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Free keywords:
OPTICAL PROPELLING BEAMS; AIRY BEAMS; GAUSSIAN BEAMS; ARBITRARY
TRAJECTORIES; ANGULAR-MOMENTUM; WAVE-PACKETS; GENERATION; PARTICLES;
LIGHT; MICROPARTICLESScience & Technology - Other Topics; Airy beams; Bessel beams; Vortex beams; Nondiffracting beams;
Self-accelerating; Self-healing;
Abstract:
Over the past several years, spatially shaped self-accelerating beams along different trajectories have been studied extensively. Due to their useful properties such as resistance to diffraction, self-healing, and self-bending even in free space, these beams have attracted great attention with many proposed applications. Interestingly, some of these beams could be designed with controllable spatial profiles and thus propagate along various desired trajectories such as parabolic, snake-like, hyperbolic, hyperbolic secant, three-dimensional spiraling, and even self-propelling trajectories. Experimentally, such beams are realized typically by using a spatial light modulator so as to imprint a desired phase distribution on a Gaussian-like input wave front propagating under paraxial or nonparaxial conditions. In this paper, we provide a brief overview of our recent work on specially shaped self-accelerating beams, including Bessel-like, breathing Bessel-like, and vortex Bessel-like beams. In addition, we propose and demonstrate a new type of dynamical Bessel-like beams that can exhibit not only self-accelerating but also self-propelling during propagation. Both theoretical and experimental results are presented along with a brief discussion of potential applications.
