Wetland soil carbon storage exceeds uplands in an urban natural area (Florida, USA)

IF 1.2 4区农林科学 Q4 SOIL SCIENCE

Soil Research Pub Date : 2023-01-01 DOI:10.1071/sr22235

Jennifer D. Bennett, Lisa G. Chambers

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引用次数: 0

Abstract

Context . Urban greenspaces and natural areas are often recognised for their cultural services, but may also provide ecological services, including carbon (C) sequestration and storage. Aims . This study investigated the strength of the relationship between easily discernable ecosystem characteristics (e.g. topographic position, vegetation, and soil type) and soil C storage, and evaluated common conversion factors and methodologies used in soil C inventories. Methods . Sixty-seven full-depth (up to 5 m) soil cores were collected across nine community types in University of Central Florida ’ s Arboretum (Orlando, Florida, USA) and were analysed for bulk density, organic matter (OM) content, total C, and total nitrogen (N). Key results . Wetlands stored an average of 16 times more C than uplands and C density increased with soil depth. A 70% underestimation of soil C stocks would have occurred if sampling stopped at 50 cm. A strong linear relationship between soil C and OM supports the use of a 0.56 (C:OM) conversion factor for estimating soil organic C. Conclusions . The presence of wetlands is the key predictor of soil C and N storage, but the magnitude of storage varies widely among wetlands. Overall, the 225-ha study area stored 85 482 ± 3365 Mg of soil C. Implications . Urban natural areas should be evaluated for their ecosystem servicesseparately from their surroundingdevelopedlanduse/land cover with consideration for C storage potential. Leveraging topographic position, a site-speci ﬁ c soil OM conversion factor, and depth to refusal testing can increase the accuracy and cost-effectiveness of soil C inventories.

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城市自然区湿地土壤碳储量超过高地(佛罗里达州，美国)

上下文。城市绿地和自然区域往往因其文化服务而得到认可，但也可能提供生态服务，包括碳(C)的封存和储存。目标本研究调查了易识别的生态系统特征(如地形位置、植被和土壤类型)与土壤C储量之间的关系强度，并评估了土壤C清单中常用的转换因子和方法。方法。在中佛罗里达大学植物园(Orlando, Florida, USA)的9个群落类型中收集了67个全深度(高达5 m)土壤岩心，并对其容重、有机质(OM)含量、总碳和总氮(N)进行了分析。湿地储存的碳平均是高地的16倍，而且碳密度随着土壤深度的增加而增加。如果采样停止在50厘米处，土壤C储量将被低估70%。土壤C和有机质之间存在很强的线性关系，支持使用0.56 (C:OM)转换因子来估算土壤有机C。湿地的存在是土壤碳氮储量的关键预测因子，但不同湿地的碳氮储量差异很大。总体而言，225 ha研究区土壤c含量为85 482±3365 Mg。城市自然区域的生态系统服务应与其周围已开发的土地利用/土地覆盖分开评估，并考虑碳储存潜力。利用地形位置、特定地点的土壤有机质转换因子和深度拒绝测试可以提高土壤有机质清单的准确性和成本效益。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Soil Research SOIL SCIENCE-

CiteScore

3.20

自引率

6.20%

发文量

审稿时长

4.5 months

期刊介绍： Soil Research (formerly known as Australian Journal of Soil Research) is an international journal that aims to rapidly publish high-quality, novel research about fundamental and applied aspects of soil science. As well as publishing in traditional aspects of soil biology, soil physics and soil chemistry across terrestrial ecosystems, the journal welcomes manuscripts dealing with wider interactions of soils with the environment. Soil Research is published with the endorsement of the Commonwealth Scientific and Industrial Research Organisation (CSIRO) and the Australian Academy of Science.