Electro-Optic Frequency Beam Splitters and Tritters for High-Fidelity Photonic Quantum Information Processing

Lu, Hsuan-Hao; Lukens, Joseph M.; Peters, Nicholas A.; Odele, Ogaga D.; Leaird, Daniel E.; Weiner, Andrew M.; Lougovski, Pavel

doi:10.1103/physrevlett.120.030502

Cited by 172 publications

(188 citation statements)

References 46 publications

Supporting

Mentioning

166

Contrasting

Unclassified

Order By: Relevance

“…The DFT gate here is a d ‐point discrete Fourier transform (DFT) defined as

D F T^{(d)} false| j false⟩ = \frac{1}{\sqrt{d}} \sum_{k = 0}^{d - 1} e^{2 π i (j k / d)} false| k false⟩

. The DFT gate can be understood as a qudit generalization of the Hadamard gate to dimensions beyond

d = 2

. When operating on a single qudit, both the Hadamard gates and the QFT in Figure a are reduced to a single DFT gate.…”

Section: Theorymentioning

confidence: 99%

Quantum Phase Estimation with Time‐Frequency Qudits in a Single Photon

Alshaykh

et al. 2019

Adv Quantum Tech

View full text Add to dashboard Cite

The Phase Estimation Algorithm (PEA) is an important quantum algorithm used independently or as a key subroutine in other quantum algorithms. Currently most implementations of the PEA are based on qubits, where the computational units in the quantum circuits are 2D states. Performing quantum computing tasks with higher dimensional states—qudits —has been proposed, yet a qudit‐based PEA has not been realized. Using qudits can reduce the resources needed for achieving a given precision or success probability. Compared to other quantum computing hardware, photonic systems have the advantage of being resilient to noise, but the probabilistic nature of photon–photon interaction makes it difficult to realize two‐photon controlled gates that are necessary components in many quantum algorithms. In this work, an experimental realization of a qudit‐based PEA on a photonic platform is reported, utilizing the high dimensionality in time and frequency degrees of freedom (DoFs) in a single photon. The controlled‐unitary gates can be realized in a deterministic fashion, as the control and target registers are now represented by two DoFs in a single photon. This first implementation of a qudit PEA, on any platform, successfully retrieves any arbitrary phase with one ternary digit of precision.

show abstract

“…The DFT gate here is a d ‐point discrete Fourier transform (DFT) defined as

D F T^{(d)} false| j false⟩ = \frac{1}{\sqrt{d}} \sum_{k = 0}^{d - 1} e^{2 π i (j k / d)} false| k false⟩

. The DFT gate can be understood as a qudit generalization of the Hadamard gate to dimensions beyond

d = 2

. When operating on a single qudit, both the Hadamard gates and the QFT in Figure a are reduced to a single DFT gate.…”

Section: Theorymentioning

confidence: 99%

Quantum Phase Estimation with Time‐Frequency Qudits in a Single Photon

Alshaykh

et al. 2019

Adv Quantum Tech

View full text Add to dashboard Cite

show abstract

“…In this article, we study a different implementation of a quantum memristor in a quantum photonics setup. Employing beam splitters for frequency-codified quantum states [15], we explore a new implementation in which the information is codified in frequency-entangled optical fields. We engineer the elements which constitute a quantum memristor, namely, a tunable dissipative element, a weak-measurement scheme, and classical feedback.…”

Section: Introductionmentioning

confidence: 99%

Quantum Memristors in Frequency-Entangled Optical Fields

et al. 2020

Self Cite

View full text Add to dashboard Cite

A quantum memristor is a resistive passive circuit element with memory engineered in a given quantum platform. It can be represented by a quantum system coupled to a dissipative environment, in which a system-bath coupling is mediated through a weak measurement scheme and classical feedback on the system. In quantum photonics, such a device can be designed from a beam splitter with tunable reflectivity, which is modified depending on the results of measurements in one of the outgoing beams. Here, we show that a similar implementation can be achieved with frequencyentangled optical fields and a frequency mixer that, working similarly to a beam splitter, produces state superpositions. We show that the characteristic hysteretic behavior of memristors can be reproduced when analyzing the response of the system with respect to the control, for different experimentally-attainable states. Since memory effects in memristors can be exploited for classical and neuromorphic computation, the results presented in this work provides the first steps of a novel route towards constructing quantum neural networks in quantum photonics.

show abstract

“…Previously, EOMs have been used in combina-tion with integrated sources to generate high-dimensional time-frequency entangled states [28][29][30]. Together with pulse shaping and bulk single-photon sources, EOMs have also been used to create frequency-bin entangled states and to demonstrate two-photon HOM-type interference with modes separated by up to 25 GHz [31][32][33][34][35][36][37]. Recently, frequency translation in a χ (2) crystal was used to demonstrate interference between a single photon and attenuated coherent laser light [38].…”

mentioning

confidence: 99%

Frequency-Domain Quantum Interference with Correlated Photons from an Integrated Microresonator

et al. 2020

View full text Add to dashboard Cite

Frequency encoding of quantum information together with fiber and integrated photonic technologies can significantly reduce the complexity and resource requirements for realizing all-photonic quantum networks. The key challenge for such frequency domain processing of single photons is to realize coherent and selective interactions between quantum optical fields of different frequencies over a range of bandwidths. Here, we report frequency-domain Hong-Ou-Mandel interference with spectrally distinct photons generated from a chip-based microresonator. We use four-wave mixing to implement an active 'frequency beam-splitter' and achieve interference visibilities of 0.95 ± 0.02. Our work establishes four-wave mixing as a tool for selective high-fidelity two-photon operations in the frequency domain which, combined with integrated single-photon sources, provides a building block for frequency-multiplexed photonic quantum networks.

show abstract

Electro-Optic Frequency Beam Splitters and Tritters for High-Fidelity Photonic Quantum Information Processing

Cited by 172 publications

References 46 publications

Quantum Phase Estimation with Time‐Frequency Qudits in a Single Photon

Quantum Phase Estimation with Time‐Frequency Qudits in a Single Photon

Quantum Memristors in Frequency-Entangled Optical Fields

Frequency-Domain Quantum Interference with Correlated Photons from an Integrated Microresonator

Contact Info

Product

Resources

About