Abstract
Forces and torques exerted on dielectric disks trapped in a Gaussian standing wave are analyzed theoretically for disks of radius $2~\mu\text{m}$ with index of refraction $n=1.45$ and $n=2.0$ as well as disks of radius 200 nm with $n=1.45$. Calculations of the forces and torques were conducted both analytically and numerically using a discrete-dipole approximation method. Besides harmonic terms, third order ro-translational coupling terms in the potential energy can be significant and a necessary consideration when describing the dynamics of disks outside of the Rayleigh limit. The coupling terms are a result of the finite extension of the disk coupling to both the Gaussian and standing wave geometry of the beam. The resulting dynamics of the degrees of freedom most affected by the coupling terms exhibit several sidebands as evidenced in the power spectral densities. Simulations show that for Gaussian beam waists of $1-4~\mu\text{m}$ the disk remains stably trapped.
Highlights
The choice of particle used in levitated optomechanics is an important factor that depends on the goal of application
Particles with decreased particle symmetry allow rotational degrees of freedom to enter into the potential energy
The forces and torques exerted on dielectric disks trapped in a Gaussian standing wave were analyzed for disks of radius 2 μm with index of refraction n = 1.45 and n = 2.0 as well as disks of radius 200 nm with n = 1.45
Summary
The choice of particle used in levitated optomechanics is an important factor that depends on the goal of application. The dynamics of spheres trapped in cavities and focused laser beams are well understood and used for cooling to the motional ground state as well as force sensing [1,2,3,4]. It is shown that higher order terms of at least third order in the potential energy are necessary for describing the dynamics of disks outside the Rayleigh regime in a Gaussian standing wave. It may be used as a means for indirectly detecting the motion of several degrees of freedom with a single detection scheme and an efficient force and/or torque detector Another common application is cooling the motion of the disk in attempt to study macroscopic quantum mechanics [20,21,22]. IV examines the resulting dynamics due to the harmonic and coupling terms described in the previous sections
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