Formation of higher-order Bessel light beams in biaxial crystals

“…These two parts of the beam can, thus, be distinguished by the use of an appropriate circular analyzer [10,16]. Fig.…”

Free-space evolution of focused Gaussian beams transformed by conical diffraction in a biaxial crystal

“…These two parts of the beam can, thus, be distinguished by the use of an appropriate circular analyzer [10,16]. Fig.…”

Free-space evolution of focused Gaussian beams transformed by conical diffraction in a biaxial crystal

“…The major advantage of self-healing beams is that they can be used through turbulent media [152] and that they are ideal candidates for particle manipulation at different planes [156,157] and in microscopy [158]. The CR phenomenon has been also reported as an efficient tool to generate Bessel beams [62,159,160]. The relation of CR with Bessel beams suggests that even if the input Gaussian beam is partially blocked, the CR beam may only be slightly affected.…”

Conical refraction: fundamentals and applications

“…The simplest case that we can analyze happens when two Bessel beams of n = 0 and n = 1 are superposed, and their axial axis are coincident. Such simplicity is not only algebraic, but includes the experimental realization, because zero-order Bessel beams can be easily generated by annular apertures, optical elements as axicons or holography, while high-order Bessel beams are achieved with crystals that present some anisotropy, as biaxial crystals, for example [20]. Fig.…”

Manipulating gradient forces on optical tweezers using bessel beams