Optical vortices are associated with a spatial phase singularity. Such a beam with a vortex is valuable in optical microscopy, hyper-entanglement, and optical levitation. In these applications, vortex beams with a perfect circle shape and a large topological charge are highly desirable. But the generation of perfect vortices with high topological charges is challenging. We present a novel method to create perfect vortex beams with large topological charges using a digital micromirror device (DMD) through binary amplitude modulation and a narrow Gaussian approximation. The DMD with binary holograms encoding both the spatial amplitude and the phase could generate fast switchable, reconfigurable optical vortex beams with significantly high quality and fidelity. With either the binary Lee hologram or the superpixel binary encoding technique, we were able to generate the corresponding hologram with high fidelity and create a perfect vortex with topological charge as large as 90. The physical properties of the perfect vortex beam produced were characterized through measurements of propagation dynamics and the focusing fields. The measurements show good consistency with the theoretical simulation. The perfect vortex beam produced satisfies high-demand utilization in optical manipulation and control, momentum transfer, quantum computing, and biophotonics.
Ince-Gaussian (IG) beam with elliptical profile, as a connection between Hermite-Gaussian (HG) and Laguerre-Gaussian (LG) beams, has showed unique advantages in some applications such as quantum entanglement and optical micromanipulation. However, its dynamic generation with high switching frequency is still challenging. Here, we experimentally reported the quick generation of Ince-Gaussian beam by using a digital micro-mirror device (DMD), which has the highest switching frequency of 5.2 kHz in principle. The configurable properties of DMD allow us to observe the quasi-smooth variation from LG (with ellipticity ε=0) to IG and HG (ε=∞) beam. This approach might pave a path to high-speed quantum communication in terms of IG beam. Additionally, the characterized axial plane intensity distribution exhibits a 3D mould potentially being employed for optical micromanipulation.
Photons in an optical vortex usually carry orbital angular momentum, which boosts the application of the micro-rotation of absorbing particles and quantum information encoding. Such photons propagate along a straight line in free space or follow a curved trace once guided by an optical fiber. Teleportation of an optical vortex using a beam with non-diffraction and self-healing is quite challenging. We demonstrate the manipulation of the propagation trace of an optical vortex with a symmetric Airy beam (SAB) and found that the SAB experiences self-rotation with the implementation of a topological phase structure of coaxial vortex. Slight misalignment of the vortex and the SAB enables the guiding of the vortex into one of the self-accelerating channels. Multiple off-axis vortices embedded in SAB are also demonstrated to follow the trajectory of the major lobe for the SAB beam. The Poynting vector for the beams proves the direction of the energy flow corresponding to the intensity distribution. Hence, we anticipate that the proposed vortex symmetric Airy beam (VSAB) will provide new possibilities for optical manipulation and optical communication.
The irradiance in microscopic lithography using a digital micro-mirror device (DMD) as a virtual digital mask generator is influenced by diffraction effects that have been exploited to fabricate microstructures. Based on the established model, the theoretical analysis and simulation of DMD diffraction characteristics has been studied. A novel method without masking to fabricate a micro-lens by pixilation of micro-mirrors inside the DMDs used in microscopic lithography has been proposed. It is a method of precise control of photon-induced curing behavior of photoresist by full use of diffraction effects and verification of the feasibility of the fabrication method based on diffraction. The introduced method provides an option for accurate and flexible micro-fabrication of microstructures.
Hermite–Gaussian (HG) mode, as one of the fundamental transverse electromagnetic modes, has significant advantages in various applications including quantum entanglement, guidance of ultracold atoms and particle acceleration, some of which require complex manipulation (such as dynamic creation and arbitrary three-dimensional spatial transformation with challenges) over HG modes. We report the dynamic creation of a transversely rotated HG mode along its propagating axis with the help of a fast amplitude digital micromirror device (DMD) and a binary encoding technique. Furthermore, this mechanism can also realize the dynamic deformation from a traditional HG beam to a vortex HG beam, which provides a deep insight into the detailed formation of optical vortex singularity in a light beam and would benefit across singular optics and optical manipulation.
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