2006 Philadelphia Annual Meeting (22–25 October 2006)

Paper No. 10
Presentation Time: 1:30 PM-5:30 PM

STRUCTURAL ANALYSIS OF ROCK CANYON NEAR PROVO, UTAH


WALD, Laura C., KOWALLIS, Bart J. and HARRIS, Ronald A., Geological Sciences, Brigham Young University, Provo, UT 84602, kowallis@byu.edu

A detailed structural study of Rock Canyon (near Provo, Utah) provides insight into Wasatch Range tectonics and fold-thrust belt kinematics. Excellent exposures along the E-W trending canyon allow the use of digital photography in conjunction with traditional field methods for a more thorough analysis of Rock Canyon's structural features. Highly detailed photomontages and analysis of some structural features help to pinpoint mechanisms used throughout the canyon's tectonic history. Larger-scale images and these structural data are synthesized in a balanced cross section, which is used to reconstruct the structural evolution of this portion of the range. Projection of surficial features into the subsurface produces geometrical relationships that correlate well with a fault-bend fold model involving one or more subsurface imbrications. Kinematic data (e.g. slickenlines, fractures, fold axes) indicate that the maximum stress direction during formation of the fault-bend fold trended at approximately S60E. Following initial thrusting, uplift and development of a thrust splay produced by duplexing may have caused a shift in local stresses in the forelimb of the Rock Canyon anticline leading to late-stage normal faulting during Sevier compression. These normal faults activated deformed zones previously caused by Sevier folding, and reactivated early-stage decollements found in the folded weak shale units and shaley limestones. Movement on most of these normal faults roughly parallels stress directions found during initial thrusting indicating that these extensional features are coeval with thrusting. Other zones of extension and brittle failure produced by lower ramp geometry appear to have been activated during Tertiary Basin and Range extension along the Wasatch Fault Zone. Slickenline data on these later normal faults suggest a transport direction of nearly E-W distinguishing it from earlier events.