2007
DOI: 10.1063/1.2724816
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Ultrahigh finesse Fabry-Pérot superconducting resonator

Abstract: We have built a microwave Fabry-Perot resonator made of diamond-machined copper mirrors coated with superconducting niobium. Its damping time (Tc = 130 ms at 51 GHz and 0.8 K) corresponds to a finesse of 4.6 × 10 9 , the highest ever reached for a Fabry-Perot in any frequency range. This result opens many perspectives for quantum information processing, decoherence and non-locality studies.PACS numbers: 42.50. Pq, Since Bohr-Einstein's photon box thought experiment, storing a photon for a long time has been a … Show more

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Cited by 215 publications
(228 citation statements)
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“…Here, instead of using optical cavities, as is usual in ongoing opto-mechanical experiments [18], we shall be using SC microwave cavities. The reason for this is that the quality factor for SC microwave cavities has already been demonstrated by Haroche and co-workers [19] to be on the order of Q ∼ 10 10 (46) which can be much higher than that of typical optical cavities. The motion of the SC wire in the middle of the microwave cavity will modulate the "pump" microwaves coming through the "IN" port so as to produce radiation at new sideband frequencies via the Doppler effect.…”
Section: The Dynamical Casimir Effect Via Parametric Oscillationsmentioning
confidence: 99%
See 1 more Smart Citation
“…Here, instead of using optical cavities, as is usual in ongoing opto-mechanical experiments [18], we shall be using SC microwave cavities. The reason for this is that the quality factor for SC microwave cavities has already been demonstrated by Haroche and co-workers [19] to be on the order of Q ∼ 10 10 (46) which can be much higher than that of typical optical cavities. The motion of the SC wire in the middle of the microwave cavity will modulate the "pump" microwaves coming through the "IN" port so as to produce radiation at new sideband frequencies via the Doppler effect.…”
Section: The Dynamical Casimir Effect Via Parametric Oscillationsmentioning
confidence: 99%
“…By inspection of (71) and (72), we see that these thresholds are quite similar. However, the electrodynamic Q factor of SC microwave cavities is typically on the order of 10 10 [19], whereas the typical mechanical Q factor for the best opto-mechanical oscillators, which are composed of non-SC materials in the ongoing opto-mechanical experiments, is at most on the order of 10 5 [18]. Therefore the question naturally arises whether it is possible to replace these low-Q, non-SC mechanical oscillators, with high-Q SC mechanical oscillators, in which their mechanical Q can approach the typical electrodynamic Q ∼ 10 10 of SC microwave cavities.…”
Section: The Dynamical Casimir Effect Via Parametric Oscillationsmentioning
confidence: 99%
“…Note that sensitivities scales as √ κ i . Therefore, if superconducting Fabry-Pérot cavities with a mediate Q = 10 5 [44], corresponding to κ i /2π = 28 kHz, is applied, the sensitivities can be improved to ∆B MP √ τ total 32.2 aT/ √ Hz when P in = 1 nW.…”
Section: Discussion Of Experimental Implementationmentioning
confidence: 99%
“…Such microwave cavities require particular designs and have been demonstrated using transmission line resonators [41][42][43] and three-dimensional superconducting Fabry-Pérot microwave cavities [44][45][46]. The Q factor of the transmission line resonator can be 100 − 10 5 [41,47], while that of the superconducting FP mw cavity can reach 10 12 [44]. Recently, Zhang et al developed a photonic crystal(PC) cavity with a small mode volume and a high Q (up to 10 5 ), working at microwave frequencies [48].…”
Section: Discussion Of Experimental Implementationmentioning
confidence: 99%
“…Due to the exchange of energy and information between the system and the environment, the non-Markovian dynamics of quantum states always occur in the realistic experimental systems [3][4][5]. Recently, much attentions have been paid to the control of the decoherence of many-body quantum systems [6,7] such as spin clusters and single molecular magnets [8].…”
Section: Introductionmentioning
confidence: 99%