Nitrogen-Fixing Plants Enhance and Stabilize Rhizospheric Soil Organic Carbon in Tropical Rainforests, Hainan Island, China

IF 1.5 4区农林科学 Q2 FORESTRY

Forest Science Pub Date : 2023-08-09 DOI:10.1093/forsci/fxad037

Huai Yang, Shirong Liu, Jingxin Wang, J. Schuler, Yi Wang, Junwei Luan

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引用次数: 0

Abstract

Nitrogen (N)-fixing plants play an important role in stimulating soil nitrogen supply, but the effect of N-fixing plants on soil organic carbon (SOC) sequestration has not been well documented. In this study, we measured rhizospheric carbon components and N content of first to second (1–2)-order and third to fifth (3–5)-order roots of N-fixing and non-N-fixing plants in a montane tropical rainforest in Hainan Island, China, to examine the effects of N-fixing plants on SOC and soil heavy fraction carbon (HFC), and to ascertain the main regulating factors. The results showed that rhizospheric SOC between (1–2) and (3–5)-order roots was 14.2% and 10.5% greater, respectively, for N-fixing plants compared with non-N-fixing plants. Similarly, the HFC was 0.9% (1–2) and 3.6% (3–5) greater for N-fixing plants than non-N-fixing plants. Redundancy analysis showed that spatial variance in rhizospheric SOC and HFC associated with 1–2-order roots was explained by specific root length (SRL) of second-order roots (55.8%) and specific leaf area (SLA) (14.6%), whereas spatial variance was better explained for 3–5 roots by total soil N (44.6%), diameter of fifth-order roots (16.4%), and leaf C (17.9%), respectively. Within the rhizospheric soil of 1–2 roots, N-fixing plants with smaller SRL of second-order roots presented greater SOC and HFC, whereas smaller SLA was associated with greater HFC. By contrast, rhizospheric soil of 3–5 roots under N-fixing plants had greater SOC and HFC levels in environments with higher total soil N and smaller diameters of fifth-order roots. Our study revealed that N-fixing plants enhanced rhizospheric SOC and HFC compared with non-N-fixing plants. The rhizospheric SOC and HFC were correlated strongly by root morphology traits, leaf morphology, and soil properties. Study Implications: In this article, we compared rhizospheric soil of N-fixing and non-N-fixing species in a montane tropical rainforest in Hainan Island, China, to examine the effects of N-fixing plants on SOC and HFC. Our results suggest the N-fixing plants enhance and stabilize rhizospheric SOC and HFC; rhizospheric SOC and HFC for first- to second-order roots of N-fixing plants were mostly negatively regulated by SRL of second-order roots; and N-fixing plants had positive effects on rhizospheric SOC and HFC for third- to fifth-order roots through increased soil N. Understanding these mechanisms could improve and accumulation of soil C sink in tropical areas.

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固氮植物提高和稳定海南岛热带雨林根际土壤有机碳

固氮植物在促进土壤氮供应方面发挥着重要作用，但固氮植物对土壤有机碳(SOC)固存的影响尚未得到很好的研究。本研究通过测定海南山地热带雨林固氮植物和非固氮植物根际一至二(1-2)级根和三至五(3-5)级根的碳组分和氮含量，探讨了固氮植物对土壤有机碳和土壤重碳组分(HFC)的影响，并确定了主要调节因子。结果表明，固氮植物根际土壤有机碳(SOC)在(1-2)和(3-5)级根间分别比非固氮植物高14.2%和10.5%。同样，固氮植物的HFC比非固氮植物高0.9%(1-2)和3.6%(3-5)。冗余分析表明，1 - 2级根的土壤有机碳和土壤碳含量的空间差异可以用二级根的比根长(55.8%)和比叶面积(14.6%)来解释，而3-5级根的土壤全氮(44.6%)、5级根直径(16.4%)和叶碳含量(17.9%)来解释。在1 ~ 2根根际土壤中，二级根SRL越小的固氮植物，其有机碳和HFC越高，而SLA越小，HFC越大。固氮植物3 ~ 5根的根际土壤在全氮高、5级根直径小的环境下具有较高的SOC和HFC水平。研究表明，与非固氮植物相比，固氮植物提高了根际有机碳和氢氟碳含量。根际有机碳和HFC与根系形态、叶片形态和土壤性质密切相关。研究意义:本研究通过对海南岛山地热带雨林根际土壤固氮和非固氮物种的比较，探讨了固氮植物对土壤有机碳和氢氟碳化物的影响。结果表明:固氮植物增强并稳定了根际有机碳和氢氟碳化物;固氮植物一至二级根的根际SOC和HFC主要受二级根SRL的负调控;固氮植物通过增加土壤氮对3 ~ 5级根际有机碳和氢氟碳含量有积极影响，了解这些机制有助于改善热带地区土壤碳汇的积累。

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来源期刊

Forest Science 农林科学-林学

CiteScore

2.80

自引率

7.10%

发文量

审稿时长

3 months

期刊介绍： Forest Science is a peer-reviewed journal publishing fundamental and applied research that explores all aspects of natural and social sciences as they apply to the function and management of the forested ecosystems of the world. Topics include silviculture, forest management, biometrics, economics, entomology & pathology, fire & fuels management, forest ecology, genetics & tree improvement, geospatial technologies, harvesting & utilization, landscape ecology, operations research, forest policy, physiology, recreation, social sciences, soils & hydrology, and wildlife management. Forest Science is published bimonthly in February, April, June, August, October, and December.