Abstract
• In cold-rolled W, a striking fraction of straight dislocations spans across the grains. • These segments are presumably ½〈111〉 screw type and the result of rolling below the knee temperature. • The contributions of CSL boundaries to the reduction in BDT temperature seems negligible. • Hall–Petch-like attempts describe the rolling-induced reduction in BDT temperature. • Considering LABs and HABs instead of HABs only results in more promising correlations. One of the key demands on tungsten (W) as designated plasma-facing material (PFM) is the capability to fulfill a structural function. Since W has refused ductilization strategies by alloying alone, the production of W materials with enhanced ductility has come into focus considering tailored microstructures. This work addresses the rolling-induced microstructural modifications of warm- and cold-deformed W sheets and is supplemented by a comprehensive fracture mechanical study as a fundament for correlations between the spatial distribution of boundaries and brittle-to-ductile transition (BDT) temperature. Here we show that an extended Hall–Petch-like relationship is well suited to describe the rolling-induced reduction in BDT temperature and moreover has the potential to reflect the anisotropic nature of the transition temperature in severely rolled W sheets. Using the data of warm- and cold-rolled W sheets and also of strongly recovered W, best description of the BDT temperature was achieved by using as microstructural variables (i) the mean spacing between boundaries which intersect with the crack front and (ii) the mean boundary spacing along the normal of the crack plane. Taking into account the similarity to recent simulative-derived relationships, our findings support the theory suggesting the stimulated dislocation nucleation at boundaries as the decisive factor for more effective shielding of the crack tip in UFG materials and, in consequence, significantly reduced BDT temperatures. Besides, this work gives strong indications that the reduction of the BDT temperature in UFG W is not related to coincidence site lattice (CSL) boundaries.
Highlights
During the operation of fusion reactors, plasma-facing materials (PFMs) are exposed to high fluences of neutrons and have to withstand highest thermal loads
We elucidate the rolling-induced evolution in brittle-to-ductile transition (BDT) tempera ture and lattice defects of W sheets
We want to highlight that the various thicknesses of the specimens can be neglected in the discussion of the BDT temperature
Summary
During the operation of fusion reactors, plasma-facing materials (PFMs) are exposed to high fluences of neutrons and have to withstand highest thermal loads. Low rates of sputtering erosion favor high-Z materials as divertor PFM [1]. Among these materials, tungsten (W) is the front-runner candidate at the present moment [2]. To give numbers: W with a recrystallized microstructure exhibits usually BDT temperatures, which are around 650 K [4] using notched specimens under quasi-static loading and 1000 K [5] in Charpy impact experiments. Even worse than the recrystallized conditions be haves as-sintered W [6], having BDT temperatures in the range 900 K1100 K [7,8,9] and in the region around 1200 K for dynamic loading rates (all temperatures are related to notched specimens).
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