首页 > 过刊浏览>2024年第61卷第5期 >1260-1270. DOI:10.11766/trxb202305220077
PDF HTML阅读 XML下载 导出引用 引用提醒
不同气候条件下土壤有机碳水热响应驱动机制研究
作者:
中图分类号:

S153.6

基金项目:

中国科学院 A类战略性先导科技专项(XDA28030102)资助


Driving Mechanism of Soil Organic Carbon Response to Increase Hydrothermal Conditions in Different Climatic Regimes
Author:
Fund Project:

Strategic Priority Research Program of the Chinese Academy of Sciences

  • 摘要
    • | |
  • 访问统计
    • |
  • 参考文献 [49]
    • | | | |
  • 文章评论
    摘要:

    土壤有机碳(SOC)是陆地生态系统中最大的碳库,其对气候变化的响应直接影响全球碳循环。然而,关于土壤有机碳对长期水热变化的响应及其微生物调控机制尚不清楚。借助跨气候带土壤移置试验平台,开展了一项8年的土壤移置试验,其中将寒温带地区(中国海伦)的黑土剖面移置到温带和中亚热带地区(即封丘和鹰潭)来模拟土壤水热条件增加。水热增加提高了植被生物量,地上部植株C/N与微生物酶活性;降低了土壤有机碳、全氮、微生物残体碳(MNC)和活性矿物的相对含量。并且,微生物残体碳对有机碳的贡献也随着水热条件的增加而降低。通过计算DMNC/DSOC以表征水热增加后微生物残体碳损失速率。结果发现,DMNC/DSOC随着水热条件的增加而显著增加,封丘地区为72.50%± 9.35%,而在鹰潭达到了82.67% ± 2.37%。重要的是,土壤活性矿物的变化与DMNC/DSOC呈强烈的负相关关系,突出了矿物保护在调控DMNC/DSOC发挥的关键作用。这些结果表明,水热增加降低了土壤矿物对微生物残体碳的保护和/或刺激了土壤中微生物对微生物残体碳的利用,通过减少微生物残体碳促进了有机碳的显著损失。

    Abstract:

    The Mollisol in north-eastern China is rich in organic matter, which supports high crop yields and agricultural production. Soil organic carbon (SOC) is the largest carbon pool in terrestrial ecosystems, which responds to climate change directly affects the global carbon cycle. Understanding the response of SOC to increased hydrothermal conditions is important for soil conservation in the context of global climate change. 【Objective】This study aimed to analyze the response of SOC to long-term increasing hydrothermal conditions and their driving factors. 【Method】Based on a soil transplantation experiment, large transects of Mollisol in a cold temperate region (Hailun, HL) were translocated to warm temperate (Fengqiu, FQ) and mid-subtropical (Yingtan, YT) regions to simulate the increasing conditions of MAT and MAP. The experiment was started in 2005, soil samples were collected in August 2013. The SOC and microbial necromass C (MNC) were measured to investigate the changes and drivers of SOC after 8 years of increasing hydrothermal conditions.【Results】The results showed that the increased hydrothermal conditions increased plant biomass, litter C/N, and potential activities of hydrolytic enzymes while decreasing the content of SOC, MNC and soil activity minerals. Moreover, the contribution of MNC to SOC also decreased as hydrothermal conditions increased. The ratio of DMNC and DSOC was calculated to characterize the change in microbial necromass C per unit decrease in SOC, which could be considered a quantitative representation of necromass loss efficiency. DMNC/DSOC increased with increasing hydrothermal activity, with values of 72.50% ± 9.35% in FQ and 82.67% ± 2.37% in YT. The correlation and Random forest analysis showed that DMNC/DSOC positively correlated with the changes in MAT, MAP, α-D-Glucosidase, β-N-Acetyl Glucosaminidase, plant biomass and Straw C/N, while negatively correlated with the changes in pH, poorly crystalline Fe and Al oxyhydroxides, organically complexed Fe and Al, and exchangeable Ca. Structural equation modeling (SEM) indicated that DMNC/DSOC increased with increasing hydrothermal conditions, while decreased with soil mineral protection, with standardized coefficients of 0.64 and -0.24, respectively. It was confirmed in the variance partitioning analysis (VPA), which showed that hydrothermal conditions together with changes in soil mineral protection explained 83.69% of the variance in DMNC/DSOC. The above results indicate that hydrothermal conditions and soil mineral protection play decisive role in regulating DMNC/DSOC. 【Conclusion】In conclusion, long-term increases in hydrothermal conditions reduce the protection of MNC by soil minerals and/or stimulate the utilization of MNC by soil microorganisms. As evidenced by increased soil N limitation that allowed microbes to decompose more MNC and weakened the conservation capacity of minerals for MNC, contributing to the significant loss of SOC by reducing MNC.

    参考文献
    [1] Schmidt M W I,Torn M S,Abiven S,et al. Persistence of soil organic matter as an ecosystem property[J]. Nature,2011,478:49-56.
    [2] Bradford M A,Wieder W R,Bonan G B,et al. Managing uncertainty in soil carbon feedbacks to climate change[J]. Nature Climate Change,2016,6:751-758.
    [3] Chen L Y,Liu L,Mao C,et al. Nitrogen availability regulates topsoil carbon dynamics after permafrost thaw by altering microbial metabolic efficiency[J]. Nature Communications,2018,9:3951
    [4] He Y,Trumbore S E,Torn M S,et al. Radiocarbon constraints imply reduced carbon uptake by soils during the 21st century[J]. Science,2016,353:1419-1424.
    [5] Shi Z,Allison S D,He Y J,et al. The age distribution of global soil carbon inferred from radiocarbon measurements[J]. Nature Geoscience,2020,13:555-559.
    [6] He M,Fang K,Chen L,et al. Depth-dependent drivers of soil microbial necromass carbon across Tibetan alpine grasslands[J]. Global Change Biology,2022,28:936-949.
    [7] Xue K,Yuan M M,Shi Z J,et al. Tundra soil carbon is vulnerable to rapid microbial decomposition under climate warming[J]. Nature Climate Change,2016,6:595-600.
    [8] Chen Y,Han M G,Yuan X,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,2022,28:1618-1629.
    [9] Yuan X,Chen Y,Qin W K,et al. Plant and microbial regulations of soil carbon dynamics under warming in two alpine swamp meadow ecosystems on the Tibetan Plateau[J]. Science of the Total Environment,2021,790:148072.
    [10] Wang X X,Dong S K,Gao Q Z,et al. Effects of short-term and long-term warming on soil nutrients,microbial biomass and enzyme activities in an alpine meadow on the Qinghai-Tibet Plateau of China[J]. Soil Biology & Biochemistry,2014,76:140-142.
    [11] Kong Y L,Qin H,Zhu C Q,et al. Research progress on the mechanism by which soil microorganisms affect soil health[J]. Acta Pedologica Sinica,DOI:10.11766/trxb202301200448. [孔亚丽,秦华,朱春权,等. 土壤微生物影响土壤健康的作用机制研究进展[J]. 土壤学报,DOI:10.11766/trxb202301200448.]
    [12] Zhang B,Chen Q,Ding X L,et al. Research progress on accumulation,turnover and stabilization of microbial residues in soil[J]. Acta Pedologica Sinica,2022,59(6):1479-1491. [张彬,陈奇,丁雪丽,等. 微生物残体在土壤中的积累转化过程与稳定机理研究进展[J]. 土壤学报,2022,59(6):1479-1491.]
    [13] Liang C,Amelung W,Lehmann J,et al. Quantitative assessment of microbial necromass contribution to soil organic matter[J]. Global Change Biology,2019,25:3578-3590.
    [14] Lavallee J M,Soong J L,Cotrufo M F. Conceptualizing soil organic matter into particulate and mineral-associated forms to address global change in the 21st century[J]. Global Change Biology,2020,26:261-273.
    [15] Slessarev E,Lin Y,Bingham N,et al. Water balance creates a threshold in soil pH at the global scale[J]. Nature,2016,540:567-569.
    [16] Campo J. Warming to increase cropland carbon sink[J]. Nature Climate Change,2023,13:121-122.
    [17] Qafoku N P,Sumner M E. Adsorption and desorption of indifferent ions in variable charge subsoils:The possible effect of particle interactions on the counter‐ion charge density[J]. Soil Science Society of America Journal,2002,66(4):1231-1239.
    [18] Ma T,Zhu S,Wang Z,et al. Divergent accumulation of microbial necromass and plant lignin components in grassland soils[J]. Nature Communications,2018,9:3480.
    [19] Chen Y,Han M,Yuan X,et al. Long-term warming reduces surface soil organic carbon by reducing mineral-associated carbon rather than “free” particulate carbon[J]. Soil Biology & Biochemistry,2023,177:108905.
    [20] Ni H,Jing X,Xiao X,et al. Microbial metabolism and necromass mediated fertilization effect on soil organic carbon after long-term community incubation in different climates[J]. The ISME Journal,2021,15:2561-2573.
    [21] Zhou R,Liu Y,Dungait J A J,et al. Microbial necromass in cropland soils:A global meta-analysis of management effects[J]. Global Change Biology,2023,29:1998- 2014.
    [22] Yin L,Dijkstra F A,Wang P,et al. Rhizosphere priming effects on soil carbon and nitrogen dynamics among tree species with and without intraspecific competition[J]. New Phytologist,2018,218(3):1036-1048.
    [23] Donhauser J,Qi W,Bergk-Pinto B,et al. High temperatures enhance the microbial genetic potential to recycle C and N from necromass in high-mountain soils[J]. Global Change Biology,2021,27:1365-1386.
    [24] Cui J,Zhu Z,Xu X,et al. Carbon and nitrogen recycling from microbial necromass to cope with C:N stoichiometric imbalance by priming[J]. Soil Biology & Biochemistry,2020,142:107720.
    [25] Chen X,Lin J,Wang P,et al. Resistant soil carbon is more vulnerable to priming effect than active soil carbon[J]. Soil Biology & Biochemistry,2022,168:108619.
    [26] Rinnan R,Michelsen A,Bååth E,et al. Fifteen years of climate change manipulations alter soil microbial communities in a subarctic heath ecosystem[J]. Global Change Biology,2007,13:28-39.
    [27] Miller B A,Schaetzl R J. Precision of soil particle size analysis using laser diffractometry[J]. Soil Science Society of America Journal,2012,76:1719-1727.
    [28] Zhu E,Cao Z,Jia J,et al. Inactive and inefficient:Warming and drought effect on microbial carbon processing in alpine grassland at depth[J]. Global Change Biology,2021,27:2241-2253.
    [29] Lalonde K,Mucci A,Ouellet A,et al. Preservation of organic matter in sediments promoted by iron[J]. Nature,2012,483(7388):198-200.
    [30] Gentsch N,Wild B,Mikutta R,et al. Temperature response of permafrost soil carbon is attenuated by mineral protection[J]. Global Change Biology,2018,24:3401-3415.
    [31] Gruba P,Mulder J. Tree species affect cation exchange capacity(CEC)and cation binding properties of organic matter in acid forest soils[J]. Science of the Total Environment,2015,511:655-662.
    [32] Amelung W,Zhang X,Flach K W,et al. Amino sugars in native grassland soils along a climosequence in North America[J]. Soil Science Society of America Journal,1999,63(1):86-92.
    [33] Shao P,Lynch L,Xie H,et al. Tradeoffs among microbial life history strategies influence the fate of microbial residues in subtropical forest soils[J]. Soil Biology and Biochemistry,2021,153:108112.
    [34] Huang R,Crowther T W,Sui Y,et al. High stability and metabolic capacity of bacterial community promote the rapid reduction of easily decomposing carbon in soil[J]. Communications Biology,2021,4:1-12.
    [35] Zhang J,Yu Z,Li Y,et al. Co-elevation of CO2 and temperature enhances nitrogen mineralization in the rhizosphere of rice[J]. Biology Fertility of Soils,2022. https://doi.org/10.1007/s00374-022-01667-4.
    [36] Bai T,Wang P,Qiu Y,et al. Nitrogen availability mediates soil carbon cycling response to climate warming:A meta‐analysis[J]. Global Change Biology,2023,29:2608-2626.
    [37] Liao C,Men X,Wang C,et al. Nitrogen availability and mineral particles contributed fungal necromass to the newly formed stable carbon pool in the alpine areas of Southwest China[J]. Soil Biology & Biochemistry,2022,173:108788.
    [38] Angst G,Mueller K E,Nierop K G J,et al. Plant-or microbial-derived? A review on the molecular composition of stabilized soil organic matter[J]. Soil Biology & Biochemistry,2021,156:108189.
    [39] Chen R,Senbayram M,Blagodatsky S,et al. Soil C and N availability determine the priming effect:microbial N mining and stoichiometric decomposition theories[J]. Global Change Biology,2014,20(7):2356-2367.
    [40] Wang S,Redmile-Gordon M,Shahbaz M,et al. Microbial formation and stabilisation of soil organic carbon is regulated by carbon substrate identity and mineral composition[J]. Geoderma,2022,414:115762.
    [41] Zhang X,Amelung W,Yuan Y,et al. Amino sugar signature of particle size fractions in soils of the native prairie as affected by climate[J]. Soil Science,1998,163:220-229.
    [42] Singh M,Sarkar B,Sarkar S,et al. Stabilization of soil organic carbon as influenced by clay mineralogy[J]. Advances in Agronomy,2018,148:33-84.
    [43] Pasut C,Tang F H M,Maggi F. A mechanistic analysis of wetland biogeochemistry in response to temperature,vegetation,and nutrient input changes[J]. Journal of Geophysical Research:Biogeosciences,2020,125(4):e2019JG005437.
    [44] Hemingway J D,Rothman D H,Grant K E,et al. Mineral protection regulates long-term global preservation of natural organic carbon[J]. Nature,2019,570(7760):228-231.
    [45] Zimmerman A R,Ahn M Y. Organo-mineral-enzyme interaction and soil enzyme activity[M]// Shukla G,Varma A. Soil enzymology. Berlin,Heidelberg:Springer,2010:271-292.
    [46] Huang W,Kuzyakov Y,Niu S,et al. Drivers of microbially and plant-derived carbon in topsoil and subsoil[J]. Global Change Biology,2023,29:6188-6200.
    [47] Pronk G J,Heister K,Kögel-Knabner I. Amino sugars reflect microbial residues as affected by clay mineral composition of artificial soils[J]. Organic Geochemistry,2015,83/84:109-113.
    [48] Keiluweit M,Bougoure J J,Nico P S,et al. Mineral protection of soil carbon counteracted by root exudates[J]. Nature Climate Change,2015,5:588-595.
    [49] Griepentrog M,Bodé S,Boeckx P,et al. Nitrogen deposition promotes the production of new fungal residues but retards the decomposition of old residues in forest soil fractions[J]. Global Change Biology,2014,20:327-340.
    相似文献
    引证文献
    网友评论
    网友评论
    分享到微博
    发 布
引用本文

黄伟根,倪浩为,黄瑞林,王晓玥,孙波,梁玉婷.不同气候条件下土壤有机碳水热响应驱动机制研究[J].土壤学报,2024,61(5):1260-1270. DOI:10.11766/trxb202305220077 HUANG Weigen, NI Haowei, HUANG Ruilin, WANG Xiaoyue, SUN Bo, LIANG Yuting. Driving Mechanism of Soil Organic Carbon Response to Increase Hydrothermal Conditions in Different Climatic Regimes[J]. Acta Pedologica Sinica,2024,61(5):1260-1270.

复制
分享
文章指标
  • 点击次数:212
  • 下载次数: 2501
  • HTML阅读次数: 1056
  • 引用次数: 0
历史
  • 收稿日期:2023-05-22
  • 最后修改日期:2023-08-16
  • 录用日期:2023-12-11
  • 在线发布日期: 2024-01-15
文章二维码
今日访问量:2157 您是第8277112 位访问者
通讯地址:江苏省南京市江宁区麒麟街道创优路298号 邮政编码:211135 电话:025-86881237
网址:http://pedologica.issas.ac.cn/ E-mail:actapedo@issas.ac.cn
版权所有:《土壤学报》编辑部 技术支持:北京勤云科技发展有限公司 ICP:05004320号-1