Observation of the Vacuum Rabi Spectrum for One Trapped Atom

Boca, A.; Miller, Ryan; Birnbaum, Kevin; Boozer, A. D.; McKeever, J.; Kimble, H. J.

doi:10.1103/physrevlett.93.233603

Cited by 383 publications

(326 citation statements)

References 23 publications

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“…In terms of the numerical [3] and the experimental results [7], a U CPF takes T = 3 ∼ 5µs for κT ≫ 1. With the experimental numbers κ/2π ∼ 4 MHz, g/2π ∼ 30 MHz, Γ/2π ∼ 2.6 MHz [7,16], we may estimate the time for the logic-qubit operations H and C NOT to be of the order of 10 −6 ∼ 10 −5 s. In realistic experiments, however, we should pay attention to photon loss during the experiment and to the detector efficiency. Fortunately, as the different operational results in each step are distinguishable in our scheme, (for example, the single-logic-qubit operation H i in the ith cavity is associated with a single-photon pulse input in port i and the detector Di, whereas the twologic-qubit operation U i,j C-Z is relevant to the input port i and the response of Dj), the successful detections of the single-photon pulses ensure the high fidelities of the gate operations.…”

Section: Is: Port I-tr1-tr1*-c-pbs-cavity I-pbs-c-tr2-hwp1-m-tr1-hwp2mentioning

confidence: 99%

Transfer and teleportation of quantum states encoded in decoherence-free subspace

et al. 2007

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Quantum state transfer and teleportation, with qubits encoded in internal states of the atoms in cavities, among spatially separated nodes of a quantum network in decoherence-free subspace are proposed, based on a cavity-assisted interaction by single-photon pulses. We show in details the implementation of a logic-qubit Hadamard gate and a two-logic-qubit conditional gate, and discuss the experimental feasibility of our scheme.PACS numbers: 03.67. Hk, 42.50.Dv Quantum state transfer and teleportation are significant components in quantum information processing, especially for quantum network. As the confined atoms in cavity QED system are well suited for storing qubits in long-lived internal states, spatially separated cavities could be used to build a quantum network assisted by photons [1,2,3,4,5,6,7,11]. On the other hand, decoherence due to the inevitable interaction with environment destroys quantum coherence. So decoherence-free subspaces (DFSs) of Hilbert space has been introduced to protect against some errors due to environmental coupling with certain symmetry [8,9,10]. For example, Ref.[10] utilized two atoms to encode single-logic-qubit, i.e.,, which are robust to collective dephasing error caused by ambient magnetic fluctuation.In this Brief Report, for the quantum state encoded in DFS mentioned above, we present implementation of single-logic-qubit Hadamard gate and two-logic-qubit conditional gate based on cavity-assisted interaction with single-photon pulses. Based on these gates, we will carry out the quantum state transfer and teleportation between two spatially separated nodes in a quantum network. Compared with previous related works, our proposal does not rely on the synchronous optical lattices [4] in implementation of the single-logic-qubit Hadamard gate. In addition, auxiliary entangled photon pairs, as employed in [5], are unnecessary in our two-logic-qubit conditional gate. Moreover, for quantum state transfer, neither the entangled photon pairs [11] nor the special time-symmetric wave packet of the photons [1] is necessary in our scheme. So our scheme could not only protect quantum information from some decoherence, but also reduce the experimental difficulty compared to the previous schemes [1,4,5,11]. Furthermore, in our scheme, each node of the quantum network in DFS has individual input port for photons to complete necessary operations, and different operational results can be distinguished by * Electronic address: huawei.hw@gmail.com † Electronic address: mangfeng1968@yahoo.com detecting output photons.The main idea using cavity-assisted photon scattering to realize a controlled phase flip (CPF) between two atoms [3,4,5,6,11], is sketched below. Suppose that two identical atoms, each of which has a three-level configuration, are well located in a high-finesse cavity. The levels |0 and |e of the atom are resonantly coupled by the bare cavity mode with h polarization or by the h component of an input photon, while level |1 is decoupled because of the large detuning, as shown in Fi...

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Section: Is: Port I-tr1-tr1*-c-pbs-cavity I-pbs-c-tr2-hwp1-m-tr1-hwp2mentioning

confidence: 99%

Transfer and teleportation of quantum states encoded in decoherence-free subspace

et al. 2007

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“…In view of the superior nature of these two materials, it is proposed that these two materials can be combined in a systematic manner. Therefore, we can achieve a composite structure with specific optical properties and can observe the new phenomenon of the interaction between SPs and excitons [69][70][71][72].…”

Section: Brief Introduction To the Interaction Between Lsps And Excitonsmentioning

confidence: 99%

Exciton-plasmon coupling interactions: from principle to applications

et al. 2017

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Abstract:The interaction of exciton-plasmon coupling and the conversion of exciton-plasmon-photon have been widely investigated experimentally and theoretically. In this review, we introduce the exciton-plasmon interaction from basic principle to applications. There are two kinds of exciton-plasmon coupling, which demonstrate different optical properties. The strong exciton-plasmon coupling results in two new mixed states of light and matter separated energetically by a Rabi splitting that exhibits a characteristic anticrossing behavior of the exciton-LSP energy tuning. Compared to strong coupling, such as surface-enhanced Raman scattering, surface plasmon (SP)-enhanced absorption, enhanced fluorescence, or fluorescence quenching, there is no perturbation between wave functions; the interaction here is called the weak coupling. SP resonance (SPR) arises from the collective oscillation induced by the electromagnetic field of light and can be used for investigating the interaction between light and matter beyond the diffraction limit. The study on the interaction between SPR and exaction has drawn wide attention since its discovery not only due to its contribution in deepening and broadening the understanding of SPR but also its contribution to its application in light-emitting diodes, solar cells, low threshold laser, biomedical detection, quantum information processing, and so on.

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“…The first rung shows the so-called vacuum Rabi splitting 2g, the second rung shows the splitting 2g √ 2, and so on. For sufficiently small damping and dephasing, the different rungs are clearly visible as discrete resonances, e.g., in transmission spectra.The first observations of strong coupling [5,6] and the second rung [7] were reported for atoms in high-quality cavities. Besides the demonstration of the discrete nature of light, this research has lead to major advances, e.g.…”

mentioning

confidence: 99%

Characterization of Strong Light-Matter Coupling in Semiconductor Quantum-Dot Microcavities via Photon-Statistics Spectroscopy

2008

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It is shown that spectrally resolved photon-statistics measurements of the resonance fluorescence from realistic semiconductor quantum-dot systems allow for high contrast identification of the twophoton strong-coupling states. Using a microscopic theory, the second-rung resonance is analyzed and optimum excitation conditions are determined. The computed photon-statistics spectrum displays gigantic, experimentally robust resonances at the energetic positions of the second-rung emission.PACS numbers: 42.50. Pq, 42.50.Ar, 78.67.Hc, 78.90.+t Even though light-quantization effects, such as squeezing [1], antibunching [2], and entanglement [3], have been observed under a wide range of conditions, one can rarely detect the discrete energy levels of the different photonnumber states directly as resonances. Under strongcoupling conditions between a two-level resonance at the energy ω and the quantized resonant light field, the resulting dressed-state resonances appear at ωn±g √ n + 1 where n is the occupation of the photon-number state |n and g is the light-matter coupling constant [4]. The resulting discrete energy structure resembles a ladder with n-dependent rungs. The first rung shows the so-called vacuum Rabi splitting 2g, the second rung shows the splitting 2g √ 2, and so on. For sufficiently small damping and dephasing, the different rungs are clearly visible as discrete resonances, e.g., in transmission spectra.The first observations of strong coupling [5,6] and the second rung [7] were reported for atoms in high-quality cavities. Besides the demonstration of the discrete nature of light, this research has lead to major advances, e.g. in utilizing entanglement effects as a basis for quantum-logic applications [8,9]. The clear identification of the secondrung resonance can be considered as the critical step if one wants to use other materials, such as solid-state systems for strong-coupling applications. A promising candidate are semiconductor quantum dots (QD) in microcavities. Recent experiments [10,11,12,13] have already demonstrated that one can see clear vacuum Rabi splitting effects in the photoluminescence (PL) of such systems. However, despite continuing attempts, the second rung resonance has not yet been observed. The most likely reason for this failure is that dephasing and the other broadening effects in the real systems smear out the expected discrete features.In this Letter, we propose a novel scheme to observe the second-rung strong coupling effects even under the realistic broadening conditions of the currently available samples. In our approach, we use a fully microscopic theory to determine the exact conditions to obtain unambiguous evidence for the presence of the second-rung resonance in QD microcavities. Our results confirm the difficulty of the second-rung observations in standard semiconductor experiments that monitor PL after carrier capture of electrons, initially created to the wetting layer. However, we demonstrate that it should be completely feasible to observe the second rung in re...

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Observation of the Vacuum Rabi Spectrum for One Trapped Atom

Cited by 383 publications

References 23 publications

Transfer and teleportation of quantum states encoded in decoherence-free subspace

Transfer and teleportation of quantum states encoded in decoherence-free subspace

Exciton-plasmon coupling interactions: from principle to applications

Characterization of Strong Light-Matter Coupling in Semiconductor Quantum-Dot Microcavities via Photon-Statistics Spectroscopy

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