Thermal shock of tungsten carbide in plasma-facing conditions

Abstract: Tungsten carbide (WC) has been found to have higher resistance to plasma-induced thermalshock compared to rolled tungsten. The electron beam device JUDITH 1 was used to simulate likely thermal shock conditions induced by edge localised modes and plasma disruptions. Loading conditions of 100-1000 cycles, heat fluxes of 0.19-1.13 GW/m 2 and base temperatures of 400-1000 °C were employed on two candidate WC-based materials: a monolithic WC ceramic, and a WC-FeCr composite. Surprisingly, the monolith outperformed … Show more

“…In addition to those critical applications, BTC components are regaining focus from the research community as neutron shielding material in fast breeder reactors [3] and as a promising candidate for plasma-facing components of fusion reactors [4][5][6]. Despite its intrinsic brittle behaviour, monolithic WC shows unexpectedly higher thermal shock resistance than cermets when subjected to extreme heat flux conditions like edge localisation and plasma disruption events [7]. WC and some of its composites (WC/B 4 C, WC/TiC, etc.)…”

Does Flash Sintering Alter the Deformation Mechanisms of Tungsten Carbide?

“…In addition to those critical applications, BTC components are regaining focus from the research community as neutron shielding material in fast breeder reactors [3] and as a promising candidate for plasma-facing components of fusion reactors [4][5][6]. Despite its intrinsic brittle behaviour, monolithic WC shows unexpectedly higher thermal shock resistance than cermets when subjected to extreme heat flux conditions like edge localisation and plasma disruption events [7]. WC and some of its composites (WC/B 4 C, WC/TiC, etc.)…”

Does Flash Sintering Alter the Deformation Mechanisms of Tungsten Carbide?

“…The recent development of high-field, high-temperature superconducting magnets [2,3] make compact spherical tokamaks (cSTs) a feasible option for rapid testing and deployment of fusion reactors but a major difficulty is shielding the magnets from the neutron and gamma radiation, particularly the central column [4]. cSTs require compact radiation shielding to be practical devices and candidate materials are currently under consideration include W and W-metal alloys [5], mixed borides including reactive sintered borides (RSBs) [6,7] tungsten borides [8][9][10] and cemented tungsten carbide (cWCs) [4,11,12]. Development of practical neutron and gamma-radiation materials that can protect the HTS magnets is required for fusion power to be a power source by the 2040 s…”

Synthesis Studies of Radiation Dense Reactive Sintered Borides (Rsb) Nuclear Shielding Materials

“…Tungsten carbide is a candidate neutron shielding material for fusion reactors due to its combined neutron moderation by carbon and the gamma attenuation of tungsten [1,2]. It's high flexural strength and toughness [3], thermal conductivity [4], sputtering resistance [5] and thermal shock resistance under edge-localised modes [6], also make it a promising candidate plasma facing material. The material also benefits from significant advantages in manufacturability and mechanical properties over other candidate materials such as tungsten, particularly when combined with a metallic binder [7].…”

Ablation resistance of tungsten carbide cermets under extreme conditions