Generation and Characterization of Multimode Quantum Frequency Combs

Pinel, Olivier; Jian, Pu; Araújo, R. Medeiros de; Feng, Jing; Chalopin, Benoît; Fabre, Claude; Treps, Nicolas

doi:10.1103/physrevlett.108.083601

Cited by 125 publications

(108 citation statements)

References 27 publications

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“…Below threshold, they produce multimode squeezed states, which has been observed experimentally [42,45]. When operated above threshold, such multimode devices have been recently proved to be capable of producing non-critically squeezed states of light via the phenomena of spontaneous symmetry breaking [32,33,35,41,46] and pump clamping [37,42].…”

Section: Introductionmentioning

confidence: 89%

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Quantum coherent control of highly multipartite continuous-variable entangled states by tailoring parametric interactions

et al. 2012

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The generation of continuous-variable multipartite entangled states is important for several protocols of quantum information processing and communication, such as one-way quantum computation or controlled dense coding. In this article we theoretically show that multimode optical parametric oscillators can produce a great variety of such states by an appropriate control of the parametric interaction, what we accomplish by tailoring either the spatio-temporal shape of the pump, or the geometry of the nonlinear medium. Specific examples involving currently available optical parametric oscillators are given, hence showing that our ideas are within reach of present technology.PACS numbers: 42.50.Dv-Quantum state engineering and measurement, 42.65.Yj-Optical parametric oscillators and amplifiers, 42.65.Re-Ultrafast processes, optical pulse generation and pulse compression.

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Section: Introductionmentioning

confidence: 89%

“…Hence (43) can be seen as the diagonal form of (45). For each choice of the coupling matrix K, which can be chosen as symmetric without loss of generality, this Hamiltonian generates a different type of multipartite entanglement between theB modes.…”

Section: Application To the Generation Of Arbitrary Cluster Statesmentioning

confidence: 99%

Quantum coherent control of highly multipartite continuous-variable entangled states by tailoring parametric interactions

et al. 2012

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“…We note, however, that in the one-way quantum computing the complexity is shifted from the state control and manipulation to its generation: the different algorithms are realized simply through different measurements. In particular, recent developments in bulk optics [55][56][57][58][59][60], indicate that quantum frequency combs may represent a viable solution for one-way quantum computing. In light of this, our recent results on the generation of wavelength multiplexed photon pairs in microring resonators demonstrate that this is a venue that should be investigated in integrated platforms.…”

Section: Cross-polarized Photon Pair Generationmentioning

confidence: 99%

Multifrequency sources of quantum correlated photon pairs on-chip: a path toward integrated Quantum Frequency Combs

et al. 2016

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Recent developments in quantum photonics have initiated the process of bringing photonic-quantumbased systems out-of-the-lab and into real-world applications. As an example, devices to enable the exchange of a cryptographic key secured by the laws of quantum mechanics are already commercially available. In order to further boost this process, the next step is to transfer the results achieved by means of bulky and expensive setups into miniaturized and affordable devices. Integrated quantum photonics is exactly addressing this issue. In this paper, we briefly review the most recent advancements in the generation of quantum states of light on-chip. In particular, we focus on optical microcavities, as they can offer a solution to the problem of low efficiency that is characteristic of the materials typically used in integrated platforms. In addition, we show that specifically designed microcavities can also offer further advantages, such as compatibility with telecom standards (for exploiting existing fibre networks) and quantum memories (necessary to extend the communication distance), as well as giving a longitudinal multimode character for larger information transfer and processing. This last property (i.e., the increased dimensionality of the photon quantum state) is achieved through the ability to generate multiple photon pairs on a frequency comb, corresponding to the microcavity resonances. Further achievements include the possibility of fully exploiting the polarization degree of freedom, even for integrated devices. These results pave the way for the generation of integrated quantum frequency combs that, in turn, may find important applications toward the realization of a compact quantum-computing platform.

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“…The duration of a single pulse in each train is T 0 , and the period between pulses is T . According to the experiment [26], the relation T 0 << L/c << T is met, so that at any given time not more than one pulse propagates through the medium. During the readout, the driving runs in the opposite direction, since we consider the case of a backward readout that is much more efficient than a forward one [27][28][29][30].…”

Section: A Modelmentioning

confidence: 99%

Noiseless signal shaping and cluster-state generation with a quantum memory cell

et al. 2017

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In this article, we employ multimode radiation of a synchronously pumped optical parametric oscillator (SPOPO) to build a cluster state through a conversion on the base of quantum memory cell. We demonstrate that by choosing an appropriate driving field we can ensure the effective writing of the only one supermode from the entire set of the SPOPO squeezed supermodes. Further, by changing the driving field profile at the readout, we convert the time profile of the retrieved signal while maintaining its quantum state. We demonstrate the possibilities of using the presented scheme by the example of creating a four-mode linear cluster state of light.

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Generation and Characterization of Multimode Quantum Frequency Combs

Cited by 125 publications

References 27 publications

Quantum coherent control of highly multipartite continuous-variable entangled states by tailoring parametric interactions

Quantum coherent control of highly multipartite continuous-variable entangled states by tailoring parametric interactions

Multifrequency sources of quantum correlated photon pairs on-chip: a path toward integrated Quantum Frequency Combs

Noiseless signal shaping and cluster-state generation with a quantum memory cell

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