Deep Fault‐Controlled Fluid Flow Driving Shallow Stratigraphically Constrained Gas Hydrate Formation: Urutī Basin, Hikurangi Margin, New Zealand

Author:

Gorman Andrew R.1ORCID,Crutchley Gareth J.2ORCID,Baker Dylan R.1,Fraser Douglas R. A.1,Henrys Stuart A.3ORCID,Tréhu Anne M.4ORCID,Harris Robert N.4ORCID,Phrampus Benjamin J.45ORCID,Pecher Ingo A.67ORCID

Affiliation:

1. Department of Geology University of Otago Dunedin New Zealand

2. GEOMAR Helmholtz Zentrum für Ozeanforschung Kiel Kiel Germany

3. GNS Science Lower Hutt New Zealand

4. College of Earth, Ocean, and Atmospheric Sciences Oregon State University Corvallis OR USA

5. Now at U.S. Naval Research Laboratory John C. Stennis Space Center MS USA

6. School of Environment University of Auckland Auckland New Zealand

7. Now at Texas A&M University Corpus Christi Corpus Christi TX USA

Abstract

AbstractThe Hikurangi Margin east of New Zealand's North Island hosts an extensive gas hydrate province with numerous gas hydrate accumulations related to the faulted structure of the accretionary wedge. One such hydrate feature occurs in a small perched upper‐slope basin known as Urutī Basin. We investigated this hydrate accumulation by combining a long‐offset seismic line (10‐km‐long receiver array) with a grid of high‐resolution seismic lines acquired with a 600‐m‐long hydrophone streamer. The long‐offset data enable quantitative velocity analysis, while the high‐resolution data constrain the three‐dimensional geometry of the hydrate accumulation. The sediments in Urutī Basin dip landward due to ongoing deformation of the accretionary wedge. These strata are clearly imaged in seismic data where they cross a distinct bottom simulating reflection (BSR) that dips counterintuitively in the opposite direction to the regional dip of the seafloor. BSR‐derived heat flow estimates reveal a distinct heat flow anomaly that coincides spatially with the upper extent of a landward‐verging thrust fault. We present a conceptual model of this gas hydrate system that highlights the roles of fault‐controlled fluid flow at depth merging into strata‐controlled fluid flow into the hydrate stability zone. The result is a layer‐constrained accumulation of concentrated gas hydrate in the dipping strata. Our study provides new insight into the interplay between deep faulting, fluid flow and gas hydrate formation within an active accretionary margin.

Funder

Division of Ocean Sciences

Crown Research Institutes

Publisher

American Geophysical Union (AGU)

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