Sorting Photons by Radial Quantum Number

Zhou, Yiyu; Mirhosseini, Mohammad; Fu, Dongzhi; Zhao, Jiapeng; Rafsanjani, Seyed Mohammad Hashemi; Willner, Alan E.; Boyd, Robert W.

doi:10.1103/physrevlett.119.263602

Cited by 110 publications

(96 citation statements)

References 39 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…However, the radial index p has to be included in the mode summation, for generality and completeness of the modal decomposition [14]. Indeed, there has been a recent surge in interest in the radial term, and it has been sought to substantiate the role p can play in informatics [15][16][17]. Of course, l and p both feature in the detailed form of the LaguerreGaussian radial distribution:…”

mentioning

confidence: 99%

Quantum features in the orthogonality of optical modes for structured and plane-wave light

Andrews

Forbes

2018

Opt. Lett.

View full text Add to dashboard Cite

A fundamental photon creation-annihilation commutation relation underpins the familiar quantum formulation of optics. However, an internal inconsistency becomes apparent in the pursuit of structured light applications. This requires the relationship between operator commutation and mode orthogonality to be recast in a form ensuring full consistency with the precepts of quantum theory. A suitable reformulation, shown to register correctly an intrinsic quantum uncertainty in the associated interactions, has special relevance to optical vortex physics-particularly with regard to information content-through its connection to the degrees of freedom in the associated radiation modes. In the field of quantum optics, much of the basic theory is conventionally cast in terms that are primarily designed to apply to a single mode of radiation-a single wavelength, direction, and polarization. In the most obvious extension of these principles-allowing for more numerous modes of radiationthere are usually significant intervals between the accommodated frequencies, as, e.g., in the case of frequency combs [1], or else there are substantial differences in the directions of propagation. At the heart of most of the quantum formalism, there is a simple and widely familiar boson commutation relation between photon creation and annihilation operators [2]. One physical interpretation is that a photon propagating in a given radiation mode in vacuum cannot spontaneously divert into another mode.In the sphere of optics, the creation-annihilation commutation relation is often presented in a mathematically concise form, neglecting polarization features that ought also, for generality, to be accommodated. Although these features are not commonly given attention, they supplement the wave vector information in uniquely defining each radiation mode. The commutation relation is specifically cast in terms of a binary basis, for although polarization measurements can be made at a spatially localized location with high fidelity, it is well understood that two linear polarization states whose electric vectors differ by only a few degrees cannot be regarded as orthogonal. However, for the directions of propagation associated with the wave vector, the assumption of an orthonormal basis is not so straightforward. Moreover the wave vector of light does not commonly engage with detection apparatusunless weak quadrupole attributes are engaged, which is rarely the case.The difficulties of assuming an infinitely sharp distinction between modes of similar wave vectors are thrown into sharp relief in the case of structured radiation [3], in which there can be local variation of wave vector direction within the confines of a single well-defined beam. An optical vortex, or "twisted light," constitutes a prime example, where the wave vector represents the normal to a wavefront of helicoidal form. Significantly, it has been shown that the twisted character extends down to the level of individual photons [4,5], such that any given photon in a structured beam may ...

show abstract

mentioning

confidence: 99%

Quantum features in the orthogonality of optical modes for structured and plane-wave light

Andrews

Forbes

2018

Opt. Lett.

View full text Add to dashboard Cite

show abstract

“…Remarkably, we discover that if both voltage and light are applied, the system can be in a spin-valley polarized QAH (SVP-QAH) insulator state, for which the subsystem of one spin is in a QVH state and that of the other spin is in a QAH state. To our knowledge, this state has not been previously described in the literature and it is distinct from the single-valley spin-polarized QAH states [26,29] and the QAH states with no spin or valley polarizations [13-17, 21-23, 28].…”

mentioning

confidence: 97%

“…The QAH state in BLG has been suggested to be induced by Rashba interaction and internal magnetization [24] or by strong circularly polarized light [25][26][27], differently from the mechanism of Landau-level quantization in quantum Hall effect. Most recently, the valley-polarized QAH state possessing the properties of both the QVH and QAH states has been proposed in other 2D systems [28,29] similar to BLG. Interestingly, this QAH state can possess edge states which are not complectly chiral [28].…”

mentioning

confidence: 99%

See 1 more Smart Citation

Spin-valley polarized quantum anomalous Hall effect and a valley-controlled half-metal in bilayer graphene

Zhai

Blanter

2020

Phys. Rev. B

View full text Add to dashboard Cite

We investigate topological phases of bilayer graphene subject to antiferromagnetic exchange field, interlayer bias, and irradiated by light. We discover that at finite bias and light intensity the system transitions into a previously unknown spin-valley polarized quantum anomalous Hall (SVP-QAH) insulator state, for which the subsystem of one spin is a valley Hall topological insulator (TI) and that of the other spin is a QAH insulator. We assess the TI phases occurring in the system by analytically calculating the spin-valley dependent Chern number, and characterize them by considering edge states in a nanoribbon. We demonstrate that the SVP-QAH edge states lead to a unique spin rectification effect in a domain wall. Along the phase boundary, we observe a bulk half-metal state with Berry's phase of 2π.

show abstract

“…[41]. This entanglement can be harnessed using the vast array of classical techniques for controlling structured light [42], including recent results for mode sorting without postselection [43][44][45]. The notion of quantummechanical transformations at apertures has been probed in Ref.…”

mentioning

confidence: 99%

Entanglement generation via diffraction

Goldberg

James

2019

Phys. Rev. A

View full text Add to dashboard Cite

Quantum entanglement is an important resource for next-generation technologies. We show that diffracting systems can supplant beam splitters, and more generally interferometric networks, for entanglement generation -systems as simple as screens with pinholes can create entanglement. We then discuss the necessary and sufficient conditions for entanglement to be generated by states input to any passive linear interferometric network. Entanglement generated in free space can now be harnessed in quantum-optical applications ranging from quantum computation and communication to quantum metrology.

show abstract

Sorting Photons by Radial Quantum Number

Cited by 110 publications

References 39 publications

Quantum features in the orthogonality of optical modes for structured and plane-wave light

Quantum features in the orthogonality of optical modes for structured and plane-wave light

Spin-valley polarized quantum anomalous Hall effect and a valley-controlled half-metal in bilayer graphene

Entanglement generation via diffraction

Contact Info

Product

Resources

About