Carbon and water exchange in extensive green roofs: A comparison between eddy covariance and soil flux chamber observations

IF 6.7 2区环境科学与生态学 Q1 ENVIRONMENTAL STUDIES

Urban Forestry & Urban Greening Pub Date : 2025-10-03 DOI:10.1016/j.ufug.2025.129099

Patrick Hansen, Jannik Heusinger, Stephan Weber

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Abstract

Vegetated roofs are currently discussed as a mitigation strategy to limit the impact of climate change in urban areas by sequestering carbon dioxide (CO₂) via photosynthetic uptake. Two observational methods, i.e., eddy covariance (EC) and automated soil flux chambers, were co-located on a large extensive green roof in Berlin, Germany, to quantify the surface-atmosphere exchange of carbon and water over a period of 4.5 months. The relationship between the surface chambers and the eddy covariance technique (EC) was poor for water vapour exchange, with the chambers underestimating half-hourly EC fluxes by up to 75 %. The analysis showed a good overall agreement between the EC carbon fluxes and the chamber-averaged fluxes on a half-hourly basis. However, the net carbon uptake of −14 g C m⁻² over the study period as observed by EC, was overestimated by the surface chambers which showed an uptake of −51 g C m⁻². The deviation is attributed to the spatial heterogeneity of the green roof site, e.g., individual plant species, and to the microscale variation of substrate properties, which is more strongly detected by enclosed chambers located on small source areas, in contrast to eddy covariance observations, which integrate a much larger source area. However, soil flux chambers were found to be an adequate alternative to EC measurements for carbon exchange, given that multiple chamber measurements spots are selected to integrate and assess the spatial heterogeneity on green roofs.

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广泛绿色屋顶的碳和水交换：涡旋相关方差和土壤通量室观测的比较

植被屋顶作为一种减缓策略，目前正在讨论通过光合作用吸收二氧化碳来限制气候变化对城市地区的影响。两种观测方法，即涡旋相关（EC）和自动土壤通量室，在德国柏林的一个大型绿色屋顶上，在4.5个月的时间里量化了碳和水的地表与大气交换。表面腔室与涡动相关技术（EC）之间的关系对于水蒸气交换很差，腔室对半小时EC通量的低估高达75% %。分析表明，欧共体碳通量与室内平均通量在半小时基础上具有良好的总体一致性。然而，在研究期间，EC观测到的- 14 g cm−2的净碳吸收量被表面室高估了，表面室显示的吸收量为- 51 g cm−2。这种偏差归因于绿色屋顶场地的空间异质性，例如单个植物物种，以及基质性质的微尺度变化，与整合更大源区域的涡动相关方差观测相比，位于小源区域的封闭室更能强烈地检测到这种变化。然而，考虑到选择多个室内测量点来整合和评估绿色屋顶上的空间异质性，土壤通量室被认为是碳交换测量的一个足够的替代方案。

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来源期刊

Urban Forestry & Urban Greening FORESTRY-

CiteScore

11.70

自引率

12.50%

发文量

289

审稿时长

70 days

期刊介绍： Urban Forestry and Urban Greening is a refereed, international journal aimed at presenting high-quality research with urban and peri-urban woody and non-woody vegetation and its use, planning, design, establishment and management as its main topics. Urban Forestry and Urban Greening concentrates on all tree-dominated (as joint together in the urban forest) as well as other green resources in and around urban areas, such as woodlands, public and private urban parks and gardens, urban nature areas, street tree and square plantations, botanical gardens and cemeteries. The journal welcomes basic and applied research papers, as well as review papers and short communications. Contributions should focus on one or more of the following aspects: -Form and functions of urban forests and other vegetation, including aspects of urban ecology. -Policy-making, planning and design related to urban forests and other vegetation. -Selection and establishment of tree resources and other vegetation for urban environments. -Management of urban forests and other vegetation. Original contributions of a high academic standard are invited from a wide range of disciplines and fields, including forestry, biology, horticulture, arboriculture, landscape ecology, pathology, soil science, hydrology, landscape architecture, landscape planning, urban planning and design, economics, sociology, environmental psychology, public health, and education.