All-optical input-agnostic polarization transformer via experimental Kraus-map control

Zhang, Wenlei; Saripalli, Ravi K.; Leamer, Jacob M.; Glasser, Ryan T.; Bondar, Denys I.

doi:10.48550/arxiv.2103.05398

Cited by 2 publications

(4 citation statements)

References 41 publications

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“…We also confirm this via simulations in Appendix A. This would suggest that the polarization of light could serve as a useful degree of freedom in FSO communications, particularly given that polarization transformers have been shown to be able to manipulate the state and degree of polarization (SOP and DOP, respectively) [21] in ways that may be suitable for FSO communications [22]. It has also been shown that polarization can be used to encode and transmit information securely [23], and that states with a DOP of 1 are preserved in the presence of turbulence [16,24].…”

Section: Introductionsupporting

confidence: 66%

“…The desired partially polarized states are generated by a Mach-Zehnder interferometer, where a polarizing beamsplitter generates beams of horizontal and vertical polarizations, which are then recombined on a 50:50 non-polarizing beamsplitter (BS), such that they are separated by a small distance and not coaxially superposing. This allows for control over the DOP by adjusting relative intensity of each arm of the interferometer [21,32]. This is done by attenuating one arm by tuning a variable neutral-density filter.…”

Section: Methodsmentioning

confidence: 99%

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Robust Free-Space Optical Communication Utilizing Polarization for the Advancement of Quantum Communication

Savino,

Leamer,

Saripalli

et al. 2024

Entropy

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Free-space optical (FSO) communication can be subject to various types of distortion and loss as the signal propagates through non-uniform media. In experiment and simulation, we demonstrate that the state of polarization and degree of polarization of light passed though underwater bubbles, causing turbulence, is preserved. Our experimental setup serves as an efficient, low cost alternative approach to long distance atmospheric or underwater testing. We compare our experimental results with those of simulations, in which we model underwater bubbles, and separately, atmospheric turbulence. Our findings suggest potential improvements in polarization based FSO communication schemes.

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Section: Introductionsupporting

confidence: 66%

Section: Methodsmentioning

confidence: 99%

Robust Free-Space Optical Communication Utilizing Polarization for the Advancement of Quantum Communication

Savino,

Leamer,

Saripalli

et al. 2024

Entropy

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“…As with all paradoxes in the technical sense of the word, a resolution awaits. The creation of such an input-agnostic polarization transformer from linear optical devices requires postselection to enable a lossless polarizer (Zhang et al, 2021); in actuality, some light is always lost by such a polarizer. Such a transformation with Kraus operators enacting Eq.…”

Section: Speculative Constraints On Polarization Changesmentioning

confidence: 99%

“…Quantum polarization has been used for quantum key distribution (Bennett et al, 1992;Muller et al, 1993), Einstein-Podolsky-Rosen tests (Kwiat et al, 1995), quantum teleportation (Bouwmeester et al, 1997), quantum tomography (James et al, 2001), weak value amplification (Hallaji et al, 2017), and more. However, the study of the changes in quantum polarization have not, to our knowledge, been the focus of any major review, which is a void that must especially be filled due to the proliferation of recent experiments on polarimetry with explicitly quantum mechanical states of light (Altepeter et al, 2011;Bogdanov et al, 2004;Daryanoosh et al, 2018;Graham et al, 2006;Mitchell et al, 2004;Oza et al, 2010;Rosskopf et al, 2020;Slussarenko et al, 2017;Sun et al, 2020;Toussaint et al, 2004;Yoon et al, 2020;Zhang et al, 2021). We set forth to present a complete picture of quantum polarimetry in this work.…”

Section: Introductionmentioning

confidence: 99%

Quantum Polarimetry

Goldberg

2021

Preprint

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Polarization is one of light's most versatile degrees of freedom for both classical and quantum applications. The ability to measure light's state of polarization and changes therein is thus essential; this is the science of polarimetry. It has become ever more apparent in recent years that the quantum nature of light's polarization properties is crucial, from explaining experiments with single or few photons to understanding the implications of quantum theory on classical polarization properties. We present a self-contained overview of quantum polarimetry, including discussions of classical and quantum polarization, their transformations, and measurements thereof. We use this platform to elucidate key concepts that are neglected when polarization and polarimetry are considered only from classical perspectives.

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All-optical input-agnostic polarization transformer via experimental Kraus-map control

Cited by 2 publications

References 41 publications

Robust Free-Space Optical Communication Utilizing Polarization for the Advancement of Quantum Communication

Robust Free-Space Optical Communication Utilizing Polarization for the Advancement of Quantum Communication

Quantum Polarimetry

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