C. Denk scite author profile

In the context of the phenomenon of Stochastic Resonance (SR) we study the correlation function, the signal-to-noise ratio (SNR) and the ratio of output over input SNR, i.e. the gain, which is associated to the nonlinear response of a bistable system driven by time-periodic forces and white Gaussian noise. These quantifiers for SR are evaluated using the techniques of Linear Response Theory (LRT) beyond the usually employed two-mode approximation scheme. We analytically demonstrate within such an extended LRT description that the gain can indeed not exceed unity.We implement an efficient algorithm, based on work by Greenside and Helfand (detailed in the Appendix), to integrate the driven Langevin equation over a wide range of parameter values. The predictions of LRT are carefully tested against the results obtained from numerical solutions of the corresponding Langevin equation over a wide range of parameter values. We further present an accurate procedure to evaluate the distinct contributions of the coherent and incoherent parts of the correlation function to the SNR and the gain. As a main result we show for subthreshold driving that both, the correlation function and the SNR can deviate substantially from the predictions of LRT and yet, the gain can be either larger or smaller than unity. In particular, we find that the gain can exceed unity in the strongly nonlinear regime which is characterized by weak noise and very slow multifrequency subthreshold input signals with a small duty cycle. This latter result is in agreement with recent analogue simulation results by Gingl et al. in Refs. [18,19].

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Solvation in binary mixtures of dipolar hard sphere solvents: Theory and simulations

Morillo

Denk

Sánchez-Burgos

et al. 2000

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The structure of mixtures of dipolar hard sphere fluids with components of equal size but different dipole moments around a single ion is studied. The solvation energy and the polarization around the ion is obtained in the framework of the mean spherical approximation ͑MSA͒. Our theoretical results and the results of other workers are compared with simulation data obtained from Monte Carlo simulations. An interpretation of the meaning of preferential solvation is given in terms of the contrasting behaviors of partial polarization in the bulk and near the ion.

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Reorganization energies for charge transfer reactions in binary mixtures of dipolar hard sphere solvents: A Monte Carlo study

Denk

Morillo

Sánchez-Burgos

et al. 1999

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Control of tunneling reactions with an external field in a four-level system: A general Redfield approach

1996

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Control of tunneling processes with an external field in a four-level system: an analytic approach

Cukier¹,

Denk²,

Morillo³

1997

Chemical Physics

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C. Denk

Gain in stochastic resonance: Precise numerics versus linear response theory beyond the two-mode approximation

Solvation in binary mixtures of dipolar hard sphere solvents: Theory and simulations

Reorganization energies for charge transfer reactions in binary mixtures of dipolar hard sphere solvents: A Monte Carlo study

Control of tunneling reactions with an external field in a four-level system: A general Redfield approach

Control of tunneling processes with an external field in a four-level system: an analytic approach

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