Sisyphus cooling and amplification by a superconducting qubit

Grajcar, M.; Ploeg, S. H. W. van der; Izmalkov, A.; Il’ichev, E.; Meyer, H.‐G.; Fedorov, Arkady; Shnirman, Alexander; Schön, Gerd

doi:10.1038/nphys1019

Cited by 123 publications

(177 citation statements)

References 29 publications

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“…(ii) The second effect is a damping or amplification effect that is similar to resolved-sideband cooling in optics [12]. The same effect has been discussed also in Josephson qubits [30] and has been seen for the first vibronic transitions [22]. Consider the lower sideband fringes in Fig.…”

Section: Prl 101 256806 (2008) P H Y S I C a L R E V I E W L E T T Ementioning

confidence: 61%

“…A large number of experiments could be interpreted using the molecular analogy, including qubits coupled to oscillators [13][14][15][16][17][18][19][20][21][22] and qubits driven by an intense field [23][24][25][26][27]. The analogy is particularly apt for our case because there is clear separation of the electronic and vibrational energy scales, we drive at two frequencies, and the parameters of the molecule can be tuned in a wide range.…”

mentioning

confidence: 99%

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Vibronic Spectroscopy of an Artificial Molecule

Gunnarsson¹,

Tuorila

Paila³

et al. 2008

Phys. Rev. Lett.

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Section: Prl 101 256806 (2008) P H Y S I C a L R E V I E W L E T T Ementioning

confidence: 61%

mentioning

confidence: 99%

Vibronic Spectroscopy of an Artificial Molecule

Gunnarsson¹,

Tuorila

Paila³

et al. 2008

Phys. Rev. Lett.

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“…In these "circuit QED" setups a superconducting qubit plays the role of an artificial atom, while the radiation field is replaced by the modes of an electric resonator. In some of these experiments a strong enhancement of the resonator field and lasing were observed [14,15].…”

Section: Introductionmentioning

confidence: 96%

Single-qubit lasing in the strong-coupling regime

et al. 2010

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Motivated by recent "circuit QED" experiments we study the lasing transition and spectral properties of single-qubit lasers. In the strong coupling, low-temperature regime quantum fluctuations dominate over thermal noise and strongly influence the linewidth of the laser. When the qubit and the resonator are detuned, amplitude and phase fluctuations of the radiation field are coupled, and the phase diffusion model, commonly used to describe conventional lasers, fails. We predict pronounced effects near the lasing transition, with an enhanced linewidth and non-exponential decay of the correlation functions. We cover a wide range of parameters by using two complementary approaches, one based on the Liouville equation in a Fock state basis, covering arbitrarily strong coupling but limited to low photon numbers, the other based on the coherent-state representation, covering large photon numbers but restricted to weak or intermediate coupling.

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“…We can also make the potential asymmetric, for example by introducing flux bias in flux qubits. The lowest three levels then function as a Λ system, which have been used to demonstrate, for example, lasing and cooling of qubits [17][18][19]. However, it is difficult to satisfy the impedance-matching condition, i.e., identical decay rates from the second excited state, in the Λ systems thus created.…”

mentioning

confidence: 99%

Implementation of an Impedance-MatchedΛSystem by Dressed-State Engineering

et al. 2013

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In one-dimensional optical setups, light-matter interaction is drastically enhanced by the interference between the incident and scattered fields. Particularly, in the impedance-matched Λ-type three-level systems, a single photon deterministically induces the Raman transition and switches the electronic state of the system. Here we show that such a Λ system can be implemented by using dressed states of a driven superconducting qubit and a resonator. The input microwave photons are perfectly absorbed and are down-converted into other frequency modes in the same waveguide. The proposed setup is applicable to single-photon detection in the microwave domain.PACS numbers: 03.67. Lx, 85.25.Cp, 42.50.Pq In one-dimensional optical setups, radiation from a quantum emitter is guided completely to specified onedimensional propagating modes. We can realize such setups in a variety of physical systems, such as optical cavity quantum electrodynamics (QED) systems using atoms or quantum dots [1][2][3] and circuit QED systems using superconducting qubits [4][5][6]. When we apply a field to excite the emitter through the one-dimensional mode in these setups, the incident field inevitably interferes with the field scattered by the emitter due to the low dimensionality [7]. As a result, we can realize unique optical phenomena that are not achievable in three-dimensional free space. A classical example is the complete transmission of a resonant field through a two-sided cavity, in which reflection from the cavity is forbidden due to the destructive interference between the incident field and the cavity emission in the reflection direction. Such one-dimensional optical setups in which reflection from the emitter is forbidden are called impedance-matched, in analogy with properly terminated electric circuits [8,9]. Recently, perfect reflection of the incident field by a single emitter has been confirmed in both optical cavity QED and circuit QED systems [2,4]. Here, transmission is forbidden by the destructive interference occurring in the transmission direction.In this study, we investigate a three-level Λ system interacting with a semi-infinite one-dimensional field in a reflection geometry (Fig. 1). We denote the three levels of the Λ system by |g , |m and |e from the lowest. We assume that |m decays to |g with a finite lifetime and therefore that the system is in |g when stationary. When a single photon resonant to the |g → |e transition is input, there are three possible processes: (a) simple reflection without exciting the system, (b) elastic scattering, inducing the |g → |e → |g transitions, and (c) inelastic scattering, inducing the |g → |e → |m → |g transitions. Destructive interference occurs here between processes (a) and (b). In particular, they cancel each other completely when the two decay rates from the top level |e are identical (Γ eg = Γ em ) and the coherence length of the input photon is sufficiently long. As a result, the input photon is down-converted deterministically, inducing the Raman transition in the sy...

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Sisyphus cooling and amplification by a superconducting qubit

Cited by 123 publications

References 29 publications

Vibronic Spectroscopy of an Artificial Molecule

Vibronic Spectroscopy of an Artificial Molecule

Single-qubit lasing in the strong-coupling regime

Implementation of an Impedance-MatchedΛSystem by Dressed-State Engineering

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