2017 Annual Meeting

(315f) Solar Thermochemical Fuel Production in a Microreactor

Authors

Fuqiong Lei - Presenter, Oregon State University
Yige Wang, Oregon State University
Thana Sornchamni, PTT Public Company Limited
Goran Jovanovic, Oregon State University
Liney Arnadottir, Oregon State University
Alexandre Yokochi, Baylor University
Nick AuYeung, Oregon State University
Harvesting and utilizing solar energy offers a sustainable way to reduce the use of fossil fuels and meet the increasing demand of energy. High temperature thermochemical reactions using concentrated solar power are of great interest due to the stored energy density associated with chemical fuels. The aim of this project is to develop technology suitable for the direct utilization of solar thermal energy through chemical processes. Both high temperature (ca. 1400°C) thermochemical water/carbon dioxide splitting cycle and moderate temperature (600-700°C) dry reforming of methane are considered. The critical component of this project is mesoscale-based reactor for the purpose of solar fuel generation. The mesoscale-based reactor, which offers advantages such as fast heat and mass transfer as well as flexibility in capacity and in design, was designed, built and tested. The reactive materials (perovskites) for high-temperature thermochemical splitting and catalysts for dry reforming of methane were synthesized, characterized and tested in the reactor.