Generating single microwave photons in a circuit

Houck, Andrew; Schuster, David I.; Gambetta, Jay; Schreier, J. A.; Johnson, Blake; Chow, Jerry M.; Frunzio, Luigi; Majer, Johannes; Devoret, Michel; Girvin, S. M.; Schoelkopf, Robert

doi:10.1038/nature06126

Cited by 448 publications

(466 citation statements)

References 36 publications

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“…Qubits separated by relatively large distances have been coherently coupled using a cavity bus [4,5]. Finally, cQED enables the generation of classical and nonclassical light [6][7][8][9].…”

Section: Introductionmentioning

confidence: 99%

“…Early work demonstrated single photon generation by applying a π pulse to a qubit to drive a transition from the ground state to the excited state. The qubit was then brought into resonance with the cavity for a short period of time, thereby transferring the excitation from the qubit to the cavity [6]. n-photon Fock states were generated by repeating this process many times [9].…”

Section: Introductionmentioning

confidence: 99%

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Double Quantum Dot Floquet Gain Medium

et al. 2016

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Strongly driving a two-level quantum system with light leads to a ladder of Floquet states separated by the photon energy. Nanoscale quantum devices allow the interplay of confined electrons, phonons, and photons to be studied under strong driving conditions. Here, we show that a single electron in a periodically driven double quantum dot functions as a "Floquet gain medium," where population imbalances in the double quantum dot Floquet quasienergy levels lead to an intricate pattern of gain and loss features in the cavity response. We further measure a large intracavity photon number n c in the absence of a cavity drive field, due to equilibration in the Floquet picture. Our device operates in the absence of a dc current-one and the same electron is repeatedly driven to the excited state to generate population inversion. These results pave the way to future studies of nonclassical light and thermalization of driven quantum systems.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Double Quantum Dot Floquet Gain Medium

et al. 2016

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“…[8][9][10][11][12][13][14] A parallel development concerned the possibilities to perform fundamental quantum optics experiments with microwave photons in cavities. Experiments on microwave quantum optics range from arbitrary photon state preparation 15 and entanglement of cavity photons 16 to single photon generation, 17 microwave lasing 18 and fast tuning of cavity photon properties. 19,20 An important recent development is the efforts to reach the ultrastrong coupling regime, where the strength of the coupling between the qubit and the cavity becomes comparable to the frequency of the fundamental cavity mode.…”

Section: Introductionmentioning

confidence: 99%

Microwave quantum optics and electron transport through a metallic dot strongly coupled to a transmission line cavity

Bergenfeldt

Samuelsson

2012

Phys. Rev. B

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We investigate theoretically the properties of the photon state and the electronic transport in a system consisting of a metallic quantum dot strongly coupled to a superconducting microwave transmission line cavity. Within the framework of circuit quantum electrodynamics we derive a Hamiltonian for arbitrary strong capacitive coupling between the dot and the cavity. The dynamics of the system is described by a quantum master equation, accounting for the electronic transport as well as the coherent, non-equilibrium properties of the photon state. The photon state is investigated, focusing on, for a single active mode, signatures of microwave polaron formation and the effects of a non-equilibrium photon distribution. For two active photon modes, intra mode conversion and polaron coherences are investigated. For the electronic transport, electrical current and noise through the dot and the influence of the photon state on the transport properties are at the focus. We identify clear transport signatures due to the non-equilibrium photon population, in particular the emergence of superpoissonian shot-noise at ultrastrong dot-cavity couplings.

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“…Hence the electric field of such pulses is completely uncertain, a fact which has recently been verified. [3] Hofheinz et al have made a tour-de-force advance by deterministically generating photon number Fock states containing up to N = 6 photons (N = 15 in recent unpublished work) using a superconducting qubit coupled to a resonator.The resonator supports discrete modes at integer multiples of the fundamental. Because the modes are widely spaced in frequency for short res-1…”

mentioning

confidence: 99%

“…Single-photons-on-demand as well as coherent superpositions of 0 and 1 photons have been generated in a microwave resonator electrical circuit. [3] A classical signal generator produces a sine wave of constant amplitude, frequency and phase. The quantum equivalent (produced by a laser or a microwave signal generator) is a so-called coherent state.…”

mentioning

confidence: 99%

Generation of Fock states in a superconducting quantum circuit

Hofheinz

Weig

Ansmann

et al. 2008

Nature

539

562

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Nature 454, 310 (2008) Recommended and Commentary by Steven M. Girvin, Yale University Microwaves, despite their name, are particles. However the photon quanta of microwave fields are rather pusillanimous. They carry four to five orders of magnitude less energy than optical photons and are correspondingly vastly more difficult to detect and count. Nevertheless, recent progress in atomic cavity QED [1] and superconducting circuit QED [2] has achieved this. Single-photons-on-demand as well as coherent superpositions of 0 and 1 photons have been generated in a microwave resonator electrical circuit.[3]A classical signal generator produces a sine wave of constant amplitude, frequency and phase. The quantum equivalent (produced by a laser or a microwave signal generator) is a so-called coherent state. Because the phase is sharply defined, the photon number (which is the conjugate variable), is necessarily ill-defined. The number of photons to be found in a coherent pulse is in fact Poisson distributed. As a result, a coherent pulse which contain N photons on average will have a variance in photon number of √N. These closest cousins to classical waves are of course useful but not terribly exciting. There is great current interest in generating highly non-classical states of the electromagnetic field for purposes of quantum communication and quantum information processing. One interesting and highly non-classical class of states are the Fock states. These are electromagnetic pulses which contain exactly n photons where n is some specified integer. Because they have definite photon number, the phase suffers complete quantum uncertainty. Hence the electric field of such pulses is completely uncertain, a fact which has recently been verified. [3] Hofheinz et al. have made a tour-de-force advance by deterministically generating photon number Fock states containing up to N = 6 photons (N = 15 in recent unpublished work) using a superconducting qubit coupled to a resonator.The resonator supports discrete modes at integer multiples of the fundamental. Because the modes are widely spaced in frequency for short res-1

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Generating single microwave photons in a circuit

Cited by 448 publications

References 36 publications

Double Quantum Dot Floquet Gain Medium

Double Quantum Dot Floquet Gain Medium

Microwave quantum optics and electron transport through a metallic dot strongly coupled to a transmission line cavity

Generation of Fock states in a superconducting quantum circuit

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