Temporal and spatial evolution of a gas hydrate-bearing accretionary ridge on the Oregon continental margin

A seismic-reflection survey on the Oregon continental margin conducted in 1989 indicates the widespread presence of gas hydrate beneath the middle and lower slope of this accretionary margin. The seismic signature of gas hydrate, a bottom simulating reflector (BSR) with negative polarity that locally cuts across stratigraphic horizons, is especially well developed beneath Hydrate Ridge. This anomalously shallow accretionary ridge was drilled during Ocean Drilling Program Leg 146 to study fluid venting. In this paper we focus on the seismic data from the southern part of Hydrate Ridge, where little evidence of active venting has previously been reported but where the seismic data indicate a complicated subsurface plumbing system. Apparent disruptions of the BSR beneath the western ridge flank suggest dissociation of gas hydrate in response to slumping. A double BSR beneath the southern crest suggests hydrate destabilization in response to tectonic uplift and folding. On the basis of these and other observations, we propose a qualitative model for the evolution of a hydrate-bearing ridge in an active accretionary complex in which gas hydrate initially stabilizes the sea floor, permitting construction of large ridges that are then eaten away by slumps along their margins. The north-to-south variation in sea-floor venting and subsurface seismic structure along Hydrate Ridge may reflect different stages in the temporal evolution of one of these ridges.

[1]  R. Hyndman,et al.  A seismic study of methane hydrate marine bottom simulating reflectors , 1992 .

[2]  G. Dickens,et al.  A blast of gas in the latest Paleocene: simulating first-order effects of massive dissociation of oceanic methane hydrate. , 1997, Geology.

[3]  J. Greinert,et al.  Gas hydrate destabilization: enhanced dewatering, benthic material turnover and large methane plumes at the Cascadia convergent margin , 1999 .

[4]  C. Ruppel Anomalously cold temperatures observed at the base of the gas hydrate stability zone on the U.S. Atlantic passive margin , 1997 .

[5]  O. E. S. Party ODP Leg 146 Examines Fluid Flow in Cascadia Margin , 1993 .

[6]  J. Greinert,et al.  Authigenic carbonates from the Cascadia subduction zone and their relation to gas hydrate stability , 1998 .

[7]  J. Moore,et al.  VARIATIONS IN TEMPERATURE GRADIENTS IDENTIFY ACTIVE FAULTS IN THE OREGON ACCRETIONARY PRISM , 1996 .

[8]  M. E. Mackay Structural variation and landward vergence at the toe of the Oregon accretionary prism , 1995 .

[9]  W. Dillon,et al.  Is the extent of glaciation limited by marine gas-hydrates , 1991 .

[10]  M. Torres,et al.  In situ measurement of fluid flow from cold seeps at active continental margins , 1994 .

[11]  M. Yamano,et al.  Deep sea bottom-simulating-reflectors: calibration of the base of the hydrate stability field as used for heat flow estimates * , 1992 .

[12]  K. Kvenvolden Methane hydrates and global climate , 1988 .

[13]  J. S. Booth,et al.  Evidence for faulting related to dissociation of gas hydrate and release of methane off the southeastern United States , 1998, Geological Society, London, Special Publications.

[14]  Warren T. Wood,et al.  Methane Hydrate and Free Gas on the Blake Ridge from Vertical Seismic Profiling , 1996, Science.

[15]  R. Yeats,et al.  Oblique strike-slip faulting of the central Cascadia , 1997 .

[16]  Thomas H. Shipley,et al.  Seismic Evidence for Widespread Possible Gas Hydrate Horizons on Continental Slopes and Rises , 1979 .

[17]  K. Brown,et al.  The nature, distribution, and origin of gas hydrate in the Chile Triple Junction region , 1996 .