Buoyancy Driven Flow and Methane Hydrate Systems
Marine gas hydrates have been studied intensely for more than five decades under the assumption that deep ocean basins lack the methane necessary to generate significant volumes of gas hydrates. Contrary to this, the deep waters of the Aleutian Basin in the Bering Sea alone are estimated to contain...
| Main Author: | |
|---|---|
| Other Authors: | , , , |
| Format: | Doctoral or Postdoctoral Thesis |
| Language: | English |
| Published: |
2019
|
| Subjects: | |
| Online Access: | https://hdl.handle.net/11244/321584 |
| id |
ftoklahomaunivs:oai:shareok.org:11244/321584 |
|---|---|
| record_format |
openpolar |
| spelling |
ftoklahomaunivs:oai:shareok.org:11244/321584 2023-05-15T15:43:58+02:00 Buoyancy Driven Flow and Methane Hydrate Systems Terry, Darrell Andrew Knapp, Camelia C. Nygaard, Runar Jaiswal, Priyank Knapp, James H. 2019-05-01 application/pdf https://hdl.handle.net/11244/321584 en_US eng https://hdl.handle.net/11244/321584 Copyright is held by the author who has granted the Oklahoma State University Library the non-exclusive right to share this material in its institutional repository. Contact Digital Library Services at lib-dls@okstate.edu or 405-744-9161 for the permission policy on the use, reproduction or distribution of this material. bottom simulating reflectors buoyancy gas hydrates rock physics seismic analysis subspace/covariance analysis Dissertation Text 2019 ftoklahomaunivs 2023-01-25T21:31:24Z Marine gas hydrates have been studied intensely for more than five decades under the assumption that deep ocean basins lack the methane necessary to generate significant volumes of gas hydrates. Contrary to this, the deep waters of the Aleutian Basin in the Bering Sea alone are estimated to contain globally significant volumes of methane in gaseous and hydrate forms in velocity-amplitude (VAMP) structures. After a brief introduction to hydrate stability and seismic data acquisition, the Dissertation is divided into four parts: Part 1. A unified effective medium model is developed to incorporate the endpoints of perfectly smooth and infinitely rough sphere components, and allow partitioning between rough and smooth grains. We incorporate the unified model into the framework for gas hydrates in unconsolidated sediments using both pore-fluid and rock matrix configurations for grain placement. The model resolves conflicting results of previous investigation from the 2002 Mallik gas hydrates projects. Part 2. Conventional semblance for seismic velocity analysis does not have the resolving power of subspace methods due to the inclusion of the noise-signal space in conventional semblance. After nearly three decades, subspace techniques still receive little use in seismic applications due to high computational costs. We develop an approach for seismic velocity spectra based on computing the temporal covariance data matrix as an intermediate step to efficiently compute the Eigen vectors of the spatial covariance data matrix. Part 3. The use of single channel far offset seismic images is investigated for what appears to be a more reliable, cost-effective indicator for the presence of bottom simulating reflectors than traditional CDP processing or AVO analysis. This non-traditional approach is taken to be more relevant to gas hydrate imaging. Results indicate BSRs are more easily identifiable from single channel far offset seismic images than from traditional CDP displays. Part 4. The Aleutian Basin, though ... Doctoral or Postdoctoral Thesis Bering Sea Methane hydrate University of Oklahoma/Oklahoma State University: SHAREOK Repository Bering Sea |
| institution |
Open Polar |
| collection |
University of Oklahoma/Oklahoma State University: SHAREOK Repository |
| op_collection_id |
ftoklahomaunivs |
| language |
English |
| topic |
bottom simulating reflectors buoyancy gas hydrates rock physics seismic analysis subspace/covariance analysis |
| spellingShingle |
bottom simulating reflectors buoyancy gas hydrates rock physics seismic analysis subspace/covariance analysis Terry, Darrell Andrew Buoyancy Driven Flow and Methane Hydrate Systems |
| topic_facet |
bottom simulating reflectors buoyancy gas hydrates rock physics seismic analysis subspace/covariance analysis |
| description |
Marine gas hydrates have been studied intensely for more than five decades under the assumption that deep ocean basins lack the methane necessary to generate significant volumes of gas hydrates. Contrary to this, the deep waters of the Aleutian Basin in the Bering Sea alone are estimated to contain globally significant volumes of methane in gaseous and hydrate forms in velocity-amplitude (VAMP) structures. After a brief introduction to hydrate stability and seismic data acquisition, the Dissertation is divided into four parts: Part 1. A unified effective medium model is developed to incorporate the endpoints of perfectly smooth and infinitely rough sphere components, and allow partitioning between rough and smooth grains. We incorporate the unified model into the framework for gas hydrates in unconsolidated sediments using both pore-fluid and rock matrix configurations for grain placement. The model resolves conflicting results of previous investigation from the 2002 Mallik gas hydrates projects. Part 2. Conventional semblance for seismic velocity analysis does not have the resolving power of subspace methods due to the inclusion of the noise-signal space in conventional semblance. After nearly three decades, subspace techniques still receive little use in seismic applications due to high computational costs. We develop an approach for seismic velocity spectra based on computing the temporal covariance data matrix as an intermediate step to efficiently compute the Eigen vectors of the spatial covariance data matrix. Part 3. The use of single channel far offset seismic images is investigated for what appears to be a more reliable, cost-effective indicator for the presence of bottom simulating reflectors than traditional CDP processing or AVO analysis. This non-traditional approach is taken to be more relevant to gas hydrate imaging. Results indicate BSRs are more easily identifiable from single channel far offset seismic images than from traditional CDP displays. Part 4. The Aleutian Basin, though ... |
| author2 |
Knapp, Camelia C. Nygaard, Runar Jaiswal, Priyank Knapp, James H. |
| format |
Doctoral or Postdoctoral Thesis |
| author |
Terry, Darrell Andrew |
| author_facet |
Terry, Darrell Andrew |
| author_sort |
Terry, Darrell Andrew |
| title |
Buoyancy Driven Flow and Methane Hydrate Systems |
| title_short |
Buoyancy Driven Flow and Methane Hydrate Systems |
| title_full |
Buoyancy Driven Flow and Methane Hydrate Systems |
| title_fullStr |
Buoyancy Driven Flow and Methane Hydrate Systems |
| title_full_unstemmed |
Buoyancy Driven Flow and Methane Hydrate Systems |
| title_sort |
buoyancy driven flow and methane hydrate systems |
| publishDate |
2019 |
| url |
https://hdl.handle.net/11244/321584 |
| geographic |
Bering Sea |
| geographic_facet |
Bering Sea |
| genre |
Bering Sea Methane hydrate |
| genre_facet |
Bering Sea Methane hydrate |
| op_relation |
https://hdl.handle.net/11244/321584 |
| op_rights |
Copyright is held by the author who has granted the Oklahoma State University Library the non-exclusive right to share this material in its institutional repository. Contact Digital Library Services at lib-dls@okstate.edu or 405-744-9161 for the permission policy on the use, reproduction or distribution of this material. |
| _version_ |
1766378182025412608 |