Experimental validation of photonic boson sampling

Spagnolo, Nicolò; Vitelli, Chiara; Bentivegna, Marco; Brod, Daniel J.; Crespi, Andrea; Flamini, Fulvio; Giacomini, Sandro; Milani, Giorgio; Ramponi, Roberta; Mataloni, Paolo; Osellame, Roberto; Galvão, Ernesto F.; Sciarrino, Fabio

doi:10.1038/nphoton.2014.135

Cited by 311 publications

(363 citation statements)

References 21 publications

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“…Unitary transformations on optical modes have been used to implement single-particle quantum gates [1,2], quantum simulations [3], and boson sampling [4][5][6][7][8][9][10][11]. Traditionally, these transformations are implemented on spatial modes using a system of beam splitters.…”

Section: Introductionmentioning

confidence: 99%

“…In conventional boson sampling schemes that use spatial modes [which we refer to as spatial mode boson sampling (SMBS)], multiple identical photons enter a high-dimensional transformation over spatial modes, such as a system of beam splitters and phase shifters, while the output probability distribution is monitored with detectors at each of the output modes [5][6][7][8][9][10][11], as shown in Fig. 1.…”

Section: Introductionmentioning

confidence: 99%

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High-dimensional unitary transformations and boson sampling on temporal modes using dispersive optics

Pant

Englund

2016

Phys. Rev. A

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A major challenge for postclassical boson sampling experiments is the need for a large number of coupled optical modes, detectors, and single-photon sources. Here we show that these requirements can be greatly eased by time-bin encoding and dispersive optics-based unitary transformations. Detecting consecutively heralded photons after time-independent dispersion performs boson sampling from unitaries for which an efficient classical algorithm is lacking. We also show that time-dependent dispersion can implement general single-particle unitary operations. More generally, this scheme promises an efficient architecture for a range of other linear optics experiments.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

High-dimensional unitary transformations and boson sampling on temporal modes using dispersive optics

Pant

Englund

2016

Phys. Rev. A

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“…Since then, several proposals have developed the idea of a linear optical quantum computer (LOQC), including Nielsen's proposal [2] of combining linear optics with cluster states, Browne and Rudolph's fusion mechanisms [5] to efficiently create optical cluster states and Kieling's et al proposal [4] of building an imperfect cluster that can be renormalized using ideas of percolation theory. While alternative schemes for LOQC [5] using parity state encoding [6] or small amplitude coherent states [7] have been proposed, we do not address these approaches in this manuscript.Recent demonstrations [8][9][10][11][12] have made significant progress towards experimental linear-optical quantum computing. In particular, the use of integrated photonics to implement large-scale, complex interferometers on a chip shows great promise.…”

mentioning

confidence: 99%

“…Recent demonstrations [8][9][10][11][12] have made significant progress towards experimental linear-optical quantum computing. In particular, the use of integrated photonics to implement large-scale, complex interferometers on a chip shows great promise.…”

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confidence: 99%

From Three-Photon Greenberger-Horne-Zeilinger States to Ballistic Universal Quantum Computation

et al. 2015

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Single photons, manipulated using integrated linear optics, constitute a promising platform for universal quantum computation. A series of increasingly efficient proposals have shown linear-optical quantum computing to be formally scalable. However, existing schemes typically require extensive adaptive switching, which is experimentally challenging and noisy, thousands of photon sources per renormalized qubit, and/or large quantum memories for repeat-until-success strategies. Our work overcomes all these problems. We present a scheme to construct a cluster state universal for quantum computation, which uses no adaptive switching, no large memories, and which is at least an order of magnitude more resource-efficient than previous passive schemes. Unlike previous proposals, it is constructed entirely from loss-detecting gates and offers a robustness to photon loss. Even without the use of an active loss-tolerant encoding, our scheme naturally tolerates a total loss rate ∼ 1.6% in the photons detected in the gates. This scheme uses only 3-GHZ states as a resource, together with a passive linear-optical network. We fully describe and model the iterative process of cluster generation, including photon loss and gate failure. This demonstrates that building a linear optical quantum computer need be less challenging than previously thought.In 2001, Knill, Laflamme and Milburn [1] showed that scalable quantum computation was possible using only linear optical elements -without the need for deterministic two-photon interactions. However, their proposal was more a proof of principle than a feasible construction as the scheme required tens of thousands of optical elements to acquire gates with a high probability of success. Since then, several proposals have developed the idea of a linear optical quantum computer (LOQC), including Nielsen's proposal [2] of combining linear optics with cluster states, Browne and Rudolph's fusion mechanisms [5] to efficiently create optical cluster states and Kieling's et al proposal [4] of building an imperfect cluster that can be renormalized using ideas of percolation theory. While alternative schemes for LOQC [5] using parity state encoding [6] or small amplitude coherent states [7] have been proposed, we do not address these approaches in this manuscript.Recent demonstrations [8][9][10][11][12] have made significant progress towards experimental linear-optical quantum computing. In particular, the use of integrated photonics to implement large-scale, complex interferometers on a chip shows great promise. However, active feed-forward remains challenging, it requires fast switching which is a dominant source of photon loss and has not yet been experimentally demonstrated in an integrated device.Of previous approaches to linear optical quantum computing, only Kieling et al's proposal [4] is ballistic -meaning that active switching is not required for the process of cluster state generation. It is thus the most suitable previous approach to LOQC in an integrated setting. It has a number o...

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“…The associated efficiency is found to greatly surpass spectral filtering effects. Our findings open the path towards on-chip scalable indistinguishable-photon emitting devices operating at room temperature.Indistinguishable single photons are the building blocks of various optically-based quantum information applications such as linear optical quantum computing [1, 2], boson sampling [3][4][5][6][7], quantum teleportation [8] or quantum networks [9]. Indistinguishable photons are usually generated either using parametric down conversion [10], or alternatively directly from a single two-level quantum emitter such as atoms, color centers, quantum dots or organic molecules [11][12][13][14][15][16][17][18][19][20].…”

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confidence: 99%

Cavity-Funneled Generation of Indistinguishable Single Photons from Strongly Dissipative Quantum Emitters

et al. 2015

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We investigate theoretically the generation of indistinguishable single photons from a strongly dissipative quantum system placed inside an optical cavity. The degree of indistinguishability of photons emitted by the cavity is calculated as a function of the emitter-cavity coupling strength and the cavity linewidth. For a quantum emitter subject to strong pure dephasing, our calculations reveal that an unconventional regime of high indistinguishability can be reached for moderate emittercavity coupling strengths and high quality factor cavities. In this regime, the broad spectrum of the dissipative quantum system is funneled into the narrow lineshape of the cavity. The associated efficiency is found to greatly surpass spectral filtering effects. Our findings open the path towards on-chip scalable indistinguishable-photon emitting devices operating at room temperature.Indistinguishable single photons are the building blocks of various optically-based quantum information applications such as linear optical quantum computing [1, 2], boson sampling [3][4][5][6][7], quantum teleportation [8] or quantum networks [9]. Indistinguishable photons are usually generated either using parametric down conversion [10], or alternatively directly from a single two-level quantum emitter such as atoms, color centers, quantum dots or organic molecules [11][12][13][14][15][16][17][18][19][20]. Parametric down conversion is presently the most mature technology available, but the usual low efficiency of the nonlinear processes is a severe limitation to the scalability of such sources. On the other hand, sources based on single solid-state quantum systems have been greatly developped in the last decade, as they hold the promise to combine indistinguishable, on-demand, energy-efficient, electrically drivable and scalable characteristics. However, except at cryogenics temperature, solid-state systems emitting single-photons are subject to strong pure dephasing processes [21][22][23][24][25][26][27][28][29], making them at first view inappropriate for quantum applications requiring photon indistinguishability.A two-level quantum emitter (QE) coupled only to vacuum fluctuations should emit perfectly indistinguishable photons. However, as soon as pure dephasing of the QE occurs, the degree of indistinguishability of the emitted photons is reduced to [30]where γ = 1/T 1 is the population decay rate, γ * /2 = 1/T * 2 the pure dephasing rate, and 1/T 2 = 2/T 1 + 1/T 2 * the total dephasing rate. For solid-state QE emitting photons at room temperature such as color centers, quantum dots or organic molecules, pure dephasing rates are typically several orders of magnitude larger than the population decay rate (typically ranging from 3 to 6 orders of magnitude) [12,14,21,22,24,[26][27][28][29]31]. Hence the intrinsic indistinguishability given by Eq. 1 is almost zero. A possible way to enhance the indistinguishability is to spectrally filter the emitted photons a posteriori. However, this linear-filter strategy leads to a very low efficiency. Engin...

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Experimental validation of photonic boson sampling

Cited by 311 publications

References 21 publications

High-dimensional unitary transformations and boson sampling on temporal modes using dispersive optics

High-dimensional unitary transformations and boson sampling on temporal modes using dispersive optics

From Three-Photon Greenberger-Horne-Zeilinger States to Ballistic Universal Quantum Computation

Cavity-Funneled Generation of Indistinguishable Single Photons from Strongly Dissipative Quantum Emitters

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