HR: 11:15h
AN: T31D-10
TI: GPS Constraints on Forearc Sliver Motion, Plate Coupling,
and Strain Partitioning in Northwestern Oregon
AU: *McCaffrey, R
EM: mccafr@rpi.edu
AF: Dept. of Earth and Environmental Sciences,
Rensselaer Polytechnic Institute Troy, NY 12180-3590 United States
AU: Goldfinger, C
EM: gold@oce.orst.edu
AF: College of Oceanic and Atmospheric Sciences,
Oregon State University
Corvallis, OR 97331 United States
AU: Murray, M H
EM: mmurray@pangea.stanford.edu
AF: Department of Geophysics,
Stanford University Stanford, CA 94305-2215 United States
AU: Zwick, P
EM: zwickp@rpi.edu
AF: Dept. of Earth and Environmental Sciences,
Rensselaer Polytechnic Institute Troy, NY 12180-3590 United States
AU: Nabelek, J L
EM: nabelekj@ucs.orst.edu
AF: College of Oceanic and Atmospheric Sciences,
Oregon State University
Corvallis, OR 97331 United States
AU: Johnson, C K
EM: johnsc2@rpi.edu
AF: Dept. of Earth and Environmental Sciences,
Rensselaer Polytechnic Institute Troy, NY 12180-3590 United States
AB: Repeated Gobal Positioning System measurements along a
forearc-crossing transect in NW Oregon between Eugene and
Salem ($44\deg$N to $45\deg$N, $121\deg$W to $124\deg$W) are being used to explore
the motion of the Oregon forearc relative to North America,
plate coupling, and strain partitioning associated with
oblique convergence between the Juan de Fuca plate and North
America. We are utilizing GPS occupations made by the US
Geological Survey in 1992 and 1994, by Rensselaer and Oregon
State in 1996, 1997, and 1998 and by the National Geodetic
Survey in 1998. (The August 1998 survey is part of a
statewide reference survey conducted by the NGS and many
local county and private surveyors.) In addition, we have
operated 2 continuous sites in this corridor since early 1996
and a third was installed by Central Washington University in
July, 1998, all forming part of the Pacific Northwest
Geodetic Array (PANGA). Preliminary results based on 1994,
1996, and 1997 data suggest that the Oregon forearc moves
north relative to North America at several mm/yr possibly
with localized shear along the Cascades arc. We see
evidence for distributed margin-parallel shear strain
across the forearc but uncertainties are still too large to
allow resolution of spatial variations in it. The
overall principal contraction direction is rotated from the
plate convergence direction toward the trench-normal, a
sign of strain partitioning. These results suggest that
plate coupling extends farther inland at this latitude than
is interpreted from uplift data alone. Similar rotation of
the principal contraction direction occurs at the Nankai
trough near Shikoku where convergence is oblique. Results
from Oregon that incorporate the 1992 USGS and 1998 RPI/OSU
measurements in the velocity determinations will be
presented at the meeting. We will also discuss the expected
relationships between plate coupling variations, rotations
of the principal strains, and the across-forearc
distribution of margin-parallel shear strain based on
finite element models.
DE: 8150 Plate boundary--general (3040)
DE: 8158 Plate motions--present and recent (3040)
DE: 8159 Rheology--crust and lithosphere
DE: 9350 North America
SC: T
MN: 1998 Fall Meeting