applied Soil Ecology, 2019, 138: 94-98
[50] Yang Y, Wu L, Lin Q, et al. Responses of the functio-nal structure of soil microbial community to livestock grazing in the Tibetan alpine grassland. Global Change Biology, 2013, 19: 637-648
[51] Waring BG. Exploring relationships between enzyme activities and leaf litter decomposition in a wet tropical forest. Soil Biology and Biochemistry, 2013, 64: 89-95
[52] Sinsabaugh RL. Phenol oxidase, peroxidase and organic matter dynamics of soil. Soil Biology and Biochemistry, 2010, 42: 391-404
[53] Burns RG, DeForest JL, Marxsen J, et al. Soil enzymes in a changing environment: Current knowledge and future directions. Soil Biology and Biochemistry, 2013, 58: 216-234
[54] Gunina A, Dippold M, Glaser B, et al. Turnover of microbial groups and cell components in soil: ¹³C analysis of cellular biomarkers. Biogeosciences, 2017, 14: 271-283
[55] 梁超, 朱雪峰, 土壤微生物碳泵储碳机制概论. 中国科学: 地球科学, 2021, 51: 680-695
[56] Mosier S, Paustian K, Davies C, et al. Soil organic matter pools under management intensification of loblo-lly pine plantations. Forest Ecology and Management, 2019, 447: 60-66
[57] Wang BR, An SS, Liang C, et al. Microbial necromass as the source of soil organic carbon in global ecosystems. Soil Biology and Biochemistry, 2021, 162: 108422
[58] Ma T, Zhu SS, Wang ZH, et al. Divergent accumulation of microbial necromass and plant lignin components in grassland soils. Nature Communications, 2018, 9: 3480
[59] Adamczyk B, Sietiö OM, Biasi C, et al. Interaction between tannins and fungal necromass stabilizes fungal residues in boreal forest soils. New Phytologist, 2019, 223: 16-21
[60] Vidal A, Klöffel T, Guigue J, et al. Visualizing the transfer of organic matter from decaying plant residues to soil mineral surfaces controlled by microorganisms. Soil Biology and Biochemistry, 2021, 160: 109347
[61] Zheng Y, Hu Z, Pan X, et al. Carbon and nitrogen transfer from litter to soil is higher in slow than rapid decomposing plant litter: A synthesis of stable isotope studies. Soil Biology and Biochemistry, 2021, 156: 108196

退牧还草地土壤有机碳固持动态与驱动机制研究进展

Dynamics and driving mechanisms of soil organic carbon sequestration in grasslands after grazing exclusion: A review.

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	冯清山, 毛勤江, 马建国, 李玉满, 杨小倩, 鲁星鑫, 王晓波. 土壤氢肥效应的微生物学机制 [J]. 应用生态学报, 2024, 35(9): 2382-2391.
[2]	安韶山, 胡洋, 王宝荣. 黄土高原植被恢复中土壤有机碳稳定机制研究进展 [J]. 应用生态学报, 2024, 35(9): 2413-2422.
[3]	孙瑞丰, 韩广轩. 模拟增温对土壤有机碳含量、组分和化学结构的影响: 进展与展望 [J]. 应用生态学报, 2024, 35(9): 2432-2444.
[4]	高闻哲, 李廷强. 不同钝化剂对土壤有机碳转化的影响及作用机制研究进展 [J]. 应用生态学报, 2024, 35(8): 2291-2300.
[5]	张康, 李佳佳, 魏振浩, 樊妙春, 上官周平. 利用土壤化学计量学和酶计量学揭示刺槐林土壤微生物的养分限制状况 [J]. 应用生态学报, 2024, 35(7): 1799-1806.
[6]	杨钧, 王瑞霞, 王俊, 于双, 杨博, 王文强, 杨君珑, 李小伟. 毛乌素沙地不同恢复年限柠条固沙林微生物群落特征及其影响因素 [J]. 应用生态学报, 2024, 35(7): 1807-1814.
[7]	许晓月, 邵珍珍, 薛娟, 侯春雨, 周磊, 任晓, 王玉英, 吴鹏飞. 川西北高寒区一年生禾本科人工草地土壤节肢动物群落动态 [J]. 应用生态学报, 2024, 35(7): 1959-1967.
[8]	王宇昕, 赵文智, 刘鹄. 生态系统突变及其在寒旱区生态系统管理中的应用展望 [J]. 应用生态学报, 2024, 35(7): 1997-2005.
[9]	韩子琛, 郭强, 夏允, 杨柳明, 范跃新, 杨玉盛. 亚热带三种林分土壤酶活性和酶化学计量比特征 [J]. 应用生态学报, 2024, 35(6): 1501-1508.
[10]	王燚, 李文珊, 展鹏飞, 王行. 若尔盖高原泥炭沼泽土壤微生物空间分布 [J]. 应用生态学报, 2024, 35(6): 1705-1715.
[11]	王译庆, 袁朝祥, 岳楷, 吴福忠, 袁吉, 赵泽敏, 彭艳. 植被恢复对矿区土壤微生物群落结构影响的整合分析 [J]. 应用生态学报, 2024, 35(4): 1141-1149.
[12]	洪宣生, 王宗星, 徐清福, 邱勇斌, 成向荣. 杉木+闽楠复层林土壤氮磷组分及微生物性状随林龄变化特征 [J]. 应用生态学报, 2024, 35(3): 622-630.
[13]	张羽涵, 李瑶, 周玥, 陈圆佳, 安韶山. 宁南山区不同恢复年限柠条林土壤养分及有机碳组分变化特征 [J]. 应用生态学报, 2024, 35(3): 639-647.
[14]	杨雪, 曹霞, 白冰, 袁艳娜, 张宁, 谢洋, 武春成. 根施生物炭对设施连作土壤氮素转化及黄瓜幼苗根系氮代谢的影响 [J]. 应用生态学报, 2024, 35(3): 713-720.
[15]	李佳玉, 施秀珍, 李帅军, 王振宇, 王建青, 邹秉章, 王思荣, 黄志群. 杉木人工林和天然次生林林龄对土壤酶活性的影响 [J]. 应用生态学报, 2024, 35(2): 339-346.