Paleomagnetic and Anisotropy of Magnetic Susceptibility (AMS) Documentation of the Formation of Large-Scale Rheomorphic Structures in the 2.06 Ma Huckleberry Ridge Tuff, Eastern Idaho

In the Teton River Valley, east of Rexburg, Idaho, the ca. 2.06 Ma Huckleberry Ridge Tuff is about 130 m thick, exceedingly well-exposed, and displays large-scale (100-150 m+ amplitude) rheomorphic folds, with eutaxitic fabrics that are parallel to inferred primary internal zonation (e.g. boundary between basal vitrophyre and overlying devitrified part of the pyroclastic deposit) as well as the basal contact with older deposits defining the fold geometries. One 150 m amplitude fold , is well-exposed on the north side of the valley about 2.5 km east of Teton Dam, has a NW trending fold axis and has a southwest limb that is overturned by about 45o. Samples were collected from 16 sites in this fold, on both limbs and the hinge area, to test the hypothesis that folding took place above maximum TRM blocking temperatures (about 580C). Progressive AF and thermal demagnetization both yield characteristic magnetizations of southwest to south-southwest declination and shallow inclination removed over a range of peak fields (typically between 20 and 80 mT) and laboratory unblocking temperatures (typically between 350 and 580C). The preliminary determination of an in situ mean based on the 16 sites is about D = 215°, I = -5°, a95= 5°, N = 16 site means). The direction of this ChRM is statistically indistinguishable from that reported by previous studies of the tuff (e.g. Reynolds, 1977, JGR; Byrd et al., 1994, JGR). The trend of the fold axis is orthogonal to this declination; the paleomagnetic fold test applied to these data is negative, with k values continuously decreasing upon unfolding, thus indicating that the entire structure in the tuff formed after the well-developed compaction fabric was acquired, at a temperature above maximum blocking temperatures of the ChRM. Post-compaction, high temperature deformation is consistent with field evidence indicating plastic secondary deformation of much of the tuff prior to devitrification. Rapid strain rates probably contributed to the formation of brittle features in the uppermost parts of the tuff (joints and fissures). AMS fabrics, at the site level, are typically very well-defined, with AMS foliations roughly parallel to compaction fabric, with K1 (maximum principal susceptibility) axes typically directed in a southwest-northeast orientation.