DAS signature of reservoir pressure changes caused by a CO2 injection: Experience from the CO2CRC Otway Project

•Fibre-optic cables can sense reservoir pressure variations during the injection of CO2 in the deep geological formation.•Linear relationship between DAS strain and pressure change allows estimation of elastic moduli of reservoir rock.•DAS can be utilized to detect leakage into the overburden during...

Full description

Saved in:
Bibliographic Details
Published in:International journal of greenhouse gas control 2022-09, Vol.119, p.103735, Article 103735
Main Authors: Sidenko, Evgenii, Tertyshnikov, Konstantin, Gurevich, Boris, Pevzner, Roman
Format: Article
Language:English
Subjects:
Borehole geophysics
CO2 geosequestration
Distributed fibre-optic sensing
Monitoring of CO2 injection
Pressure response on DAS
Reservoir pressure monitoring
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•Fibre-optic cables can sense reservoir pressure variations during the injection of CO2 in the deep geological formation.•Linear relationship between DAS strain and pressure change allows estimation of elastic moduli of reservoir rock.•DAS can be utilized to detect leakage into the overburden during CO2 injection. Distributed Acoustic Sensing (DAS) is a fast-developing technology and is being actively used in geophysical monitoring applications. DAS technology is based on continuous measurements along a fibre-optic cable and can record seismic waves/signals that induce axial strain in the cable. Most DAS systems are designed to measure signals higher than 1 Hz; however some DAS systems are sensitive to low-frequency (< 1 Hz) signals such as reservoir pressure variations. At the time of CO2 injection within the CO2CRC Otway Project, pressure related strain-rate DAS signals were observed in two monitoring wells. These signals are highly correlated with the pressure signals measured by borehole pressure gauges above the perforations in monitoring wells. Comparison of DAS measurements and pressure measurements shows a linear relationship between the two datasets. Analysis of data shows that DAS is able to detect reservoir pressure variations higher than 10−4 psi/s. Analysis of pressure variations and strain calculated from DAS strain rate values allows estimation of the elastic modulus of the reservoir formation. Obtained results show that DAS systems can be utilised not only as seismic sensors, but also as continuous pressure sensors that can help track possible CO2 leakages into the overburden. In contrast to traditional pressure gauges, DAS is also capable of tracking the pressure profile along the entire well. DAS pressure sensing capabilities open up many new applications to complement subsurface reservoir pressure monitoring, CCUS and hydrogeological studies.
ISSN:1750-5836
1878-0148
DOI:10.1016/j.ijggc.2022.103735