Soft modes and elasticity of nearly isostatic lattices: randomness and dissipation

Abstract

The square lattice with central-force springs on nearest-neighbor bonds is isostatic. It has a zero mode for each row and column, and it does not support shear. Using the Coherent Potential Approximation (CPA), we study how the random addition, with probability P=(z-4)/4 (z = average number of nearest neighbors), of springs on next-nearest-neighbor (NNN) bonds restores rigidity and affects phonon structure. We find that the CPA effective NNN spring constant m(ω), equivalent to the complex shear modulus G(ω), obeys the scaling relation, m(ω) = m h(ω/ω*), at small P, where m = 'm(0) P2 and ω* P, implying that elastic response is nonaffine at small P and that plane-wave states are ill-defined beyond the Ioffe-Regel limit at ω≈ ω*. We identify a divergent length l* P-1, and we relate these results to jamming.