Preserving photon qubits in an unknown quantum state with Knill dynamical decoupling: Towards an all optical quantum memory

Gupta, Manish K.; Navarro, Erik J.; Moulder, Todd; Mueller, Jason D.; Balouchi, Ashkan; Brown, Katherine L.; Lee, Hwang; Dowling, Jonathan P.

doi:10.1103/physreva.91.032329

Cited by 8 publications

(5 citation statements)

References 32 publications

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“…A technique for minimizing the quantum noise is called dynamical decoupling. The application of dynamical decoupling in an optical fiber to reduce quantum noise was first proposed by Wu and Lidar in [22], and later investigated in [23][24][25][26][27] for the protection of photonic qubits traveling in an optical fiber. Although dynamical decoupling has been used to preserve the state of a qubit, it has never been applied for reduction of noise in an AC signal in an optical fiber.…”

Section: Optical Magnetometerymentioning

confidence: 99%

“…If a photonic qubit propagates for a length ∆L in an optical fiber then the phase accumulated by it is given by ∆φ = (2π/λ)∆L∆n, where ∆n is the birefringence of the fiber and λ is the wavelength. We model the axially varying index dephasing in an optical fiber of length L by a series of concatenated, homogeneous segments of length ∆L with constant ∆n [23,26,31]. The index fluctuations across these segments of fiber are random and the stochastic fluctuation of refractive index difference ∆n(x) across the segments are simulated as a Gaussian-distributed zero mean random process [31,32].…”

Section: Noise Modelmentioning

confidence: 99%

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High precision Optical AC Magnetometry using Dynamical Decoupling

Gupta,

Kunjummen,

Wang

et al. 2018

Preprint

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We propose a magnetometer for the precise measurement of AC magnetic fields that uses a Terbium-doped optical fiber with half-waveplates built into it at specified distances. Our scheme uses an open-loop quantum control technique called dynamical decoupling to reduce the noise floor and thus increase the sensitivity. We show that dynamical decoupling is extremely effective in preserving the photon state evolution due to the external AC magnetic field from random birefringence in the fiber, even when accounting for errors in pulse timing. Hence we achieve high sensitivity. For a given inter-waveplate distance, the minimum detectable field is inversely proportional to fiber length, as is the bandwidth of detectable frequencies.

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Section: Optical Magnetometerymentioning

confidence: 99%

Section: Noise Modelmentioning

confidence: 99%

High precision Optical AC Magnetometry using Dynamical Decoupling

Gupta,

Kunjummen,

Wang

et al. 2018

Preprint

Self Cite

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“…In general, the index of refraction fluctuation in an optical fiber can be represented by a series of concatenated, homogeneous segments of length ∆L with constant index fluctuation ∆β = ω(n l −n −l ) c [17,18]. When a photon that is in superposition of +l and −l propagates through the fiber in z direction the E-fields see a slightly different refractive index due to the corkscrew nature of the OAM photon.…”

mentioning

confidence: 99%

“…Since the mean of variance is zero in Eq. 10, and average of the variance is ∆ φ2 = ∆φ 2 , hence we obtain the expression [17,19] exp…”

mentioning

confidence: 99%

“…Decoherence of a photonic state has its origin in optical index fluctuation of a fiber that can result from both intrinsic and extrinsic perturbations. We model axially varying index dephasing in an optical fiber of length L by a series of concatenated, homogeneous segments of length ∆L with constant ∆n [17,18,20]. The index fluctuations across these segments is modeled by generating a set of values according to the Rayleigh distribution, whose probability density function is given as…”

mentioning

confidence: 99%

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Dephasing of Single-Photon Orbital Angular Momentum Qudit States in Fiber: Limits to Correction via Dynamical Decoupling

Gupta

Dowling

2016

Phys. Rev. Applied

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We analytically derive a decoherence model for orbital angular momentum states of a photon in a multimode optical fiber and show that rate of decoherence scales exponentially with l 2 , where l is the azimuthal mode order. We also show numerically that for large values of l the orbital angular momentum photon state completely dephases. However for lower values of l the decoherence can be minimized by using dynamical decoupling to allow for qudit high-bandwidth quantum communication and similar applications.

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Quantum Memory

Bashkansky¹,

Black²,

Kwolek³

et al. 2021

Wiley Encyclopedia of Electrical and Electronics Engineering

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Quantum Memory (QM) commonly refers to a system that reversibly transfers quantum states between a material storage system and a propagating electromagnetic field. It represents a key component in quantum information science and technology. Over the past 25 years, a wide range of theoretical protocols and experimental approaches to QM has been studied. These include optical delays, mechanical resonators, topological approaches, solid state spins, trapped single atoms and ions, and atomic ensembles. New applications of QM are being investigated and discovered all the time, including quantum computation, long‐distance entanglement distribution, quantum teleportation, and long‐distance quantum key distribution. Challenges to the implementation of QM include inefficiencies in storing and recovering the quantum state, and decoherence, which usually manifests by environment‐induced dephasing. In this monograph we describe, in general terms, methods and protocols that are used in many forms of QM. We also discuss the various experimental systems in which QM has been demonstrated or proposed. Additionally, we discuss the applications of QM that have been identified and progress made in implementing those applications.

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Preserving photon qubits in an unknown quantum state with Knill dynamical decoupling: Towards an all optical quantum memory

Cited by 8 publications

References 32 publications

High precision Optical AC Magnetometry using Dynamical Decoupling

High precision Optical AC Magnetometry using Dynamical Decoupling

Dephasing of Single-Photon Orbital Angular Momentum Qudit States in Fiber: Limits to Correction via Dynamical Decoupling

Quantum Memory

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