Self-propulsion of a grain-filled dimer in a vertically vibrated channel

Abstract: Steady dissipation of energy is a crucial property that distinguishes active particles from Brownian particles. However, it is not straightforward to explicitly model the dissipative property of existing active particles driven by a vibrating plate. We present a novel active particle that can be explicitly modeled by Newtonian dynamics of a conservative force field plus two asymmetrical dissipative terms. The particle is a dimer consisting of two ping-pong balls connected by a rigid rod, and its two balls are … Show more

“…Due to symmetry breaking, the granular dumbbell converts the energy from the vertical vibration of the shaker into a horizontal self-propulsion along its long axis, whose self-driving mechanism is similar to those of previously designed active granular particles. 34,35 Fig. 1(c) plots representative trajectories of the active dumbbell, showing the directed motion accompanied by stochastic turns due to rotational noise (mean square displacement of the active granular dumbbell is provided in the ESI †).…”

Spontaneous population oscillation of confined active granular particles

“…Due to symmetry breaking, the granular dumbbell converts the energy from the vertical vibration of the shaker into a horizontal self-propulsion along its long axis, whose self-driving mechanism is similar to those of previously designed active granular particles. 34,35 Fig. 1(c) plots representative trajectories of the active dumbbell, showing the directed motion accompanied by stochastic turns due to rotational noise (mean square displacement of the active granular dumbbell is provided in the ESI †).…”

Spontaneous population oscillation of confined active granular particles

Insight Into the Drift Motion of a Bouncing Asymmetric Dimer

Macroscopic, artificial active matter