Seismic and well test analysis methods to characterise fluvially deposited reservoir elements

Barens, Leonardus Maria

January 2001

No description available.

551

Geologic mapping of exhumed, mid-Cretaceous paleochannel complexes near Castle Dale, Emery County, Utah: On the correlative relationship between the Dakota Sandstone and the Mussentuchit Member of the Cedar Mountain Formation

Sorensen, Amanda Elizabeth MacKay

21 April 2011

Numerous well-preserved, exhumed paleochannels in the Morrison, Cedar Mountain and Dakota Sandstone formations are exposed east of Castle Dale, Utah. These channels consist primarily of point bar complexes and scattered, low sinuosity channels. To determine the vertical and lateral relationships of these channels within the Cedar Mountain and Dakota Sandstone formations, a 1:24,000 scale geologic map covering ~140 km2 was created showing the fluvial sandstones. In the study area the Cedar Mountain Formation consists, from bottom to top, of 2.5-10 m of Buckhorn Conglomerate Member equivalent units, ~80 m of the Ruby Ranch Member, and ~30 m of the Mussentuchit Member. The Dakota Sandstone consists of conglomeratic to sandy, meandering channel fills within the Mussentuchit Member. The Ruby Ranch-Mussentuchit member contact is diagnosed as the top of a laterally extensive, ~10 meter thick, maroon paleosol with calcrete horizons and root traces. When deeply weathered the contact is discernable as a shift from maroon mudstone to a pale green-white, silty mudstone. Like the balance of the Mussentuchit Member overbank deposits, the white-green mudstone is rich in smectitic clays. In the southern one-third of the mapped area, Ruby Ranch Member sandstones are thin, discontinuous channel segments surrounded by floodplain deposits. In the middle to northern area, point bar complexes dominate, some of which are laterally amalgamated. Flow direction data from four meander complexes and a low sinuosity channel indicate an average northeast flow. Dakota Sandstone channels all of which are within the Mussentuchit Member also flowed to the northeast but point bar complexes are both more numerous and more laterally continuous than in the Ruby Ranch Member, indicating deposition in an area with less accommodation space than during Ruby Ranch Member time. The data indicate the Dakota Sandstone consists exclusively of fluvial sandstones encased within the Mussentuchit Member of the Cedar Mountain Formation. Therefore, these units are coeval and simply different facies of the same depositional system. Consequently the Mussentuchit Member is considered a member facies of the Dakota Formation.

exhumed paleochannel

point bar complex

Cedar Mountain Formation

Dakota Sandstone

Mussentuchit Member

Ruby Ranch Member

Geology

Développement de la végétation saisonnière et dynamique hydrosédimentaire sur les bancs alluviaux

Lalonde, Olivier

January 2009

Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal.

Végétation riveraine

Végétation colonisatrice

Banc alluvial

Banc de convexité

Rivière Yamachiche

Biodiversité

Riverbank vegetation

Colonizing vegetation

Alluvial bar

Point bar

Yamachiche River

Biodiversity

Intra-meander groundwater-surface water interactions in a losing experimental stream

Nowinski, John David

23 December 2010

Groundwater-surface water interactions between streams and shallow alluvial aquifers can significantly affect their thermal and chemical regimes and thus are critical for effective management of water resources and riparian ecosystems. Of particular significance is the hyporheic zone, an area delineated by subsurface flow paths that begin and end in surface water bodies. Although detailed work has examined hyporheic flow in the vertical dimension, some studies have suggested that the drop in a stream’s elevation as it flows downstream can laterally extend the hyporheic zone. This study examines intra-meander hyporheic flow using extensive field measurements in a full-scale experimental stream-aquifer system. Synoptic head measurements from 2008 and 2009 and a lithium tracer test were conducted to determine the extent and nature of hyporheic flow within the meander. Permeability was measured and sediment cores were analyzed from 2008 to 2009 to assess aquifer properties. Finally, transient head and temperature measurements were collected during flooding events to assess the sensitivity of intra-meander hyporheic flow and temperature to stream discharge. Results verify that hyporheic flow through meanders occurs, but show that it is sensitive to whether a stream is gaining or losing water to the subsurface overall. In addition, permeability and core grain size results indicate moderate heterogeneity in permeability can occur in aquifers composed of relatively uniform sediment. Results also demonstrate that permeability in alluvial aquifers can evolve through time. Such evolution may be driven by groundwater flow, which transports fine particles from areas where porosity and permeability are relatively high and deposits them where they are relatively low, thus creating a positive feedback loop. Finally, measurements during flooding indicate that steady-state hyporheic flow and the thermal regime within the aquifer are largely insensitive to stream discharge. Together, these results expand upon previous field studies of intra-meander hyporheic flow and verify previous modeling work, although they demonstrate a level of complexity within these systems that should be considered in future work. / text

Intra-meander

Hyporheic flow

Meander

Permeability

Hydraulic conductivity

Point bar

Flood

Temperature

Particle

Colloid

Outdoor streamlab

Groundwater

Surface water

Streams

Aquifers

Développement de la végétation saisonnière et dynamique hydrosédimentaire sur les bancs alluviaux

Lalonde, Olivier

January 2009

Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal

Végétation riveraine

Végétation colonisatrice

Banc alluvial

Banc de convexité

Rivière Yamachiche

Biodiversité

Riverbank vegetation

Colonizing vegetation

Alluvial bar

Point bar

Yamachiche River

Biodiversity