Publication Type:

Journal Article

Source:

Sedimentary Geology, Elsevier, Amsterdam, Netherlands, Volume 351, p.66-79 (2017)

ISBN:

0037-0738

Keywords:

Arctic Archipelago, Arctic region, Cambrian, Canada, carbonate rocks, cave environment, cross-bedding, depositional environment, dolines, faults, fluidization, folds, intrusions, neoproterozoic, northwest territories, paleoenvironment, paleohydrology, paleokarst, Paleozoic, pipes, planar bedding structures, Precambrian, proterozoic, sea-level changes, Sedimentary rocks, sedimentary structures, sinkholes, solution features, structural controls, terrestrial environment, tilt, unconformities, upper Precambrian, Victoria Island, Western Canada

Abstract:

Paleokarst is most commonly expressed as subtle stratigraphic surfaces rather than large void systems penetrating deeply into the paleo-subsurface. In contrast, a regional Precambrian-Cambrian unconformity on Victoria Island (NWT, Canada), is associated with exceptional exposure of large, intact Cambrian paleocaverns (100 m diameter; tens of m high). The paleocaves are distributed along a paleo-horizontal plane, and an associated gryke network is present in the 30-60 m of Neoproterozoic dolostone between cave rooves and the base of overlying Cambrian sandstone; both are filled by Cambrian sandstone. The formation and preservation of such karst features require aggressive dissolution along a stable paleo-water-table shortly before transgression and deposition of shallow-marine sand over the dolostone. During the transgression, the karst network acted as a conduit for flowing groundwater that was discharged through overlying, unconsolidated Cambrian shallow-marine sand, producing water-escape structures (sand volcanoes and their conduits). The conduits are preserved as cylindrical remnants of the sand volcanoes' feeder pipes. Sediment fluidisation was probably caused by variations in the hydraulic-head gradient in a meteoric lens near the Cambrian coastline under a tropical climate with abundant, probably seasonally variable rainfall that caused pulses in subsurface fluid flow. Spatial distribution of the paleocaves and sand volcanoes suggests their formation on the southeast side of a recently faulted horst of Proterozoic carbonate bedrock that formed a nearshore island during early Cambrian sea-level rise. Fluidisation structures such as those reported here have generally been difficult to interpret owing to a lack of data on the fluid hydraulics of the underlying aquifer. This is the first report linking the hydraulics of a well-characterised paleokarst to development of fluid-escape structures. Such structures are widely known from sandstones overlying the sub-Cambrian unconformity around the circumference of Laurentia.

Notes:

GeoRef, Copyright 2018, American Geological Institute.<br/>2017-037559<br/>fluidization structures<br/>paleocaves<br/>Quyuk formation<br/>Wynniatt Formation