Effects of long-range dispersion in nonlinear dynamics of DNA molecules
Abstract
A discrete nonlinear Schrodinger (NLS) model with long-range dispersive interactions describing the dynamical structure of DNA is proposed. Dispersive interactions of two types: the power dependence r-s and the exponential dependence e-β r on the distance, r, are studied. For s less than some critical value, scr, and similarly for β ≤ βcr there is an interval of bistability where two stable stationary states: narrow, pinned states and broad, mobile states exist at each value of the total energy. For cubic nonlinearity the bistability of the solitons occurs for dipole-dipole dispersive interaction (s=3), and for the inverse radius of the dispersive interaction β ≤ βcr=1.67. For increasing degree of nonlinearity, σ, the critical values scr and βcr increase. The long-distance behavior of the intrinsically localized states depends on s. For s>3 their tails are exponential while for 2<s<3 they are algebraic. A controlled switching between pinned and mobile states is demonstrated applying a spatially symmetric perturbation in the form of a parametric kick. The mechanism could be important for controlling energy storage and transport in DNA molecules.
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