Jeremy Q. Broughton scite author profile

We develop a novel technique for simulation of the mechanics of micron-scale solid systems: Coarse Grained Molecular Dynamics (CGMD). It captures the important atomistic e ects without the computational cost of conventional molecular dynamics (MD). The CGMD equations of motion are derived directly from nite temperature MD through a statistical coarse graining procedure, so they agree with MD as the mesh size is reduced to the atomic scale. This allows a seamless coupling of length scales. The use of e cient CGMD in peripheral regions extends atomistic simulation to much larger systems than amenable to MD alone.

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Crystallization Rates of a Lennard-Jones Liquid

Broughton¹,

Gilmer²,

Jackson³

1982

Phys. Rev. Lett.

342

215

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Molecular dynamics investigation of the crystal–fluid interface. VI. Excess surface free energies of crystal–liquid systems

1986

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We present the first direct calculation by simulation of the excess surface free energy of a crystal–liquid interface. We perform these calculations on the (111), (100), and (110) interfaces of a truncated Lennard-Jones face-centered-cubic crystal–liquid system at the triple point by the molecular dynamics technique. Bulk crystal and liquid systems are first cleaved and then combined with one another reversibly. The work required to do this is integrated and equals the excess surface Helmholtz (and Gibbs) free energy. The free energies are found to be 0.35±0.02, 0.34±0.02, and 0.36±0.02 (dimensionless units) for the (111), (100), and (110) faces, respectively. The three faces are therefore energetically isotropic within our error bars and the equilibrium form of the crystal is approximately spherical.

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Spanning the continuum to quantum length scales in a dynamic simulation of brittle fracture

et al. 1998

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