Your search keyword '"Holbrook, W. Steven"' showing total 7 results

1. Estimating snow water equivalent over long mountain transects using snowmobile-mounted ground-penetrating radar

Author

Holbrook, W. Steven, primary, Miller, Scott N., additional, and Provart, Matthew A., additional

Published

2016

2. Constraining hydrologic interpretations using near-surface geophysical methods

Author

Flinchum*, Brady, primary, Holbrook, W. Steven, additional, and Clair, James St., additional

Published

2014

3. Direct seismic detection of methane hydrate on the Blake Ridge

Author

Hornbach, Matthew J., Holbrook, W. Steven, Gorman, Andrew R., Hackwith, Kara L., Lizarralde, Daniel, Pecher, Ingo, Hornbach, Matthew J., Holbrook, W. Steven, Gorman, Andrew R., Hackwith, Kara L., Lizarralde, Daniel, and Pecher, Ingo

Abstract

Seismic detection of methane hydrate often relies on indirect or equivocal methods. New multichannel seismic reflection data from the Blake Ridge, located approximately 450 km east of Savannah, Georgia, show three direct seismic indicators of methane hydrate: (1) a paleo bottom‐simulating reflector (BSR) formed when methane gas froze into methane hydrate on the eroding eastern flank of the Blake Ridge, (2) a lens of reduced amplitudes and high P‐wave velocities found between the paleo‐BSR and BSR, and (3) bright spots within the hydrate stability zone that represent discrete layers of concentrated hydrate formed by upward migration of gas. Velocities within the lens (∼1910 m/s) are significantly higher than velocities in immediately adjacent strata (1820 and 1849 m/s). Conservative estimates show that the hydrate lens contains at least 13% bulk methane hydrate within a 2‐km3 volume, yielding 3.2 × 1010kg [1.5 TCF (4.2 × 1010 m3] of methane. Low seismic amplitudes coupled with high interval velocities within the lens offer evidence for possible methane hydrate “blanking.” Hydrate bright spots yield velocities as high as 2100 m/s, with bulk hydrate concentrations predicted as high as 42% in an approximately 15‐m thick layer. Our results show that, under certain circumstances, hydrate in marine sediments can be directly detected in seismic reflections but that quantification of hydrate concentrations requires accurate velocity information. Read More: http://library.seg.org/doi/abs/10.1190/1.1543196

Published

2003

4. Prestack waveform inversion for the water‐column velocity structure‐ the present state and the road ahead

Author

Padhi, Amit, primary, Mukhopadhyay, Pradip, additional, Blacic, Tanya, additional, Fortin, Will, additional, Holbrook, W. Steven, additional, and Mallick, Subhashis, additional

Published

2010

5. Direct seismic detection of methane hydrate on the Blake Ridge

Author

Hornbach, Matthew J., primary, Holbrook, W. Steven, additional, Gorman, Andrew R., additional, Hackwith, Kara L., additional, Lizarralde, Daniel, additional, and Pecher, Ingo, additional

Published

2003

6. Hybrid shortest path and ray bending method for traveltime and raypath calculations

Author

Van Avendonk, Harm J. A., primary, Harding, Alistair J., additional, Orcutt, John A., additional, and Holbrook, W. Steven, additional

Published

2001

7. Seismic signal penetration beneath postrift sills on the Newfoundland rifted margin.

Author

Shililngton, Donna J., Hopper, John R., and Holbrook, W. Steven

Subjects

SEISMIC reflection method data processing, SEISMIC prospecting, FREQUENCY spectra, PENETRATION mechanics

Abstract

Analysis of averaged, smoothed instantaneous frequency and amplitude of seismic-reflection data collected on the Newfoundland magma-starved rifted margin along the Ocean Drilling Program (ODP) leg 210 transect demonstrate that the transparency of "transitional" crust arises from poor signal penetration. In principle, the high-frequency spectral content and amplitude of seismic reflection data should decrease with increasing traveltime as a result of absorption, geometric spreading, and scattering so long as seismic energy continues to return from deeper levels of the subsurface. As a result, if average frequency and amplitude cease to decrease with depth, background noise, rather than returning seismic energy, likely dominates the record. Average frequency increases and average amplitude remains comparatively constant below bright reflections overlying transitional crust on the Newfoundland margin. Similar patterns are not observed at the sediment-basement contact farther seaward in oceanic crust where intracrustal reflections are apparent. In those records, both amplitude and frequency continue to decrease steadily for at least 2-3 s below the top of basement. We interpret these observations as evidence that signal penetration is comparatively poor beneath bright reflections overlying transitional basement. Consequently, the featureless appearance of transitional crust on the Newfoundland margin in seismic-reflection profiles cannot be used to make inferences about its physical properties; instead, only seismic characteristics observed in rare basement highs that rise above bright reflections in the lowermost sedimentary section can provide meaningful information. Weak signal penetration in this crustal domain is consistent with the results from site 1276 during ODP leg 210, where interlayered diabase sills and sediments were recovered above basement, which would be expected to result in high reflection coefficients and low signal penetration. The apparent lack of seismic penetration throughout the transition zone off Newfoundland also implies interlayered sills and sediments might be widespread over this crustal domain. [ABSTRACT FROM AUTHOR]

Published

2008