Middle and Late Tertiary Tectonic and Physiographic Developments

Trettin, HP

doi:10.1130/dnag-gna-e.491

Cited by 3 publications

References 6 publications

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A fluid inclusion study of diagenetic fluids in Proterozoic and Paleozoic carbonate rocks, Victoria Island, NWT

2013

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Despite the presence of known economic resources in Canada's Arctic archipelago, Victoria Island remains understudied. This study addresses the fluid history and economic potential of two major carbonate units on Victoria Island by integrating fluid inclusion microthermometry with SEM‐EDS analysis of evaporate mounds. Three cements containing fluid inclusion assemblages (FIA) occur in the Neoproterozoic Wynniatt Formation: saddle dolomite, brown dolomite and calcite, in paragenetic order. The two dolomite‐hosted cements have average homogenisation temperatures (Th) for FIAs (n = 3) of 108°C (saddle) and 101 and 116°C, but metastability precluded determining salinities; most calcite‐hosted fluid inclusions are too small and/or necked to obtain Th values, but rare larger inclusions have salinities from 1.7 to 0.4 wt. % NaCl equiv. SEM‐EDS analysis of evaporate mounds indicates the fluid changed from an early K‐rich (saddle dolomite), to a later K + Na (brown dolomite), and finally Na‐rich (calcite), which suggests mixing of two end‐member fluids (i.e. Na‐rich and K‐rich). Dolostone of the lower Paleozoic ‘Victoria Island formation’ contains two cements: early quartz and late dolomite. Quartz‐hosted FIAs (n = 2) have an average Th value of 126°C, and salinity of 23.2 wt. % NaCl equiv., whereas FIAs (n = 3) in dolomite have average Th values of 109, 116 and 124°C; metastability precluded determining salinity. Evaporate mound analysis for the cements indicates evolution from a Na‐rich to a Na + K fluid through interaction with reservoir rocks. A reduced, metal‐rich fluid was present during quartz precipitation, as implied by the presence of pyrite framboids along growth zones and nanoparticles of barite and sulphide minerals (Zn, Cu and Pb) in evacuated inclusions, which suggests the area may have potential to host base‐metal mineralisation. Importantly, distinguishing different fluid compositions in both of the case studies would not have been possible without evaporate mound analysis and therefore the results emphasise integrating this technique into diagenetic studies.

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A fluid inclusion study of diagenetic fluids in Proterozoic and Paleozoic carbonate rocks, Victoria Island, NWT

2013

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The Arctic Islands

Trettin¹

1989

The Geology of North America—An Overview

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The Canadian Arctic Archipelago, perched on the northern rim of the continent, is about 1.3 million km2 in area, including intervening waters (Fig. 1; Plate 9, index). Parry Channel, a seaway connecting Baffin Bay with the western Arctic Ocean, separates the Queen Elizebeth Islands to the north from another group of islands to the south. Rugged mountain ranges with extensive ice caps in the eastern part of the archipelago, and plateaus, lowlands, and a coastal plain in the western part, are all dissected by numerous channels and fiords (Dawes and Christie, Ch. 3).1 Outlines of the geography and rudiments of the geology were established during the last century and the first half of this century. This work was done by ship, with sledges, or on foot, under hardship and often tragic circumstances (Christie and Dawes, Ch. 2). A coherent stratigraphic-structural framework has emerged from subsequent systematic surface studies, which have been supported by helicopters since 1955. Paleontology, always at the forefront of Arctic earth science, has provided the basis for both regional correlations and reconstructions of the geologic history. Petroleum exploration has been active in the islands since the early 1960s, and by 1987, 176 wells had been drilled and more than 65,000 km of seismic reflection lines had been shot. The well data have been absorbed into the stratigraphic framework, and a few instructive seismic interpretations have been released (e.g., Harrison and Bally, 1988), but the bulk of the seismic work remains unpublished. Gravity surveys (Sobczak, Ch. 5A) and deep seismic refraction surveys, both carried out from the late 1950s onward, have permitted construction of crustal cross sections in the western parts of the islands (Sweeney and others, 1986; Sobczak and others, Ch. 5B), while aeromagnetic surveys (Coles, Ch. 5D), electrical conductivity studies (Niblett and Kurtz, Ch. 5E), and analyses of seismicity (Forsyth and others, Ch. 5C) have elucidated other aspects of crustal structure and tectonics.

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A New Frontier Province Offshore Northwest Greenland: Structure, Basin Development, and Petroleum Potential of the Melville Bay Area

Whittaker¹

1997

Bulletin

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Middle and Late Tertiary Tectonic and Physiographic Developments

Cited by 3 publications

References 6 publications

A fluid inclusion study of diagenetic fluids in Proterozoic and Paleozoic carbonate rocks, Victoria Island, NWT

A fluid inclusion study of diagenetic fluids in Proterozoic and Paleozoic carbonate rocks, Victoria Island, NWT

The Arctic Islands

A New Frontier Province Offshore Northwest Greenland: Structure, Basin Development, and Petroleum Potential of the Melville Bay Area

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