Add to ORKGPolarization vectors of light traveling in a coiled optical fiber rotate around its propagating axis even in the absence of birefringence. This rotation was usually explained due to the Pancharatnam-Berry phase of spin-1 photons. Here, we use a purely geometric method to understand this rotation. We show that similar geometric rotations also exist for twisted light carrying orbital angular momentum (OAM). The corresponding geometric phase can be applied in photonic OAM-state-based quantum computation and quantum sensing.Comment: 6 pages and 4 figure
Spiral twisting offers additional opportunities for controlling the loss, dispersion, and polarizati...
Spiral twisting offers additional opportunities for controlling the loss, dispersion, and polarizati...
Light carries both orbital angular momentum (OAM) and spin angular momentum (SAM), related to wavefr...
Graduation date: 1989The polarization state of light in a single mode optical fiber may\ud be change...
The goal of this project is to first present a detailed explanation and analysis of light with Orbit...
Beams of light can carry spin and orbital angular momentum. Spin angular momentum describes how the ...
In this introductory article, we explain the concept of orbital angular momentum (OAM) of light, dis...
The orbital angular momentum of light represents a fundamentally new optical degree of freedom. Unli...
The nature of intrinsic/extrinsic character of angular momentum is defined in terms of the kind of t...
In this Letter we show that, in spectral regions where there are no orbital cladding resonances to c...
The propagation of light guided in optical fibers is affected in different ways by bending or twisti...
That light travels in straight lines is a statement of the obvious. However, the energy and momentu...
We provide a theoretical investigation of optical Poincar\'e beams that exhibit interwinding chiral ...
Optical activity is conventionally understood as a natural difference in the optical responses of ch...
Geometric phases are ubiquitous in physics; they act as memories of the transformation of a physical...
Spiral twisting offers additional opportunities for controlling the loss, dispersion, and polarizati...
Spiral twisting offers additional opportunities for controlling the loss, dispersion, and polarizati...
Light carries both orbital angular momentum (OAM) and spin angular momentum (SAM), related to wavefr...
Graduation date: 1989The polarization state of light in a single mode optical fiber may\ud be change...
The goal of this project is to first present a detailed explanation and analysis of light with Orbit...
Beams of light can carry spin and orbital angular momentum. Spin angular momentum describes how the ...
In this introductory article, we explain the concept of orbital angular momentum (OAM) of light, dis...
The orbital angular momentum of light represents a fundamentally new optical degree of freedom. Unli...
The nature of intrinsic/extrinsic character of angular momentum is defined in terms of the kind of t...
In this Letter we show that, in spectral regions where there are no orbital cladding resonances to c...
The propagation of light guided in optical fibers is affected in different ways by bending or twisti...
That light travels in straight lines is a statement of the obvious. However, the energy and momentu...
We provide a theoretical investigation of optical Poincar\'e beams that exhibit interwinding chiral ...
Optical activity is conventionally understood as a natural difference in the optical responses of ch...
Geometric phases are ubiquitous in physics; they act as memories of the transformation of a physical...
Spiral twisting offers additional opportunities for controlling the loss, dispersion, and polarizati...
Spiral twisting offers additional opportunities for controlling the loss, dispersion, and polarizati...
Light carries both orbital angular momentum (OAM) and spin angular momentum (SAM), related to wavefr...