High-Dimensional Entanglement-Enabled Holography

“…1 OAM beams form a helical wavefront described by the Laguerre-Gaussian mode, featuring a phase factor of exp(ilφ), where l represents a 2π phase shift of the vortex beam wavefront around the optical axis, which is called the topological charge (TC) of the vortex beam and can take any integer or fractional value and φ represents the azimuthal angle. Subsequent studies have demonstrated that OAM beams are not just a physical phenomenon, but also serve practical technological applications, playing pivotal roles in various fields including quantum entanglement, [2][3][4] optical communication, [5][6][7] optical microscopy, [8][9][10][11] and particle manipulation. 12,13 The topological charge of vortex beams theoretically offers infinite eigenstates, which are orthogonal to physical dimensions such as wavelength and polarization, presenting new degrees of freedom for information technology.…”

Nanostructure-based orbital angular momentum encryption and multiplexing

“…1 OAM beams form a helical wavefront described by the Laguerre-Gaussian mode, featuring a phase factor of exp(ilφ), where l represents a 2π phase shift of the vortex beam wavefront around the optical axis, which is called the topological charge (TC) of the vortex beam and can take any integer or fractional value and φ represents the azimuthal angle. Subsequent studies have demonstrated that OAM beams are not just a physical phenomenon, but also serve practical technological applications, playing pivotal roles in various fields including quantum entanglement, [2][3][4] optical communication, [5][6][7] optical microscopy, [8][9][10][11] and particle manipulation. 12,13 The topological charge of vortex beams theoretically offers infinite eigenstates, which are orthogonal to physical dimensions such as wavelength and polarization, presenting new degrees of freedom for information technology.…”

Nanostructure-based orbital angular momentum encryption and multiplexing

“…Due to that OAM can give access to an in principle unbounded state space, it can be used to encode information beyond one bit per photon in a higher-dimensional Hilbert space. This has led to a series of applications ranging from optical communications [26][27][28][29][30] to high-dimensional quantum entanglement [31][32][33][34][35][36][37]. However, in these fields, separating different OAM states is a fundamental requirement.…”

Compact and sturdy orbital angular momentum sorter without destroying photon states

“…LC-SLMs have enabled the development of extensive compact and lightweight optical components with electronic modulation capacity, and as a result, LC-SLMs have shown great potential in widespread applications, and have been crucial in quantum optics 26,27 , microscopy 28 , imaging 29,30 , optical trapping and tweezers 31,32 , materials processing 33 and holography 34 . For instance, LC-SLMs can be used as spatial filters, deflectors, beam splitters or optical interconnects.…”

A review of liquid crystal spatial light modulators: devices and applications