Your search keyword '"Roger H. Morin"' showing total 4 results

1. Neogene tectonic and climatic evolution of the Western Ross Sea, Antarctica — Chronology of events from the AND-1B drill hole

Author

Reed P. Scherer, Frank Niessen, Massimo Pompillio, Peter Barrett, Rosemary Cody, Leah Joseph, Stefanie Ann Brachfeld, Robert M. McKay, Greg H. Browne, Marco Taviani, Nelia W. Dunbar, William C. McIntosh, Ellen A. Cowan, Giuliana Villa, Richard D. Jarrard, Robert M. DeConto, D. Winter, Roger H. Morin, Leonardo Sagnotti, Dhiresh Hansaraj, Fabio Florindo, James S. Crampton, Stuart Henrys, J. Ian Raine, C Percy Strong, P. Maffioli, Gerhard Kuhn, Jake Ross, Sonia Sandroni, Gary S. Wilson, Ross D. Powell, Terry J. Wilson, Sherwood W. Wise, Diana Magens, Franco M Talarico, Timothy Paulsen, Brent V. Alloway, Michelle A. Kominz, Richard H. Levy, Trevor Williams, Linda A. Hinnov, Giovanna Giorgetti, M. J. Hannah, Christina Millan, Catalina Gebhardt, Donata Monien, Lionel Carter, Andreas Läufer, Larry Krissek, Tom Wilch, S. W. Vogel, Christina R. Riesselman, Tim R Naish, David Pollard, David M. Harwood, Charlotte Sjunneskog, Philip R. Kyle, Ian J. Graham, Gavin B. Dunbar, Robert B. Dunbar, Hilmar von Eynatten, Davide Persico, Christian Ohneiser, and D. R. Schmitt

Subjects

Stratigraphic Drilling, McMurdo Ice Shelf, Chronostratigraphy, Neogene, Tectonics, Ice Sheet history, Global and Planetary Change, 010504 meteorology & atmospheric sciences, Pyroclastic rock, Late Miocene, 010502 geochemistry & geophysics, Oceanography, Mbsf, 01 natural sciences, Unconformity, Diamictite, Paleontology, Stratigraphy, 13. Climate action, Sedimentary rock, Geology, 0105 earth and related environmental sciences

Abstract

Stratigraphic drilling from the McMurdo Ice Shelf in the 2006/2007 austral summer recovered a 1284.87 m sedimentary succession from beneath the sea floor. Key age data for the core include magnetic polarity stratigraphy for the entire succession, diatom biostratigraphy for the upper 600 m and 40Ar/39Ar ages for in-situ volcanic deposits as well as reworked volcanic clasts. A vertical seismic profile for the drill hole allows correlation between the drill hole and a regional seismic network and inference of age constraint by correlation with well‐dated regional volcanic events through direct recognition of interlayered volcanic deposits as well as by inference from flexural loading of pre‐existing strata. The combined age model implies relatively rapid (1 m/2–5 ky) accumulation of sediment punctuated by hiatuses, which account for approximately 50% of the record. Three of the longer hiatuses coincide with basin‐wide seismic reflectors and, along with two thick volcanic intervals, they subdivide the succession into seven chronostratigraphic intervals with characteristic facies: 1. The base of the cored succession (1275–1220 mbsf) comprises middle Miocene volcaniclastic sandstone dated at approx 13.5 Ma by several reworked volcanic clasts; 2. A late-Miocene sub-polar orbitally controlled glacial–interglacial succession (1220–760 mbsf) bounded by two unconformities correlated with basin‐wide reflectors associated with early development of the terror rift; 3. A late Miocene volcanigenic succession (760–596 mbsf) terminating with a ~1 my hiatus at 596.35 mbsf which spans the Miocene–Pliocene boundary and is not recognised in regional seismic data; 4. An early Pliocene obliquity-controlled alternating diamictite and diatomite glacial–interglacial succession (590–440 mbsf), separated from; 5. A late Pliocene obliquity-controlled alternating diamictite and diatomite glacial–interglacial succession (440–150 mbsf) by a 750 ky unconformity interpreted to represent a major sequence boundary at other locations; 6. An early Pleistocene interbedded volcanic, diamictite and diatomite succession (150–80 mbsf), and; 7. A late Pleistocene glacigene succession (80–0 mbsf) comprising diamictite dominated sedimentary cycles deposited in a polar environment.

Published

2012

2. Negative correlation between porosity and hydraulic conductivity in sand-and-gravel aquifers at Cape Cod, Massachusetts, USA

Author

Roger H. Morin

Subjects

geography, geography.geographical_feature_category, Hydraulic conductivity, Electrical resistivity and conductivity, Well logging, Principal component analysis, Mineralogy, Aquifer, Porosity, Groundwater, Geology, Water Science and Technology, Aquifer properties

Abstract

Although it may be intuitive to think of the hydraulic conductivity K of unconsolidated, coarse-grained sediments as increasing monotonically with increasing porosity F, studies have documented a negative correlation between these two parameters under certain grain-size distributions and packing arrangements. This is confirmed at two sites on Cape Cod, Massachusetts, USA, where groundwater investigations were conducted in sand-and-gravel aquifers specifically to examine the interdependency of several aquifer properties using measurements from four geophysical well logs. Along with K and F, the electrical resistivity R0 and the natural gamma activity g of saturated deposits were determined as functions of depth. Qualitative examination of results from the first site implies a negative correlation between K and F that is substantiated by a rigorous multivariate analysis of log data collected from the second site. A principal components analysis describes an overdetermined system of inversion equations, with approximately 92% of the cumulative proportion of the total variance being accounted for by only three of the four eigenvectors. A subsequent R-mode factor analysis projects directional trends among the four variables (K, F, R0 and g), and a negative correlation between K and F emerges as the primary result. q 2005 Elsevier B.V. All rights reserved.

Published

2006

3. Hydrologic properties of coal beds in the Powder River Basin, Montana I. Geophysical log analysis

Author

Roger H. Morin

Subjects

geography, geography.geographical_feature_category, Lineament, Bedding, business.industry, Coal mining, Borehole, Physiographic province, Aquifer, Geophysics, Aquifer test, Sedimentary rock, business, Geology, Water Science and Technology

Abstract

As part of a multidisciplinary investigation designed to assess the implications of coal-bed methane development on water resources for the Powder River Basin of southeastern Montana, six wells were drilled through Paleocene-age coal beds along a 31km east–west transect within the Tongue River drainage basin. Analysis of geophysical logs obtained in these wells provides insight into the hydrostratigraphic characteristics of the coal and interbedded siliciclastic rocks and their possible interaction with the local stress field. Natural gamma and electrical resistivity logs were effective in distinguishing individual coal beds. Full-waveform sonic logs were used to determine elastic properties of the coal and an attendant estimate of aquifer storage is in reasonable agreement with that computed from a pumping test. Inspection of magnetically oriented images of the borehole walls generated from both acoustic and optical televiewers and comparison with coal cores infer a face cleat orientation of approximately N338E, in close agreement with regional lineament patterns and the northeast trend of the nearby Tongue River. The local tectonic stress field in this physiographic province as inferred from a nearby 1984 earthquake denotes an oblique strike-slip faulting regime with dominant east–west compression and north–south extension. These stress directions are coincident with those of the primary fracture sets identified from the televiewer logs and also with the principle axes of the drawdown ellipse produced from a complementary aquifer test, but oblique to apparent cleat orientation. Consequently, examination of these geophysical logs within the context of local hydrologic characteristics indicates that transverse transmissivity anisotropy in these coals is predominantly controlled by bedding configuration and perhaps a mechanical response to the contemporary stress field rather than solely by cleat structure. Published by Elsevier B.V.

Published

2005

4. Modeling regional salinization of the Ogallala aquifer, Southern High Plains, TX, USA

Author

Sunil Mehta, R. M Brady, Roger H. Morin, and Alan E. Fryar

Subjects

Salinity, Hydrology, geography, geography.geographical_feature_category, Soil salinity, Evaporite, Water flow, Aquifer, Groundwater recharge, Groundwater, Geology, Water Science and Technology, Plume

Abstract

Two extensive plumes (combined area .1000 km 2 ) have been delineated within the Ogallala aquifer in the Southern High Plains, TX, USA. Salinity varies within the plumes spatially and increases with depth; Cl ranges from 50 to .500 mg l 21 . Variable-density flow modeling using SUTRA has identified three broad regions of upward cross-formational flow from the underlying evaporite units. The upward discharge within the modeled plume area is in the range of 10 24 ‐10 25 m 3 day 21 , and the TDS concentrations are typically .3000 mg l 21 . Regions of increased salinity, identified within the Whitehorse Group (evaporite unit) underlying the Ogallala aquifer, are controlled by the structure and thickness variations relative to the recharge areas. Distinct flow paths, on the order of tens of km to .100 km in length, and varying flow velocities indicate that the salinization of the Ogallala aquifer has been a slow, ongoing process and may represent circulation of waters recharged during Pleistocene or earlier times. On-going pumping has had negligible impact on the salinity distribution in the Ogallala aquifer, although simulations indicate that the velocity distribution in the underlying units may have been affected to depths of 150 m after 30 years of pumping. Because the distribution of saline ground water in this region of the Ogallala aquifer is heterogeneous, careful areal and vertical characterization is warranted prior to any well-field development. q 2000 Elsevier Science B.V. All rights reserved.

Published

2000