A major challenge for heat transfer in nuclear materials is to ensure thermal mobility after high amounts of neutron irradiation.  Tungsten is widely selected as a heat transfer material in fusion reactors.  In metals, thermal conductivity is dominated by electrons’ ability to transfer energy.  Neutron irradiation generates point defects, clusters, and solid transmutation (e.g.rhenium and osmium in tungsten), which inhibit electron motion.  The purpose of this work is to quantify the irradiation-induced change in electron mobility and deconvolute transmutation and microstructural effects on observed changes to electron mobility.

Single and polycrystalline tungsten were fast neutron irradiated in the High Flux Isotope Reactor at Oak Ridge National Laboratory to doses between 0.2 and 0.7 displacements per atom (dpa) and temperatures from 500°C to 1000°C.  Grain growth was observed in all samples.  Microstructure and transmutation were quantified.  The geometric orientation of samples with elongated grains has been shown to affect electrical resistivity.  A mathematical model was developed and used to deconvolute solid-solution transmutation, grain, and temperature-dependent lattice effects on resistivity.  At ~0.4 dpa at ~590°C, the combined resistivity degradation due to voids, vacancies, interstitials, and dislocations is estimated to be greater than the contribution from solid solution Re transmutation, which is greater than the contribution from grain boundaries.  At doses of ~0.7 dpa at ~750°C, solid solution Re contributions are greater than all other effects combined.  This work establishes a basis to predict the effects of irradiation temperature and transmutation on thermal properties of tungsten and highlights the importance of irradiation temperature.