Werkendam, the Dutch Natural Analogue for CO2 Storage – Long-term Mineral Reactions

The Werkendam (WED) and Barendrecht-Ziedewij (BRTZ) gas fields are CO2- and CH4-bearing stratigraphic equivalents in the Netherlands. A comparison in petrographic characteristics and burial histories of the two fields is performed to investigate long-term mineral reactions induced by the presence of...

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Bibliographic Details
Published inEnergy procedia Vol. 37; pp. 3452 - 3460
Main Authors Koenen, Mariëlle, Wasch, Laura J., van Zalinge, Marit E., Nelskamp, Susanne
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 2013
Subjects
burial history
CO2 storage
diagenetic history
mineral reactions
natural analogue
PHREEQC modeling
PHREEQC modeling
CO2 storage
burial history
diagenetic history
natural analogue
mineral reactions
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Summary:The Werkendam (WED) and Barendrecht-Ziedewij (BRTZ) gas fields are CO2- and CH4-bearing stratigraphic equivalents in the Netherlands. A comparison in petrographic characteristics and burial histories of the two fields is performed to investigate long-term mineral reactions induced by the presence of CO2. The mineral relations in BRTZ are used as a CO2-free reference for WED. However, the results show that the differences in paragenetic sequence between the two fields are partially due to different temperature evolutions and fluid influxes. The mineral relations that can be linked to the presence of CO2 in WED are the partial dissolution of anhydrite and feldspar and the precipitation of siderite, quartz and potentially minor dolomite. The amount of CO2 sequestered in siderite (and potentially dolomite) is small. PHREEQC geochemical modelling was able to simulate the observations of the mineral reactions induced by carbonized brine. Yet, a sensitivity study on the type of illite used in the model, and the inclusion of minor minerals showed that significantly different reactions can be induced. Furthermore the presence and type of Fe-minerals determines if and how much siderite forms. This shows that careful selection of initial mineralogy is required as model input. In one model run mineral reactions were predicted which are known from petrographic studies not to occur under the applied conditions. Hence, besides careful mineral selection, an expert opinion on diagenetic processes is necessary to guide the model towards the proper mineral reactions.
ISSN:1876-6102
1876-6102
DOI:10.1016/j.egypro.2013.06.235