Quaternary shelf-slope development in the northern Gulf of Alaska from combined geophysical and geomorphologic analysis
This dissertation follows the hybrid format as defined by the Office of Graduate Studies at the University of New Mexico. The three chapters defined herein were prepared as manuscripts to be submitted for publication in peer reviewed journals in the field of Earth sciences. A version of chapter 1 wa...
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| Format: | Text |
| Language: | English |
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UNM Digital Repository
2020
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| Online Access: | https://digitalrepository.unm.edu/eps_etds/273 https://digitalrepository.unm.edu/cgi/viewcontent.cgi?article=1289&context=eps_etds |
| Summary: | This dissertation follows the hybrid format as defined by the Office of Graduate Studies at the University of New Mexico. The three chapters defined herein were prepared as manuscripts to be submitted for publication in peer reviewed journals in the field of Earth sciences. A version of chapter 1 was published in Proceedings of the Integrated Ocean Drilling Program, 2017, Volume 41. Chapter 2 was submitted to Marine Geology in Feb 2020, and is under revision as of this date. A version of chapter 3 will be submitted to the Journal of Geophysical Research. In chapter 1, I was the lead researcher establishing a time-depth relationship for Integrated Ocean Drilling Program (IODP) Expedition 341 Southern Alaska Margin Sites U1420 and U1421 using high-resolution multichannel seismic, core, and logging data. Results from the core-log-seismic integration significantly contributed to Exp. 341 goals, particularly by providing a quantitative basis to relate borehole observations and regional seismic-stratigraphic interpretations, and led to publications where I was a contributing coauthor in journals including Earth and Planetary Science Letters, and Nature Communications. In Chapter 2 I led an investigation of how the drainage morphology in the northern Gulf of Alaska relates to glacial activity, faults, and large-scale mass movements. I present a multivariable spatial analysis applied to measurements of channel and feature cross-profile shapes, and in the text, the results are interpreted and evaluated with respect to major near-surface geologic features and existing geophysical data. This analysis highlights and quantifies the broad correspondence between ice sheet location and U-shaped features here, and reveals a more focused shape influence attributable to fault location and mass movements in comparison. In Chapter 3 the focus is on the Bering Trough and Pamplona Zone fold-thrust belt. I present models of velocity, porosity, and overpressure developed from the inversion of seismic refraction data and integration of ... |
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