Scientist I

The University of Madison Department of Nuclear Engineering and Engineering Physics seeks to hire a research scientist to support a 4-year Fusion Innovation Research Engine (FIRE) in Fusion Neutrons for Integrated Blanket Technology Development Through Advanced Testing and Design, funded by the U.S. DOE Office of Fusion Energy Sciences (FES). UW-Madison is working with academic, national lab and industry partners to deliver a cross-cutting research project culminating in first-of-its-kind integrated fusion blanket system testing. Partners include MIT, SHINE, EPRI, Realta Fusion, Rockwell Automation, Argonne National Laboratory, Princeton Plasma Physics Laboratory, Lawrence Livermore National Laboratory, University of Illinois Urbana Champaign and University of New Mexico. Additionally, the UW-Madison Department of Nuclear Engineering and Engineering Physics is leading an FES funded project investigating hydrogen isotope retention in fusion materials through elevated-temperature 14 MeV neutron irradiations, in partnership with SHINE Technologies’ FLARE facility. This project will neutron irradiate additively manufactured W, Ta, V44, and Eurofer97 specimens, at temperatures between 500-800°C, before subsequent deuterium charging and thermal desorption spectroscopy. Both of these projects will combine to address a crucial gap in the development of fusion pilot plants (FPPs): the development and validation of integrated blanket technology in prototypical environments - particularly under the irradiation of 14 MeV D-T neutrons, at elevated temperatures, and with high-magnetic fields - to demonstrate representative performance of key components and systems. Guided by industry-informed use cases, the FIRE collaborative will manufacture and test advanced components for blankets (PbLi and FLiBe) made from materials paired with these coolants (RAFM-SiC and V44-W), under prototypic conditions, and using state-of-the-art U.S. facilities including FLARE and WHAM. Integration across the FIRE project is delivered through a model-based systems engineering (MBSE) methodology, which leverages advanced AI/ML techniques to improve validation and computational design of fusion energy systems. This will include collaboration with the experiments being performed at FLARE, WHAM and other facilities throughout the collaborative, but we also target collaboration with tritium breeding and high heat flux experiments at other FIRE collaboratives for improved high-fidelity predictions and accelerate design innovation. UW-Madison is seeking an early career fusion technologist to drive technical integration efforts tasks across the collaborative; identify new and emergent research opportunities; and support project reporting and data management. It is anticipated this position requires work be performed in-person, onsite, at a designated campus work location