Evaluating the use of electrical resistivity imaging technique for improving CH4 and CO2 emission rate estimations in landfills

I. Georgaki; P. Soupios; N. Sakkas; F. Ververidis; E. Trantas; F. Vallianatos; T. Manios

doi:10.1016/j.scitotenv.2007.08.033

Evaluating the use of electrical resistivity imaging technique for improving CH₄ and CO₂ emission rate estimations in landfills

I. Georgaki^*, P. Soupios, N. Sakkas, F. Ververidis, E. Trantas, F. Vallianatos, T. Manios

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

66 Scopus citations

Abstract

In order to improve the estimation of surface gas emissions in landfill, we evaluated a combination of geophysical and greenhouse gas measurement methodologies. Based on fifteen 2D electrical resistivity tomographies (ERTs), longitudinal cross section images of the buried waste layers were developed, identifying place and cross section size of organic waste (OW), organic waste saturated in leachates (SOW), low organic and non-organic waste. CH₄ and CO₂ emission measurements were then conducted using the static chamber technique at 5 surface points along two tomographies: (a) across a high-emitting area, ERT#2, where different amounts of relatively fresh OW and SOW were detected, and (b) across the oldest (at least eight years) cell in the landfill, ERT#6, with significant amounts of OW. Where the highest emission rates were recorded, they were strongly affected by the thickness of the OW and SOW fraction underneath each gas sampling point. The main reason for lower than expected values was the age of the layered buried waste. Lower than predicted emissions were also attributed to soil condition, which was the case at sampling points with surface ponding, i.e. surface accumulation of leachate (or precipitated water).

Original language	English
Pages (from-to)	522-531
Number of pages	10
Journal	Science of the Total Environment
Volume	389
Issue number	2-3
DOIs	https://doi.org/10.1016/j.scitotenv.2007.08.033
State	Published - 25 Jan 2008
Externally published	Yes

Bibliographical note

Funding Information:
The authors are grateful to Panagiotis Tsourlos, whose comments have helped to improve the manuscript. Financial support for this project was provided by the Greek Ministry of Education through Archimedes I and II programmes. The research team would also like to thank the students involved in the survey work: Evi Seferou, Aris Tsamoukas, Panos Georgakopoulos and Anna Tzave.

Keywords

Geophysical
Greenhouse gases
Landfill
Leachate
Solid wastes
Static chamber

ASJC Scopus subject areas

Environmental Engineering
Environmental Chemistry
Waste Management and Disposal
Pollution

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1016/j.scitotenv.2007.08.033

Cite this

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title = "Evaluating the use of electrical resistivity imaging technique for improving CH4 and CO2 emission rate estimations in landfills",

abstract = "In order to improve the estimation of surface gas emissions in landfill, we evaluated a combination of geophysical and greenhouse gas measurement methodologies. Based on fifteen 2D electrical resistivity tomographies (ERTs), longitudinal cross section images of the buried waste layers were developed, identifying place and cross section size of organic waste (OW), organic waste saturated in leachates (SOW), low organic and non-organic waste. CH4 and CO2 emission measurements were then conducted using the static chamber technique at 5 surface points along two tomographies: (a) across a high-emitting area, ERT\#2, where different amounts of relatively fresh OW and SOW were detected, and (b) across the oldest (at least eight years) cell in the landfill, ERT\#6, with significant amounts of OW. Where the highest emission rates were recorded, they were strongly affected by the thickness of the OW and SOW fraction underneath each gas sampling point. The main reason for lower than expected values was the age of the layered buried waste. Lower than predicted emissions were also attributed to soil condition, which was the case at sampling points with surface ponding, i.e. surface accumulation of leachate (or precipitated water).",

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author = "I. Georgaki and P. Soupios and N. Sakkas and F. Ververidis and E. Trantas and F. Vallianatos and T. Manios",

note = "Funding Information: The authors are grateful to Panagiotis Tsourlos, whose comments have helped to improve the manuscript. Financial support for this project was provided by the Greek Ministry of Education through Archimedes I and II programmes. The research team would also like to thank the students involved in the survey work: Evi Seferou, Aris Tsamoukas, Panos Georgakopoulos and Anna Tzave. ",

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AU - Georgaki, I.

AU - Soupios, P.

AU - Sakkas, N.

AU - Ververidis, F.

AU - Trantas, E.

AU - Vallianatos, F.

AU - Manios, T.

N1 - Funding Information: The authors are grateful to Panagiotis Tsourlos, whose comments have helped to improve the manuscript. Financial support for this project was provided by the Greek Ministry of Education through Archimedes I and II programmes. The research team would also like to thank the students involved in the survey work: Evi Seferou, Aris Tsamoukas, Panos Georgakopoulos and Anna Tzave.

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Y1 - 2008/1/25

N2 - In order to improve the estimation of surface gas emissions in landfill, we evaluated a combination of geophysical and greenhouse gas measurement methodologies. Based on fifteen 2D electrical resistivity tomographies (ERTs), longitudinal cross section images of the buried waste layers were developed, identifying place and cross section size of organic waste (OW), organic waste saturated in leachates (SOW), low organic and non-organic waste. CH4 and CO2 emission measurements were then conducted using the static chamber technique at 5 surface points along two tomographies: (a) across a high-emitting area, ERT#2, where different amounts of relatively fresh OW and SOW were detected, and (b) across the oldest (at least eight years) cell in the landfill, ERT#6, with significant amounts of OW. Where the highest emission rates were recorded, they were strongly affected by the thickness of the OW and SOW fraction underneath each gas sampling point. The main reason for lower than expected values was the age of the layered buried waste. Lower than predicted emissions were also attributed to soil condition, which was the case at sampling points with surface ponding, i.e. surface accumulation of leachate (or precipitated water).

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