Stochastic Hopf bifurcations in vacuum optical tweezers

0547258 - ÚPT 2022 RIV US eng J - Článek v odborném periodiku
Simpson, Stephen Hugh - Arita, Y. - Dholakia, K. - Zemánek, Pavel
Stochastic Hopf bifurcations in vacuum optical tweezers.
Physical Review A. Roč. 104, č. 4 (2021), č. článku 043518. ISSN 2469-9926. E-ISSN 2469-9934
Grant CEP: GA ČR(CZ) GA19-17765S; GA MŠMT EF15_003/0000476
Grant ostatní: AV ČR(CZ) AP2002
Program: Akademická prémie - Praemium Academiae
Institucionální podpora: RVO:68081731
Klíčová slova: optical trap * vacuum * bifurcations * limit cycles
Obor OECD: Optics (including laser optics and quantum optics)
Impakt faktor: 2.971, rok: 2021
Způsob publikování: Omezený přístup
https://journals.aps.org/pra/abstract/10.1103/PhysRevA.104.043518

The forces acting on an isotropic microsphere in optical tweezers are effectively conservative. However, reductions in the symmetry of the particle or trapping field can break this condition. Here we theoretically analyze the motion of a particle in a linearly nonconservative optical vacuum trap, concentrating on the case where symmetry is broken by optical birefringence, causing nonconservative coupling between rotational and translational degrees of freedom. Neglecting thermal fluctuations, we first show that the underlying deterministic motion can exhibit a Hopf bifurcation in which the trapping point destabilizes and limit cycles emerge whose amplitude grows with decreasing viscosity. When fluctuations are included, the bifurcation of the underlying deterministic system is expressed as a transition in the statistical description of the motion. For high viscosities, the probability distribution is normal, with a kurtosis of three, and persistent probability currents swirl around the stable trapping point. As the bifurcation is approached, the distribution and currents spread out in phase space. Following the bifurcation, the probability distribution function hollows out, reflecting the underlying limit cycle, and the kurtosis halves abruptly. The system is seen to be a noisy self-sustained oscillator featuring a highly uneven limit cycle. A variety of applications, from autonomous stochastic resonance to synchronization, is discussed.
Trvalý link: http://hdl.handle.net/11104/0323601