부산대학교 도서관

The wave nature of light leads to interference and diffraction. A well known example of the wave nature is Thomas Young's double slit experiment, where light propagates through slits in an opaque screen to form a diffraction pattern at the detector. Here we extend this concept from opaque screens to spatially polarized wave fronts. The spatial variation of polarization gives rise to diffraction, opening the possibility to manipulate the beam shape and propagation direction via polarization control. We describe and simulate the propagation of a spatially inhomogeneous polarized wavefront and then experimentally demonstrate polarization control with a Bessel beam. Lensing in a beam without the need to change the phase-front of a beam is shown. We further explore how non-uniformly polarized beams may be used in combination with phase modulation for a high speed point scanning technique. This is in contrast to traditional methods of beam manipulation that make use of phase or amplitude modulation alone. Our work shows that diffraction due to polarization opens new possibilities for flexible and high speed beam control.