Life-cycle greenhouse gas emissions assessment and extended exergy accounting of a horizontal-flow constructed wetland for municipal wastewater treatment: A case study in Chile

Life-cycle greenhouse gas emissions assessment and extended exergy accounting of a horizontal-flow constructed wetland for municipal wastewater treatment: A case study in Chile

•Extended exergy accounting (EEA) of wastewater treatment using constructed wetland.•Constructed wetlands contribute to reduction of GHG and resources consumption in wastewater sector.•The seasonality favors the removal efficiency and environmental remediation costs. The life-cycle greenhouse gaseou...

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Bibliographic Details
Published in:Ecological indicators Vol. 74; pp. 130 - 139
Main Authors: Casas Ledón, Yannay, Rivas, Ariel, López, Daniela, Vidal, Gladys
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-03-2017
Subjects:
Constructed wetland
Environmental remediation cost
Extended exergy accounting
Life-cycle greenhouse gas emission
Phragmites australis
Resources consumption
Schoenoplectus californicus
Chile
Extended exergy accounting
Life-cycle greenhouse gas emission
Constructed wetland
Resources consumption
Environmental remediation cost
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Summary:•Extended exergy accounting (EEA) of wastewater treatment using constructed wetland.•Constructed wetlands contribute to reduction of GHG and resources consumption in wastewater sector.•The seasonality favors the removal efficiency and environmental remediation costs. The life-cycle greenhouse gaseous emissions and primary exergy resources consumption associated with a horizontal subsurface flow constructed wetland (HSSF) were investigated. The subject of study was a wetland for municipal wastewater treatment with a 700-person-equivalent capacity. The effects of two types of emergent aquatic macrophytes (Phragmites australis and Schoenoplectus californicus) and seasonality on greenhouse gas (GHG) gas emissions, the environmental remediation cost (ERC) and the specific environmental remediation cost (SERC) were assessed. The results indicate that GHG emissions per capita (12–22kgCO2eq/p.e/yr) and primary exergy resources consumed (24–27MJ/m3) for the HSSF are lower than those of a conventional wastewater treatment plant (67.9kgCO2eq/p.e/yr and 96MJ/m3). The SERC varied between 176 and 216MJ/kg biological oxygen demand (BOD5) removal, which should be further reduced by 20% for an improved BOD5 removal efficiency above 90%. The low organic matter removal efficiency is associated with a high organic load and low bacterial development. Seasonality has a marked effect on the organic removal efficiency and the SERC, but the macrophyte species does not.
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ISSN:1470-160X
1872-7034
DOI:10.1016/j.ecolind.2016.11.014