EP23C-0980
Provenance Analysis using Raman Spectroscopy of Carbonaceaous Material: a case study in the Southern Alps of New Zealand

Tuesday, 15 December 2015
Poster Hall (Moscone South)
Lukas Nibourel, University of Bern, Institute of Geological Sciences, Bern, Switzerland, Frederic Herman, ETH, Zurich, Switzerland, Simon Cox, GNS Science-Institute of Geological and Nuclear Sciences Ltd, Lower Hutt, New Zealand, Olivier Beyssac, IMPMC Institut de Minéralogie et de Physique des Milieux Condensés, paris, France and Jerome Lave, CRPG Centre de Recherches Pétrographiques et Géochimiques, Vandoeuvre-Les-Nancy, France
Abstract:
Detrital provenance analyses in orogenic settings, in which sediments are collected at the outlet of a catchment, have become an important tool to estimate how erosion varies in space and time. Here we present how Raman Spectroscopy on Carbonaceous Material (RSCM) can be used for provenance analysis. RSCM provides an estimate of the peak temperature (RSCM-T) experienced during metamorphism. We show that we can infer modern erosion patterns in a catchment by combining new measurements on detrital sands with previously acquired bedrock data. We focus on the Whataroa catchment in the Southern Alps of New Zealand and exploit the metamorphic gradient that runs parallel to the main drainage direction. To account for potential sampling biases, we also quantify abrasion properties using flume experiments and measure the total organic carbon content in the bedrock that produced the collected sands. Finally, we integrate these parameters into a mass-conservative model. Our results first demonstrate that RSCM-T can be used for detrital studies. Second, we find that spatial variations in tracer concentration and erosion have a first-order control on the RSCM-T distributions, even though our flume experiments reveal that weak lithologies produce substantially more fine particles than do more durable lithologies. This result implies that sand specimens are good proxies for mapping spatial variations in erosion when the bedrock concentration of the target mineral is quantified. The modeling suggests highest present-day erosion rates (in Whataroa catchment) are not situated at the range front, as might be expected from the long-term metamorphic rock exhumation pattern, but about 10 km into the mountain belt near the location of maximum rain fall and highest short-term (contemporary) inter-seismic uplift.