PALEOMAGNETISM AND PALEOTHERMOMETRY OF THE SYDNEY BASIN .1. THERMOVISCOUS AND CHEMICAL OVERPRINTING OF THE MILTON MONZONITE

The Early Triassic (similar to 245 Ma) Milton Monzonite of the Sydney Basin, Australia, has four distinct components of natural remanent mag netization (NRM) with only slightly overlapping ranges of unblocking t emperatures. The low-temperature (LT) component, the first to be therm ally demagnetized, is thought to be a Late Cretaceous (approximate to 100 Ma) thermoviscous overprint acquired in slow cooling during uplift . The high-temperature (HT) component, the second to be demagnetized, is probably the primary thermoremanent magnetization (TRM) of the Milt on intrusion but could possibly be a Jurassic overprint. LT and HT are usually carried by magnetite and occasionally by pyrrhotite. Samples from nine sites have a further NRM component which unblocks at higher temperatures than HT but below the magnetite Curie temperature of 580 degrees C. This component is argued to be a chemical remanent magnetiz ation (CRM) because of its discrete range of high unblocking temperatu res, above those of the thermal components HT and LT, and is called CR M1. CRM1 has almost the same direction as LT and is likely carried by authigenic magnetite produced during uplift similar to 100 Ma. Samples from five sites have a fourth NRM component, with a direction resembl ing that of HT but carried by hematite. This fourth component could be a primary TRM but is more likely a CRM and is therefore called CRM2. The HT-CRM2 mean direction is D= 50 degrees, I= 75.5 degrees, defining a pareopole at 16 degrees S, 172 degrees E. The HT-CRM2 paleopole fal ls near 150 Ma on the Australian apparent polar wander path but is a c onsiderable distance from paleopoles of Permian and Early Triassic age . There is no known tectonic or other remagnetizing event in the Sydne y Basin around 150 Ma. For this reason, we propose that the HT-CRM2 pa leopole defines a new Triassic segment of the Australian polar wander path. The LT-CRM1 mean direction is D= 348 degrees, I= -79 degrees, wi th a paleopole falling at 56 degrees S, 158 degrees E, near 100 Ma on the polar wander path. This age is consistent with uplift and cooling related to initial rifting of the Tasman Sea.