Laguerre-Gaussian mode sorter

Fontaine, Nicolas K.; Ryf, Roland; Chen, Haoshuo; Neilson, David T.; Kim, Kwangwoong; Carpenter, Joel

doi:10.1038/s41467-019-09840-4

Cited by 369 publications

(212 citation statements)

References 65 publications

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“…In fact, if O(N 2 ) degrees of control are available, one can expect generating arbitrary N × N transformations between the input and output modes. Over the past two decades there is an ever-growing interest in realizing reconfigurable multimode transformations, for a wide range of applications, such as quantum photonic circuits [22,[31][32][33][34] optical communications [18,35], and nanophotonic processors [20,36]. These realizations require strong mixing of the input modes, as the output modes are arbitrary superpositions of the input modes.…”

Section: Discussionmentioning

confidence: 99%

Wavefront shaping in multimode fibers by transmission matrix engineering

et al. 2020

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One of the greatest challenges in utilizing multimode optical fibers is mode-mixing and inter-modal interference, which scramble the information delivered by the fiber. A common approach for canceling these effects is to tailor the optical field at the input of the fiber to obtain a desired field at its output. In this work, we present a new approach which relies on modulating the transmission matrix of the fiber rather than the incident light. We apply computer-controlled mechanical perturbations to the fiber to obtain a desired intensity pattern at its output. Using an all-fiber apparatus, we demonstrate focusing light at the distal end of the fiber and conversion between fiber modes. Since in this approach the number of degrees of control can be larger than the number of fiber modes, it allows simultaneous control over multiple inputs and multiple wavelengths.

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Section: Discussionmentioning

confidence: 99%

Wavefront shaping in multimode fibers by transmission matrix engineering

et al. 2020

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“…quantum bound, but it is important to note that they scaled the quantum bound with respect to the diffracted photon number, not the photon number before the hologram, meaning that the result did not take into account the low diffraction efficiency of their hologram. Efficient SPADE is possible with multiple holograms however [89,99,100].…”

Section: Hologramsmentioning

confidence: 99%

Resolving starlight: a quantum perspective

Tsang

2019

Contemporary Physics

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The wave-particle duality of light introduces two fundamental problems to imaging, namely, the diffraction limit and the photon shot noise. Quantum information theory can tackle them both in one holistic formalism: model the light as a quantum object, consider any quantum measurement, and pick the one that gives the best statistics. While Helstrom pioneered the theory half a century ago and first applied it to incoherent imaging, it was not until recently that the approach offered a genuine surprise on the age-old topic by predicting a new class of superior imaging methods. For the resolution of two sub-Rayleigh sources, the new methods have been shown theoretically and experimentally to outperform direct imaging and approach the true quantum limits. Recent efforts to generalize the theory for an arbitrary number of sources suggest that, despite the existence of harsh quantum limits, the quantum-inspired methods can still offer significant improvements over direct imaging for subdiffraction objects, potentially benefiting many applications in astronomy as well as fluorescence microscopy.

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“…A schematic showing the essential components of the type of experimental setup we envisage is shown in Fig. 1: with respect to the theory developed here, the key features are provided by the OAM sorters that determine the OAM of the incident beam and enable measurements of the distribution of the scattered field power over different OAM values [5][6][7][8][9][10]. This problem has several very dif- where an incident beam propagating along the directionk0 interacts with a distribution of particles within a cylindrical volume defined by the dimensions L ⊥ and L .…”

Section: Numerical Resultsmentioning

confidence: 99%

“…While scattering is considered to be detrimental for applications in information transfer, the ability to measure the power of the OAM states of the scattered light [5][6][7][8][9][10] may provide a source of information about the properties of the scattering medium, from the size and type of the particulates to their geometrical distribution, that has not yet been exploited. This may be of particular benefit for environmental sensing and metrology, and ocean transmissometry, and may even find applications in biological imaging.…”

Section: Introductionmentioning

confidence: 99%

Scattering of light with angular momentum from an array of particles

McArthur

Yao

Papoff

2020

Phys. Rev. Research

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Understanding the scattering properties of various media is of critical importance in many applications, from secure, high-bandwidth communications to extracting information about biological and mineral particles dissolved in sea water. In this paper we demonstrate how beams carrying orbital angular momentum (OAM) can be used to detect the presence of symmetric or chiral subsets of particles in disordered media. Using a generalized Mie theory we calculate analytical expressions for quasi-monochromatic structured light scattered by dilute distributions of micro-and nanoparticles. These allow us to determine the angular momentum of the scattered field as a function of the angular momentum of the incident beam and of the spatial distributions of scattering particles. Our numerical results show that we can distinguish structured from random distributions of particles, even when the number density of ordered particles is a few percent of the total distribution. We also find that the signal-to-noise ratio, in the forward direction, is equivalent for all orders of the Laguerre-Gaussian modes in relatively dense (but still dilute) distributions, making them an ideal basis to encode and transmit multiplexed signals.PACS numbers:

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Laguerre-Gaussian mode sorter

Cited by 369 publications

References 65 publications

Wavefront shaping in multimode fibers by transmission matrix engineering

Wavefront shaping in multimode fibers by transmission matrix engineering

Resolving starlight: a quantum perspective

Scattering of light with angular momentum from an array of particles

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