Tracing Coalbed Natural Gas-Coproduced Water Using Stable Isotopes of Carbon

Tracing Coalbed Natural Gas-Coproduced Water Using Stable Isotopes of Carbon

Recovery of hydrocarbons commonly is associated with coproduction of water. This water may be put to beneficial use or may be reinjected into subsurface aquifers. In either case, it would be helpful to establish a fingerprint for that coproduced water so that it may be tracked following discharge on...

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Bibliographic Details
Published in:Ground water Vol. 46; no. 2; pp. 329 - 334
Main Authors: Sharma, S, Frost, C.D
Format: Journal Article
Language:English
Published: Malden, USA Malden, USA : Blackwell Publishing Inc 01-03-2008
Blackwell Publishing Inc
Ground Water Publishing Company
Subjects:
01 COAL, LIGNITE, AND PEAT
CARBON 13
Carbon Isotopes - chemistry
Coal
COAL SEAMS
ENVIRONMENTAL IMPACTS
Fossil Fuels
GROUND WATER
Groundwater
Hydrocarbons
INJECTION WELLS
ISOTOPE RATIO
Isotopes
METHANE
MONITORING
Natural gas
Reservoirs
River basins
Studies
SURFACE WATERS
WASTE WATER
Water - chemistry
Water treatment
Wyoming
Wyoming
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Summary:Recovery of hydrocarbons commonly is associated with coproduction of water. This water may be put to beneficial use or may be reinjected into subsurface aquifers. In either case, it would be helpful to establish a fingerprint for that coproduced water so that it may be tracked following discharge on the surface or reintroduction to geologic reservoirs. This study explores the potential of using δ¹³C of dissolved inorganic carbon (DIC) of coalbed natural gas (CBNG)-coproduced water as a fingerprint of its origin and to trace its fate once it is disposed on the surface. Our initial results for water samples coproduced with CBNG from the Powder River Basin show that this water has strongly positive δ¹³CDIC (12[per thousand] to 22[per thousand]) that is readily distinguished from the negative δ¹³C of most surface and ground water (-8[per thousand] to -11[per thousand]). Furthermore, the DIC concentrations in coproduced water samples are also high (more than 100 mg C/L) compared to the 20 to 50 mg C/L in ambient surface and ground water of the region. The distinctively high δ¹³C and DIC concentrations allow us to identify surface and ground water that have incorporated CBNG-coproduced water. Accordingly, we suggest that the δ¹³CDIC and DIC concentrations of water can be used for long-term monitoring of infiltration of CBNG-coproduced water into ground water and streams. Our results also show that the δ¹³CDIC of CBNG-coproduced water from two different coal zones are distinct leading to the possibility of using δ¹³CDIC to distinguish water produced from different coal zones.
Bibliography:http://dx.doi.org/10.1111/j.1745-6584.2007.00417.x
ArticleID:GWAT417
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ISSN:0017-467X
1745-6584
DOI:10.1111/j.1745-6584.2007.00417.x