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Abstract
In this article, we present an asymptotic analysis of waves of elastic stress in an infinite solid whose boundary is subject to a rapid thermal load. The problem under consideration couples the wave equation and the heat equation, and the asymptotic approximation of the solution requires three-scaled variables. The asymptotic approximation is supplied with a rigorous remainder estimate and is illustrated numerically.
Notes
This is especially pronounced for the materials with relatively high thermal diffusivity, for example, germanium (κ = 0.31 cm2s−1), gallium nitride (κ = 0.43 cm2s−1) or gallium arsenide (κ = 0.31 cm2s−1) widely used in modern electronics applications (see, for example, http://www.carondelet.pvt.kl2.ca.us/Family/Science/GroupIVA/germanium.htm). The speed a of dilatational waves in germanium is around 5400 m/s. Hence, one can deduce that even if the duration of thermal loading is of the order 10−12 of a second, such a time interval should not be treated as a negligibly small quantity if represented in terms of the normalized time-variable τ = a 2 t/κ.