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

doi:10.16258/j.cnki.1674-5906.2026.05.005

生态环境学报 ›› 2026, Vol. 35 ›› Issue (5): 714-724.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

邱锡香¹^,²(), 罗义豪¹^,², 周健闪¹^,², 张昆¹^,²^,³, 张银烽¹^,²^,³^,^*()

¹ 云南省高原湿地保护修复与生态服务重点实验室/西南林业大学，云南昆明 650224
² 西南林业大学生态与环境学院（湿地学院）/国家高原湿地研究中心，云南昆明 650224
³ 香格里拉普达措国家公园碧塔海高原湿地生态系统云南省野外科学观测研究站，云南香格里拉 674400

收稿日期:2025-08-07 修回日期:2025-12-16 接受日期:2025-12-23 出版日期:2026-05-18 发布日期:2026-05-08
通讯作者: *E-mail: zhangyf16@swfu.edu.cn
作者简介:邱锡香（2000年生），女，硕士研究生，研究方向为土壤有机碳。E-mail: qiuxixiang973@163.com
基金资助:
云南省科学技术厅农业联合专项面上项目(202301BD070001-250);国家自然科学基金地区基金项目(32360291)

Characteristics and Controlling Factors of Iron-Bound Organic Carbon in Typical Plateau Wetland of Northwest Yunnan

QIU Xixiang¹^,²(), LUO Yihao¹^,², ZHOU Jianshan¹^,², ZHANG Kun¹^,²^,³, ZHANG Yinfeng¹^,²^,³^,^*()

¹ Yunnan Key Laboratory of Plateau Wetland Conservation, Restoration and Ecological Services/Southwest Forestry University, Kunming 650224, P. R. China
² College of Ecology and Environment (Wetland College), Southwest Forestry University/National Plateau Wetlands Research Center, Kunming 650224, P. R. China
³ Shangri-La Potatso National Park Bita Lake Plateau Wetland Ecosystem Observation and Research Station of Yunnan Province, Shangri-La 674400, P. R. China

Received:2025-08-07 Revised:2025-12-16 Accepted:2025-12-23 Online:2026-05-18 Published:2026-05-08

摘要/Abstract

摘要：

铁氧化物介导的矿物保护是土壤有机碳长期固存的核心机制。为探究湿地土壤铁结合态有机碳（Fe-OC）含量特征，铁形态及其调控因素，该研究以滇西北弥里塘高原湿地及周边草地、森林为对象，对比分析不同生态系统表层土壤中Fe-OC的含量特征、铁赋存形态及其调控因素。结果表明：1）湿地Fe-OC质量分数[（33.3±42.6）]g∙kg⁻¹]显著高于森林[（12.8±8.7）g∙kg⁻¹，p<0.01]和草地[（17.3±17.0）g∙kg⁻¹，p<0.05]；2）Fe-OC与总有机碳（TOC）、碳铁摩尔比（OC/Fe）、Fe-OC占TOC比例（f_(Fe-OC)）、全氮（TN）均呈显著正相关（p<0.05），表明土壤TOC的空间异质性是影响Fe-OC含量特征的主要因素；3）湿地、草地与森林土壤中的铁均以有机结合态和金属有机物络合态为主，其次为铁-锰氧化物结合态，土壤水分质量分数、OC/Fe和TOC是调控土壤中铁形态的主要因素；4）主成分分析结果显示，湿地与森林之间存在较为明显的差异，其中湿地土壤特征主要由碳指标（Fe-OC，OC/Fe，TOC）驱动，而森林土壤则由有机结合态铁矿物驱动，草地土壤作为二者间的过渡区域则受到碳指标和铁矿物形态的共同影响。该研究揭示了由土壤水分质量分数差异驱动的TOC空间异质性、营养盐和铁形态等关键Fe-OC含量特征驱动因素，为高原湿地碳管理提供科学依据。

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

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.

Key words: iron-bound organic carbon, plateau wetlands, soil organic carbon, carbon sequestration, controlling factors

中图分类号:

S153
X144

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.

QIU Xixiang, LUO Yihao, ZHOU Jianshan, ZHANG Kun, ZHANG Yinfeng. Characteristics and Controlling Factors of Iron-Bound Organic Carbon in Typical Plateau Wetland of Northwest Yunnan[J]. Ecology and Environmental Sciences, 2026, 35(5): 714-724.

图/表 7

图1 弥里塘各地类采样点分布图本图基于国家地理信息公共服务平台下载的审图号为GS（2024）0650号的标准地图制作；底图边界无修改

Figure 1 Distribution of sampling sites for each taxon in Militang

图2 湿地、草地和森林土壤中Fe-OC含量 n=3，下同。*表示二者间含量存在显著差异，p<0.05；**表示二者间含量存在显著差异，p<0.01；ns表示表示二者间含量无显著差异；▲表示平均值

Figure 2 Fe-OC content in wetland, grassland, and forest soils

图3 湿地、草地和森林土壤中不同形态铁

Figure 3 Different forms of iron in wetland, grassland, and forest soils

图4 湿地、草地和森林土壤水分质量分数及其与TOC、Fe-OC之间的关系图4（a）中不同小写字母（a、b、c）表示二者间含量存在显著差异，p<0.05；（b）中x表示土壤水分质量分数，y为土壤TOC质量分数；（c）中x表示土壤水分质量分数，y为土壤Fe-OC的质量分数

Figure 4 Soil moisture content in wetlands, grasslands, and forests and their relationships with TOC and Fe-OC

图5 土壤Fe-OC含量与土壤理化性质和铁形态的相关性 *表示二者间含量存在显著相关性，p<0.05；**表示二者间含量存在更显著的相关性，p<0.01；***表示二者间含量存在极显著相关，p<0.001

Figure 5 Correlation between soil Fe-OC content and soil physicochemical properties and iron forms

图6 土壤中Fe-OC与理化性质的主成分分析（PCA）

Figure 6 Principal component analysis (PCA) of Fe-OC and physicochemical properties in soil

表1 本研究土壤TOC和Fe-OC与其他地区比较

Table 1 Comparison of total soil organic carbon and iron-bound organic carbon in this study with other regions

地点	类型	w_TOC/(g∙kg⁻¹)	w_Fe-OC/(g∙kg⁻¹)	参考文献
中国南黄海	海底沉积物	7.5±3.5	0.08±0.08	Ma et al.， 2018
青藏高原	泥炭沉积物	184－325	9.49±6.2	Huang et al.， 2021
滦海子湿地	泥炭沉积物	125.1±33.8	89.8±3.1	Wang et al.， 2017
闽江河口湿地	潮汐湿地沉积物	27.9±2.6	1.8±0.01	林于蓝等， 2022
蜡湖三角洲	三角洲沉积物	6.2±1.1	0.7±0.6	Shields et al.， 2016
大兴安岭湿地	泥炭沉积物	236.6±11.4	51.5±3.1	Liu et al.， 2024
鄱阳湖湿地	湖沼相沉积物（0－10 cm）	34.7±3.2	2.3±0.8	徐晨瀛等， 2024
弥里塘	森林表层土	108.46±110.76	12.8±8.7	本研究
弥里塘	草地表层土	219.39±132.89	17.3±17.0	本研究
弥里塘	湿地表层土	280.32±83.58	33.3±42.6	本研究

参考文献 44

[1]	ADHIKARI D, POULSON S R, SUMAILA S, et al., 2016. Asynchronous reductive release of iron and organic carbon from hematite-humic acid complexes[J]. Chemical Geology, 430: 13-20.
[2]	BAI J, LUO M, YANG Y, et al., 2021. Iron-bound carbon increases along a freshwater-oligohaline gradient in a subtropical tidal wetland[J]. Soil Biology and Biochemistry, 154: 108128. DOI URL
[3]	BOWLES J F W, 1997. The iron oxides: structure, properties reactions occurrence and uses[J]. Mineralogical Magazine, 61(408): 740-741. DOI URL
[4]	CHEN C, HALL S J, COWARD E, et al., 2020. Iron-mediated organic matter decomposition in humid soils can counteract protection[J]. Nature Communications, 11(1): 2255. DOI PMID
[5]	CHEN C M, THOMPSON A, 2021. The influence of native soil organic matter and minerals on ferrous iron oxidation[J]. Geochimica et Cosmochimica Acta, 292: 254-270.
[6]	CHEN W, CHEN W X, DONG K, et al., 2024. Iron-bound organic carbon distribution in freshwater wetlands with varying vegetation and hydrological regime[J]. Wetlands, 44(6): 71. DOI
[7]	DICEN G P, NAVARRETE I A, RALLOS R V, et al., 2019. The role of reactive iron in long-term carbon sequestration in mangrove sediments[J]. Journal of Soils and Sediments, 19(1): 501-510. DOI
[8]	DUAN X, YU X F, LI Z, et al., 2020. Iron-bound organic carbon is conserved in the rhizosphere soil of freshwater wetlands[J]. Soil Biology and Biochemistry, 149: 107949. DOI URL
[9]	FAN Z X, BRäUNING A, THOMAS A, et al., 2010. Spatial and temporal temperature trends on the Yunnan Plateau (Southwest China) during 1961-2004[J]. International Journal of Climatology, 31(14): 2078-2090. DOI URL
[10]	FENG X J, ZHAO Y P, WANG H Q, et al., 2025. Iron-organic carbon interactions in wetlands: implications for wetland carbon preservation under global changes[J]. Global Change Biology, 31(6): e70300. DOI URL
[11]	FREEMAN C, JOHN OSTLE N, KANG H, 2001. An enzymic ‘latch’ on a global carbon store - A shortage of oxygen locks up carbon in peatlands by restraining a single enzyme[J]. Nature, 409: 149.
[12]	FRØSETH R B, BLEKEN M A, 2015. Effect of low temperature and soil type on the decomposition rate of soil organic carbon and clover leaves, and related priming effect[J]. Soil Biology and Biochemistry, 80: 156-166. DOI URL
[13]	GENTSCH N, WILD B, MIKUTTA R, et al., 2018. Temperature response of permafrost soil carbon is attenuated by mineral protection[J]. Global Change Biology, 24(8): 3401-3415. DOI PMID
[14]	HUANG X Y, LIU X W, LIU J L, et al., 2021. Iron-bound organic carbon and their determinants in peatlands of China[J]. Geoderma, 391: 114974. DOI URL
[15]	JIA N, LI L, GUO H, et al., 2024. Important role of Fe oxides in global soil carbon stabilization and stocks[J]. Nature Communications, 15(1): 10318. DOI
[16]	LALONDE K, MUCCI A, OUELLET A, et al., 2012. Preservation of organic matter in sediments promoted by iron[J]. Nature, 483(7388): 198-200. DOI
[17]	LI Y, HOU Z, ZHANG L, 2023. Long-term spatio-temporal changes of wetlands in Tibetan Plateau and their response to climate change[J]. International Journal of Applied Earth Observation and Geoinformation 121: 103351. DOI URL
[18]	LIU C Z, ZHAO Y P, MA L X, et al., 2024. Metallic protection of soil carbon: divergent drainage effects in Sphagnum vs. non-Sphagnum wetlands[J]. National Science Review, 11(11): nwae178.
[19]	LIU F T, QIN S Q, FANG K, et al., 2022b. Divergent changes in particulate and mineral-associated organic carbon upon permafrost thaw[J]. Nature Communications, 13(1): 5073. DOI
[20]	LIU F, WU H Y, ZHAO Y G, et al., 2022c. Mapping high resolution National Soil Information Grids of China[J]. Science Bulletin, 67(3): 328-340. DOI URL
[21]	LIU L F, CHEN H, TIAN J Q, 2022a. Varied response of carbon dioxide emissions to warming in oxic, anoxic and transitional soil layers in a drained peatland[J]. Communications Earth & Environment, 3(1): 313.
[22]	MA W W, ZHU M X, YANG G P, et al., 2018. Iron geochemistry and organic carbon preservation by iron (oxyhydr)oxides in surface sediments of the East China Sea and the south Yellow Sea[J]. Journal of Marine Systems, 178: 62-74. DOI URL
[23]	MITSCH W J, BERNAL B, NAHLIK A M, et al., 2013. Wetlands, carbon, and climate change[J]. Landscape Ecology, 28(4): 583-597. DOI URL
[24]	NICHOLS J E, PETEET D M, 2019. Rapid expansion of northern peatlands and doubled estimate of carbon storage[J]. Nature Geoscience, 12(11): 917-921. DOI
[25]	PATZNER M S, MUELLER C W, MALUSOVA M, et al., 2020. Iron mineral dissolution releases iron and associated organic carbon during permafrost thaw[J]. Nature Communications, 11(1): 6329. DOI PMID
[26]	POULTON S W, RAISWELL R, 2005. Chemical and physical characteristics of iron oxides in riverine and glacial meltwater sediments[J]. Chemical Geology, 218(3): 203-221. DOI URL
[27]	SHIELDS M R, BIANCHI T S, GÉLINAS Y, et al., 2016. Enhanced terrestrial carbon preservation promoted by reactive iron in deltaic sediments[J]. Geophysical Research Letters, 43(3): 1149-1157. DOI URL
[28]	ŠKERLEP M, NEHZATI S, JOHANSSON U, et al., 2022. Spruce forest afforestation leading to increased Fe mobilization from soils[J]. Biogeochemistry, 157(3): 273-290. DOI
[29]	SOKOL N W, WHALEN E D, JILLING A, et al., 2022. Global distribution, formation and fate of mineral- associated soil organic matter under a changing climate: A trait-based perspective[J]. Functional Ecology, 36(6): 1411-1429. DOI URL
[30]	SONG X X, LIU T X, 2021. Effects of soil iron mineral transformation on organic carbon sequestration: A review[J]. Acta Ecologica Sinica, 41(20): 7928-7938.
[31]	SUN J F, YUAN X Z, LIU G D, et al., 2019. Emergy and eco-exergy evaluation of wetland restoration based on the construction of a wetland landscape in the northwest Yunnan Plateau, China[J]. Journal of Environmental Management, 252: 109499. DOI URL
[32]	TEMMINK R J M, LAMERS L P M, ANGELINI C, et al., 2022. Recovering wetland biogeomorphic feedbacks to restore the world’s biotic carbon hotspots[J]. Science, 376(6593): eabn1479.
[33]	VOGGENREITER E, THOMASARRIGO L, KILIAN J, et al., 2025. Reduction of iron-organic carbon associations shifts net greenhouse gas release after initial permafrost thaw[J]. Soil Biology and Biochemistry, 203: 109735. DOI URL
[34]	WAN D, YE T H, LU Y, et al., 2019. Iron oxides selectively stabilize plant-derived polysaccharides and aliphatic compounds in agricultural soils[J]. European Journal of Soil Science, 70(6): 1153-1163. DOI URL
[35]	WANG Y Y, LIU X Q, ZHANG X Y, et al., 2022. Evaluating wetland soil carbon stability related to iron transformation during redox oscillations[J]. Geoderma, 428: 116222. DOI URL
[36]	WANG Y Y, WANG H, HE J S, et al., 2017. Iron-mediated soil carbon response to water-table decline in an alpine wetland[J]. Nature Communications, 8(1): 15972. DOI URL
[37]	ZHANG Y M, NAAFS B D A, HUANG X Y, et al., 2022. Variations in wetland hydrology drive rapid changes in the microbial community, carbon metabolic activity, and greenhouse gas fluxes[J]. Geochimica et Cosmochimica Acta, 317: 269-285. DOI URL
[38]	ZHAO B, DOU A M, ZHANG Z W, et al., 2023. Ecosystem-specific patterns and drivers of global reactive iron mineral-associated organic carbon[J]. Biogeosciences, 20(23): 4761-4774. DOI URL
[39]	ZHAO J J, MINASNY B, SETIA R, et al., 2025. Global distribution and predictors of the mineral-associated to total soil organic carbon ratio: An indicator of soil carbon stability[J]. Earth Critical Zone, 2: 100035. DOI URL
[40]	ZHAO Q, ADHIKARI D, HUANG R X, et al., 2017. Coupled dynamics of iron and iron-bound organic carbon in forest soils during anaerobic reduction[J]. Chemical Geology, 464: 118-126. DOI URL
[41]	ZHAO Q, POULSON S R, OBRIST D, et al., 2016. Iron-bound organic carbon in forest soils: quantification and characterization[J]. Biogeosciences, 13(16): 4777-4788. DOI URL
[42]	段勋, 李哲, 刘淼, 等, 2022. 铁介导的土壤有机碳固持和矿化研究进展[J]. 地球科学进展, 37(2): 202-211. DOI
	DUAN X, LI Z, LIU M, et al., 2022. Progress of the iron-mediated soil organic carbon preservation and mineralization[J]. Advances in Earth Science, 37(2): 202-211. DOI
[43]	林于蓝, 陈钰, 尹晓雷, 等, 2022. 围垦养殖与退塘还湿对闽江河口湿地土壤铁碳结合特征的影响[J]. 环境科学学报, 42(7): 466-477.
	LIN Y L, CHEN Y, YIN X L, et al., 2022. Effects of reclamation and pond returning on iron-bound organic carbon characteristics in the soil of Minjiang estuarine wetland[J]. Acta Scientiae Circumstantiae, 42(7): 466-477.
[44]	LUO Q, HE Q, WU H Q, et al., 2024. Characteristics of soil organic carbon fractions in Liao River Estuary Wetland and their influencing factors[J]. Ecology and Environmental Sciences, 33(3): 333-340.
[45]	吴旺喜, 余汉年, 李华禄, 2003. 土壤中不同形态铁的浸取条件研究[J]. 江汉大学学报(自然科学版), 31(4): 64-66.
	WU W X, YU H N, LI H L, 2003. Investigation on extraction conditions for various iron species in soil matrices[J]. Journal of Jianghan University (Natural Sciences), 31(4): 64-66.
[46]	徐晨瀛, 胡启武, 张桂华, 等, 2024. 鄱阳湖湿地剖面土壤铁结合态有机碳沿高程的分布特征[J]. 应用生态学报, 35(12): 3488-3496. DOI
	XU C Y, HU Q W, ZHANG G H, et al., 2024. Distribution characteristics of soil iron-bound organic carbon in profiles along the elevation in Poyang Lake wetland[J]. Chinese Journal of Applied Ecology, 35(12): 3488-3496. DOI
[44]	罗庆, 何清, 吴慧秋, 等, 2024. 辽河口湿地土壤有机碳组分特征及其影响因素[J]. 生态环境学报, 33(3): 333-340. DOI

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

RichHTML

PDF

可视化

摘要/Abstract

引用本文

使用本文

图/表 7

参考文献 44

相关文章 15

编辑推荐

Metrics

本文评价

[1]	石含之, 曹怡然, 刘帆, 吴志超, 李富荣, 邓腾灏博, 徐爱平, 李冬琴, 文典, 王旭. 秸秆与细菌联合作用下土壤铅形态转化的调控研究[J]. 生态环境学报, 2026, 35(1): 155-166.
[2]	唐中奥, 淳祯杰, 段兴武, 张瑞环, 荣丽, 刘文旭. 模拟侵蚀对元江流域黄红壤土壤微生物和土壤有机碳的影响[J]. 生态环境学报, 2026, 35(1): 54-61.
[3]	刘卿, 龚雨顺, 王伟, 方贤滔, 吴金水, 沈健林. 湖南典型茶园土壤有机碳及其组分时空特征[J]. 生态环境学报, 2025, 34(9): 1386-1397.
[4]	申佳龙, 吴栎宏, 李林霜, 周远芳, 杨孝民. 典型喀斯特山地小流域土地利用类型对土壤有机碳组分及其固碳效应的影响[J]. 生态环境学报, 2025, 34(3): 358-367.
[5]	李建付, 黄志霖, 和成忠, 姜昕, 宋琳, 刘佳鑫, 陈利顶. 滇东喀斯特断陷盆地土壤有机碳空间分布特征及其关键影响因子[J]. 生态环境学报, 2024, 33(9): 1339-1352.
[6]	石含之, 熊振乾, 曹怡然, 吴志超, 文典, 李富荣, 李冬琴, 王旭. 外源秸秆添加对红壤及黑土有机碳固定的影响[J]. 生态环境学报, 2024, 33(9): 1372-1383.
[7]	罗庆, 何清, 吴慧秋, 寇力月, 方旭, 张鑫雨, 李缘, 柴育廷, 张瑞生, 代文举. 辽河口湿地土壤有机碳组分特征及其影响因素[J]. 生态环境学报, 2024, 33(3): 333-340.
[8]	林丹丹, 毕华兴, 赵丹阳, 管凝, 韩金丹, 郭艳杰. 晋西黄土区不同密度刺槐林土壤有机碳组分及碳库特征[J]. 生态环境学报, 2024, 33(3): 379-388.
[9]	常博然, 陈茹岚, 王彪, 蓝天, 邓琳, 薛会英. 藏东南折拉山不同林分类型土壤有机碳及其组分分布特征[J]. 生态环境学报, 2024, 33(10): 1495-1505.
[10]	梁鑫, 韩亚峰, 郑柯, 王旭刚, 陈志怀, 杜鹃. 磁铁矿对稻田土壤碳矿化的影响[J]. 生态环境学报, 2023, 32(9): 1615-1622.
[11]	张林, 齐实, 周飘, 伍冰晨, 张岱, 张岩. 北京山区针阔混交林地土壤有机碳含量的影响因素研究[J]. 生态环境学报, 2023, 32(3): 450-458.
[12]	秦佳琪, 肖指柔, 明安刚, 朱豪, 滕金倩, 梁泽丽, 陶怡, 覃林. 针阔人工混交林及其纯林对土壤微生物碳循环功能基因丰度的影响[J]. 生态环境学报, 2023, 32(10): 1719-1731.
[13]	肖国举, 李秀静, 郭占强, 胡延斌, 王静. 贺兰山东麓土壤有机碳对玉米生长发育及水分利用的影响[J]. 生态环境学报, 2022, 31(9): 1754-1764.
[14]	马辉英, 李昕竹, 马鑫钰, 贡璐. 新疆天山北麓中段不同植被类型下土壤有机碳组分特征及其影响因素[J]. 生态环境学报, 2022, 31(6): 1124-1131.
[15]	龚玲玄, 王丽丽, 赵建宁, 刘红梅, 杨殿林, 张贵龙. 不同覆盖作物模式对茶园土壤理化性质及有机碳矿化的影响[J]. 生态环境学报, 2022, 31(6): 1141-1150.