Journal
GEOCHIMICA ET COSMOCHIMICA ACTA
Volume 309, Issue -, Pages 57-78Publisher
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.gca.2021.06.019
Keywords
Microcrystalline quartz; In situ oxygen isotope analysis; Chalcedony; NanoSIMS
Categories
Funding
- ExxonMobil Upstream Research Company
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The study examines the relationships between quartz cement, chalcedony/amorphous silica, and microcrystalline quartz in sandstones, with implications for the porosity of deeply buried sandstones. It is suggested that chalcedony and microcrystalline quartz developed during cooling of flowing formation water, with higher delta O-18 values indicating considerable water-rock interaction typical of basin-center waters. The presence of duplicate layers suggests two thrust-induced fluid expulsion events in the Coniacian to Campanian.
The origin and growth mechanisms of microcrystalline quartz cement in sandstones and its relationship to quartz overgrowths remain puzzling even though it has an important effect on rock properties in deeply buried sandstones; microcrystalline quartz cement inhibits the growth of quartz cement and so leaves sandstones with anomalously high porosity deep in sedimentary basins. Here we have examined the relationships between quartz cement, and duplicate layers of chalcedony/amorphous silica and microcrystalline quartz from outcrops of the Upper Cretaceous Heidelberg Formation, Germany. We have used an array of techniques including: NanoSIMS for spatially-resolved stable oxygen isotope analysis, and high-resolution chemical analysis of the silica cements using electron microprobe analysis, as well as crystallographic studies using TEM and EBSD. Based on burial history modeling and the low degree of compaction of the Heidelberg Formation sandstones, we conclude that maximum temperature due to conductive heating was about 42 degrees C; quartz overgrowths with delta O-18 of 18.8 parts per thousand developed from meteoric-derived formation water with delta O-18 of about -12 parts per thousand V-SMOW. Based on published precedents and an awareness that silica solubility decreases with decreasing temperature, we assume that chalcedony/amorphous silica and then microcrystalline quartz developed during cooling of flowing formation water. Chalcedony with delta O-18 of 27.4 parts per thousand developed from meteoric-derived formation water with delta O-18 of between -1 and -3 parts per thousand V-SMOW depending on whether the initial temperature of the cooling formation water was 45 or 55 degrees C. The interpreted higher delta O-18 of the warmer water responsible for chalcedony and microcrystalline quartz growth is typical of basin-center waters that have undergone considerable water-rock interaction. It is likely that the fluid movement was caused by thrust tectonics in the Coniacian to Campanian. The duplicate layers of chalcedony/amorphous silica and then microcrystalline quartz suggests that there were two thrust-induced fluid expulsion events. (C) 2021 Elsevier Ltd. All rights reserved.
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