We investigate a particle in a ratchet potential (the system) coupled to an harmonic bath of N=1-500 degrees of freedom (the discrete bath). The dynamics of the energy exchange between the system and the discrete bath is studied in the transition regime from low to high values of N . First manifestation of dissipation (energy lost by the system) appears for the bath composed of 10 less, similar N less, similar 20 oscillators, as expected. For low values of N , beside small dissipation effects, the system experiences the bath-induced particle transfer between different potential wells from the ratchet. We show that this effect decreases the mobility of particles along the ratchet. The hopping probability along the ratchet and the energy decay rates for the system are shown to obey the power law for late times, a behavior typical of discrete baths which for low and intermediate values of N always induce a non-Markovian process. The exponential decay is recovered for high bath frequencies distribution and for high values of N , where the Markovian limit is expected. Moreover, by including the external oscillating field with intensity F , we show that current reversal occurs in two situations: By increasing N and by switching from low to high frequencies distribution of the bath. The mobility of particles is shown to have a maximum at F=0.1 , which is N independent (for higher values of N ).
A system plus environment conservative model is used to characterize the
nonlinear dynamics when the time averaged energy for the system particle starts
to decay. The system particle dynamics is regular for low values of the $N$
environment oscillators and becomes chaotic in the interval $13\le N\le15$,
where the system time averaged energy starts to decay. To characterize the
nonlinear motion we estimate the Lyapunov exponent (LE), determine the power
spectrum and the Kaplan-Yorke dimension. For much larger values of $N$ the
energy of the system particle is completely transferred to the environment and
the corresponding LEs decrease. Numerical evidences show the connection between
the variations of the {\it amplitude} of the particles energy time oscillation
with the time averaged energy decay and trapped trajectories.Comment: 18 pages and 10 figure
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