Algebraic approach to electro-optic modulation of light: exactly solvable multimode quantum model

Miroshnichenko, G. P.; Kiselev, Alexei D.; Trifanov, Alexander; Gleim, A.V.

doi:10.1364/josab.34.001177

Cited by 36 publications

(38 citation statements)

References 62 publications

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“…In this Rapid Communication, we build on the work above and use single photons from an isolated InGaAs quantum dot to show agreement with the quantum analysis [19] when an electro-optic phase modulator is used to produced frequency sidebands centered around the emission frequency of the dot. A HOM interferometer is used to demonstrate preservation of quantum coherence in the resulting quantum coherent superposition state.…”

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confidence: 77%

“…The work by Kolchin et al [20] lays an experimental foundation for the pulse shaping at a single-photon level and has motivated several works on the topic [21][22][23][24][25]. The timeliness for a demonstration is highlighted by the recent publication of papers that use a phase modulator as a quantum optics device that preserves quantum coherence [26][27][28][29][30].In this Rapid Communication, we build on the work above and use single photons from an isolated InGaAs quantum dot to show agreement with the quantum analysis [19] when an electro-optic phase modulator is used to produced frequency sidebands centered around the emission frequency of the dot. A HOM interferometer is used to demonstrate preservation of quantum coherence in the resulting quantum coherent superposition state.…”

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confidence: 85%

“…The state vector of a single photon becomes modified with additional frequency modes that were previously unoccupied. The new frequency components are separated by the harmonics of the microwave field with amplitudes determined by the microwave field modes coupling with the optical field [19]. For a monochromatic input field (|ψ in = |1 ω 0 ) of the single photon centered at ω 0 , at the limit that a large number of microwave modes are coupled with the optical field, the output state can be expanded as an infinite sum of the Bessel coefficients of the first kind [19,47],…”

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confidence: 99%

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Generation of frequency sidebands on single photons with indistinguishability from quantum dots

et al. 2018

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Generation and manipulation of the quantum state of a single photon is at the heart of many quantum information protocols. There has been growing interest in using phase modulators as quantum optics devices that preserve coherence. In this Rapid Communication, we have used an electro-optic phase modulator to shape the state vector of single photons emitted by a quantum dot to generate new frequency components (modes) and explicitly demonstrate that the phase modulation process agrees with the theoretical prediction at a single-photon level. Through two-photon interference measurements we show that for an output consisting of three modes (the original mode and two sidebands), the indistinguishability of the mode engineered photon, measured through the second-order intensity correlation [g 2 (0)] is preserved. This work demonstrates a robust means to generate a photonic qubit or more complex state (e.g., a qutrit) for quantum communication applications by encoding information in the sidebands without the loss of coherence. DOI: 10.1103/PhysRevA.98.011802 Quantum communication and computing protocols often require a flexible and customizable single-photon source that can form a link between distant nodes [1][2][3]. Swapping entanglement between these nodes can be achieved utilizing the two-photon interference [Hong-Ou-Mandel (HOM)] measurements [4][5][6], where the optimal interference to assure indistinguishability requires that the spatial, temporal, polarization, and spectral modes of the input photon wave functions must be identical [6,7]. Thus manipulation of the photonic degrees of freedom while maintaining coherence is very important for many quantum information applications.Single photons also function for cryptographic key distributions to enable transfer of information between two remote parties [2,8], where quantum information is encoded in the various degrees of freedom of a single photon. Polarization qubits are typical, but are prone to decoherence when transmitted through a fiber [9][10][11]. Frequency qubits [12], on the other hand, are known to be robust against any mechanically or environmentally induced fluctuation in a fiber [13][14][15]. Frequency qubits can be generated through phase modulation of a single photon [14,16], where the information is encoded in the relative amplitude between the sidebands. Recently, Lukens and Lougovski proposed a universal linearoptical quantum computing (LOQC) platform using frequency components generated from an electro-optic modulators [14]. Similarly, there has been proof-of-concept demonstrations of the 1984 protocol of Bennett and Brassard (BB84) using phase-modulated weak coherent sources [13,17]. A quantum analysis of phase modulation was first discussed by Louisell, Yariv, and Siegman [18]. Frequency conversion is described as a two-mode coupling process with sinusoidal coupling between the unmodulated and the new frequency component. The coupling between the two modes is generated through a periodic perturbation of the refractive index of the medium ...

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confidence: 77%

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confidence: 85%

Section: Fig 2 (A)mentioning

confidence: 99%

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Generation of frequency sidebands on single photons with indistinguishability from quantum dots

et al. 2018

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“…There are some difficulties with unitarity which appears form straightforward generalization of existing classical model of electro-optical phase modulation process [3]. In [4] we suggest an algebraic model of EOPM based of effective Hamiltonian approach describing multimode quantum parametric process including arbitrary, but finite number of interacting modes. From that we obtain transformation of each frequency mode operator ( ) following from temporal evolution of signal inside phase modulator [4]:…”

Section: Introductionmentioning

confidence: 99%

“…In [4] we suggest an algebraic model of EOPM based of effective Hamiltonian approach describing multimode quantum parametric process including arbitrary, but finite number of interacting modes. From that we obtain transformation of each frequency mode operator ( ) following from temporal evolution of signal inside phase modulator [4]:…”

Section: Introductionmentioning

confidence: 99%

Transformations properties of quantum optical signals in phase modulator

Trifanov

Trifanova

2019

EPJ Web Conf.

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We investigate evolution of multimode quantum light in electro-optical modulator, using semiclassical model of phase modulation process. For the case of monochromatic incoming signal, we consider transformation of its spectrum and calculate statistical properties of each frequency mode. Particularly, we find that for the case of initial coherent state our result is covered by the well-known classical model. While for the case of initially squeezed state we observe single-and multi-mode squeezing in frequency spectrum of modulated light.

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