生态环境学报2026,Vol.35Issue(5):714-724,11.DOI:10.16258/j.cnki.1674-5906.2026.05.005
滇西北典型高原湿地土壤铁结合态有机碳含量特征及调控因素
Characteristics and Controlling Factors of Iron-Bound Organic Carbon in Typical Plateau Wetland of Northwest Yunnan
摘要
Abstract
Iron oxides are widely recognized as critical regulators of soil organic carbon(SOC)persistence,since they provide reactive mineral surfaces that facilitate the formation of iron-organic carbon complexes(Fe-OC)which effectively shield organic matter from microbial decomposition and oxidative loss,thereby enabling long-term carbon storage in soils.Wetlands,as globally important ecosystems,play a disproportionately large role in carbon sequestration relative to their land area,acting both as sinks of organic carbon and as regulators of greenhouse gas emissions,and are thus highly relevant for global climate change mitigation.Despite this importance,the stability and mechanisms of SOC preservation in plateau wetlands remain insufficiently understood,particularly in terms of the contribution of Fe-OC,which has been proposed as a key pathway linking mineral protection with ecosystem carbon stability.Understanding the distribution characteristics of Fe-OC and identifying its main controlling factors in different ecosystems are therefore of fundamental importance,since such knowledge provides both theoretical insights into the wetland carbon cycling and practical guidance for wetland conservation and carbon management strategies.Against this backdrop,the present study focused on Militang wetland in northwestern Yunnan,China,a representative high-altitude plateau wetland located within Pudacuo National Park,together with adjacent grassland and forest ecosystems.This region is characterized by distinctive hydrological gradients,diverse vegetation assemblages,and contrasting biogeochemical conditions,which together create an ideal natural laboratory for investigating the regulatory mechanisms of Fe-OC across varying conditions.We systematically examined surface soils(0‒15 cm depth)from these three ecosystems,quantified Fe-OC contents,analyzed iron speciation through sequential extraction approaches,and employed statistical correlation and principal component analysis to determine the major factors influencing Fe-OC distribution and to compare ecosystem-specific patterns.The results demonstrated clear differences in Fe-OC accumulation among ecosystems.Wetland soils contained significantly higher Fe-OC[(33.3±42.6)g∙kg-1]compared to forest soils[(12.8±8.7)g∙kg-1,p<0.01]and grassland soils[(17.3±17.0)g∙kg-1,p<0.05],underscoring the unique capacity of wetlands to promote Fe-OC accumulation.This elevated Fe-OC content can be attributed to the anaerobic or hypoxic conditions characteristic of wetlands,which slow down organic matter decomposition while facilitating the redox cycling of iron.Periodic reduction and reoxidation processes promote the formation of reactive Fe minerals that bind strongly with organic molecules,thereby enhancing carbon preservation.In addition,the high organic matter input and sustained soil moisture typical of wetland environments create favorable conditions for the formation and persistence of Fe-OC complexes.Correlation analyses further revealed significant positive relationships(p<0.05)between Fe-OC and total organic carbon(TOC),the carbon-to-iron molar ratio(OC/Fe),the proportion of Fe-OC relative to TOC(f(Fe-OC)),and total nitrogen(TN),indicating that TOC spatial heterogeneity is the dominant factor controlling Fe-OC content.The quality and quantity of organic matter inputs not only determine the size of the available carbon pool for Fe binding but also influence microbial activity and nutrient cycling processes.The observed correlation with TN suggests that nitrogen availability,through its role in microbial metabolism and organic matter transformation,indirectly enhances Fe-OC formation.Iron speciation analysis revealed that organically bound Fe and metal-organic complexes were the dominant forms of iron across all three ecosystems,followed by Fe-Mn oxide-bound Fe,thereby highlighting the intimate relationship between iron chemistry and organic matter association.The distribution of these iron species was primarily regulated by soil moisture,OC/Fe,and TOC,factors that are closely interlinked in governing redox dynamics and carbon stabilization.In wetlands,periodic flooding and fluctuating redox conditions accelerate the dissolution and reprecipitation of Fe oxides,thereby intensifying interactions with organic matter and reinforcing Fe-OC formation.Principal component analysis revealed distinct ecosystem-specific signatures:wetland soils were strongly associated with carbon-related variables(Fe-OC,OC/Fe,TOC),suggesting that carbon input and accumulation processes are the dominant drivers of Fe-OC dynamics under saturated conditions;forest soils were characterized more by organically bound Fe mineral forms,reflecting the influence of forest litter input and relatively higher organic matter decomposition;grassland soils exhibited an intermediate pattern,where both carbon indicators and iron speciation jointly influenced Fe-OC dynamics,consistent with their transitional position in hydrological and vegetation gradients.Collectively,these results emphasize the crucial role of soil moisture-driven heterogeneity in TOC,along with nutrient status and iron speciation,in shaping Fe-OC characteristics across plateau ecosystems.The elevated Fe-OC levels observed in wetlands reflect not only favorable hydrological and redox conditions but also the synergistic interaction between abundant organic inputs and reactive iron phases.These findings provide novel evidence that wetlands,compared with adjacent grasslands and forests,function as more effective reservoirs for Fe-OC and possibly contribute disproportionately to SOC sequestration.From a management perspective,this suggests that conservation or restoration strategies aimed at maintaining stable water regimes and promoting anaerobic soil conditions are likely to enhance Fe-OC accumulation and improve long-term carbon sequestration in plateau wetlands.Integrating such strategies with vegetation management and microbial process regulation could further strengthen the resilience of these ecosystems to environmental change.It should be noted,however,that this study primarily focused on the quantification of Fe-OC content and associated controlling factors,while the direct mechanistic link between Fe-OC dynamics and carbon fluxes such as CO2 and CH4 emissions remains unquantified.Although the strong correlations with TOC indicate a significant role of Fe-OC in shaping soil carbon pools,the extent to which Fe-OC acts as a stabilizer or amplifier of greenhouse gas emissions under changing environmental conditions requires further investigation.Future research incorporating microscopic characterization techniques such as spectroscopy,isotope tracing approaches,and long-term in situ monitoring of carbon fluxes will be essential to unravel the pathways and stability of Fe-OC and to validate these findings across broader spatial and temporal scales.Such integrative studies would not only deepen our understanding of the wetland carbon cycle but also provide a stronger scientific foundation for modeling the role of plateau wetlands in global carbon budgets and for developing evidence-based strategies for wetland management,conservation,and climate mitigation.关键词
铁结合态有机碳/高原湿地/土壤有机碳/碳固存/调控因素Key words
iron-bound organic carbon/plateau wetlands/soil organic carbon/carbon sequestration/controlling factors分类
农业科技引用本文复制引用
邱锡香,罗义豪,周健闪,张昆,张银烽..滇西北典型高原湿地土壤铁结合态有机碳含量特征及调控因素[J].生态环境学报,2026,35(5):714-724,11.基金项目
云南省科学技术厅农业联合专项面上项目(202301BD070001-250) (202301BD070001-250)
国家自然科学基金地区基金项目(32360291) (32360291)
