Abstract
The use of the electric curtain (EC) has been proposed for manipulation and control of particles in various applications. The EC studied in this paper is called the 2-phase EC, which consists of a series of long parallel electrodes embedded in a thin dielectric surface. The EC is driven by an oscillating electric potential of a sinusoidal form where the phase difference of the electric potential between neighboring electrodes is 180°. We investigate the one- and two-dimensional nonlinear dynamics of a particle in an EC field. The form of the dimensionless equations of motion is codimension two, where the dimensionless control parameters are the interaction amplitude (A) and damping coefficient (β). Our focus on the one-dimensional EC is primarily on a case of fixed β and relatively small A, which is characteristic of typical experimental conditions. We study the nonlinear behaviors of the one-dimensional EC through the analysis of bifurcations of fixed points in the Poincaré sections. We analyze these bifurcations by using Floquet theory to determine the stability of the limit cycles associated with the fixed points in the Poincaré sections. Some of the bifurcations lead to chaotic trajectories where we then determine the strength of chaos in phase space by calculating the largest Lyapunov exponent. In the study of the two-dimensional EC, we independently look at bifurcation diagrams of variations in A with fixed β and variations in β with fixed A. Under certain values of β and A, we find that no stable trajectories above the surface exists; such chaotic trajectories are described by a chaotic (strange) attractor, for which the largest Lyapunov exponent is found. We show the well-known stable oscillations between two electrodes come into existence for variations in A and the transitions between several distinct regimes of stable motion for variations in β.
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