Abstract
Low-z materials are exemplary candidates in tiling critical plasma-facing components in future fusion reactors due to their low ablation rates under intense high heat fluxes especially during abnormal and hard disruption events. Beryllium and Lithium as low-z materials show good performance as plasma-facing materials in current tokamak. Future tokamaks will exhibit long duration hard disruptions, which in turn requires further investigation of plasma-facing materials, as Li and Be, to judge their performance and evaluate their erosion rates. Electrothermal plasma capillary discharges are used to simulate the high-heat flux deposition on materials to assess their erosion rates. The electrothermal plasma code ETFLOW, which is written for capillary discharges to predict the plasma parameters and erosion rates is used to simulate the high-heat flux conditions similar to expected disruption events for simulated heat fluxes from as low as ~50 to as high as ~290 GW/m2 with a reconnoitering of generating the Be and Li plasmas up to the third ionization (Br+++, Li+++). Performance of Be and Li under the lowest capillary discharge currents (50 kA and 100 kA) is almost identical, however, Li shows sharper increase in the plasma pressure, heat flux, total ablated mass and the exit velocities than Be for higher discharge currents (150, 200 and 250 kA). This huge difference between the performance of Li and Be under low and high heat fluxes can be an important issue for the future magnetic fusion reactors.
Highlights
Magnetic fusion Tokamak reactors like ITER will be the first step to test the viability of fusion and to help solving the engineering problems associated with such reactors
One of the challenges in these devices is the plasma-material interactions (PMI) issues because impurities produced as a result of these interactions deteriorate plasma performance
Low Z materials are preferred for first wall of fusion reactors like Carbon, Beryllium and Lithium
Summary
Magnetic fusion Tokamak reactors like ITER will be the first step to test the viability of fusion and to help solving the engineering problems associated with such reactors. There is the effect on the lifetime of the plasma-facing materials (PFMs) due to ablation resulting from high heat flux exposure during normal and abnormal operational regimes These impurities contaminate the core plasma and dilute the hydrogenic fuel, which gives rise to the loss of energy due to increased Bremsstrahlung radiation. The electrothermal plasma code ETFLOW, which is written for capillary discharges to predict the plasma parameters and erosion rates, simulates the highheat flux conditions similar to expected disruption events It has been used in this study for simulated heat fluxes from as low as ~50 to as high as ~290 GW/m2 with a reconnoitering of generating the beryllium and lithium plasmas up to the third ionization (Be+++, Li+++)
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