The continuum elastic and atomistic viewpoints on the formation volume and strain energy of a point defect

We discuss the roles of continuum linear elasticity and atomistic calculations in determining the formation volume and the strain energy of formation of a point defect in a crystal. Our considerations bear special relevance to defect formation under stress. The elasticity treatment is based on the Green’s function solution for a center of contraction or expansion in an anisotropic solid. It makes possible the precise definition of a formation volume tensor and leads to an extension of Eshelby’s result for the work done by an external stress during the transformation of a continuum inclusion (Proc. Roy. Soc. Lond. Ser. A, 241(1226), 376, 1957 ). Parameters necessary for a complete continuum calculation of elastic fields around a point defect are obtained by comparing with an atomistic solution in the far field. However, an elasticity result makes it possible to test the validity of the formation volume that is obtained via atomistic calculations under various boundary conditions. It also yields the correction term for formation volume calculated under these boundary conditions. Using two types of boundary conditions commonly employed in atomistic calculations, a comparison is also made of the strain energies of formation predicted by continuum elasticity and atomistic calculations. The limitations of the continuum linear elastic treatment are revealed by comparing with atomistic calculations of the formation volume and strain energies of small crystals enclosing point defects. Assistant professor, Dept. of Mechanical Engineering, and Program in Applied Physics. Corresponding [email protected] Assistant professor, Dept. of Materials Science and Engineering, and Program in Applied Physics. Formerly, graduate research assistant, Dept. of Materials Science and Engineering. Now a post-doctoral fellow at Institute of Materials Research and Engineering, Singapore. Graduate research assistant, Dept. of Materials Science and Engineering. Graduate research assistant, Dept. of Mechanical Engineering.