Molecular dynamics of deuterium plasma on TiB₂ sputtering in tokamak wall surfaces for Shannon entropy of computation

Maintaining the plasma core process for generating heat energy—which a turbine uses to generate electricity-is the major objective of creating Tokamak reactor fusion technology. Solving Tokamak reactor process difficulties is a substantial task owing to plasma-material interactions. Interactions between plasma and surface material occur at the molecular level. This study investigates the Shannon entropy estimate for sputtering operations using molecular dynamics simulation of TiB₂ as a novel material for surface processes exposed to deuterium plasma. TiB₂ is one of the possible structural materials for divertor regions in Tokamak fusion reactors. The molecular dynamics process results in the production of kinetic energy, potential energy, and sputtering yield for the system. As a result, the target surface morphology, chemistry, plasma properties, and Shannon entropy information all have an impact on the plasma-induced surface morphology of TiB₂ surface layers. Based on molecular dynamics procedures, impurity-driven surface features are a well-documented phenomenon in published experimental studies. Because this theoretical investigation will confirm that the material surface features of plasma-exposed samples are chemically characterized.