Evidence for Quantized Displacement in Macroscopic Nanomechanical Oscillators

Gaidarzhy, A.; Zolfagharkhani, G.; Badzey, Robert L.; Mohanty, Pritiraj

doi:10.1103/physrevlett.94.030402

Cited by 104 publications

(84 citation statements)

References 34 publications

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“…minute cantilevers, this would involve placing an object of many millions of atoms in a superposition state. However anti-intuitive this may appear, work has been recently reported that suggests this may indeed be possible 16,17 . Even if possible, such a device would not be at all easy to use, having to be operated at cryogenic temperatures to avoid decoherence due to thermal effects.…”

Section: Qubit Entanglement In An Optical Wavefront Processormentioning

confidence: 94%

Considerations for the extension of coherent optical processors into the quantum computing regime

2016

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Previously we have examined the similarities of the quantum Fourier transform to the classical coherent optical implementation of the Fourier transform (R. Young et al, Proc SPIE Vol 87480,. In this paper, we further consider how superposition states can be generated on coherent optical wave fronts, potentially allowing coherent optical processing hardware architectures to be extended into the quantum computing regime. In particular, we propose placing the pixels of a Spatial Light Modulator (SLM) individually in a binary superposition state and illuminating them with a coherent wave front from a conventional (but low intensity) laser source in order to make a so-called 'interaction free' measurement. In this way, the quantum object, i.e. the individual pixels of the SLM in their superposition states, and the illuminating wavefront would become entangled. We show that if this were possible, it would allow the extension of coherent processing architectures into the quantum computing regime and we give an example of such a processor configured to recover one of a known set of images encrypted using the well-known coherent optical processing technique of employing a random Fourier plane phase encryption mask which classically requires knowledge of the corresponding phase conjugate key to decrypt the image. A quantum optical computer would allow interrogation of all possible phase masks in parallel and so immediate decryption.

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Section: Qubit Entanglement In An Optical Wavefront Processormentioning

confidence: 94%

Considerations for the extension of coherent optical processors into the quantum computing regime

2016

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“…With respect to the (promising) applications and advantages of nanomechanical resonator, it still faces many serious technical challenges and difficulties, such as the fluctuation due to thermomechanical noise [10,20,21]; low Q factor with decreasing size [10,17,18,21,22], increasing magnetic field [21], increasing ambient pressure [4,21] and dynamic nonlinear response [3][4][5][6][7][8]10,11,21,23,24]. Recent findings on the initial conditions-dependent antiresonance response of weakly nonlinear nanomechanical resonator [24] and strongly nonlinear response of doubly clamped nanomechanical resonator [10] demonstrate some application limitations of nanomechanical resonators because of nonlinearity.…”

Section: Introductionmentioning

confidence: 99%

“…The advent of electronic transistor and magnetic storage technologies in 1960s, which were much superior to the mechanism of mechanical moving element in both manipulation speed and data density, resulted in the abandonment of Babbage's idea of mechanical computer [19]. Recent breakthrough in the fabrication of NEMS resonator with the fundamental characteristic frequency of 1 GHz and higher [9,11] intrigues further research interest in this area because such breakthrough could eventually lead to the realization of high performance mechanical computer which can compete with current electronic computer. Mechanical resonator with GHz characteristic frequency which moves on time scale of a nanosecond or less makes such competition possible [19].…”

Section: Introductionmentioning

confidence: 99%

“…As its characteristic frequency scales upwards with decreasing size [9], micro/nanometre-scale mechanical resonator/oscillator with high and ultrahigh characteristic frequency is suitable for those applications requiring both high responsivity and high frequency operation [10], such as charge detection [2], ultra-sensitive mass sensing [7,[12][13][14][15][16][17], signal processing/mixing [8] and possible quantum effect study on a macroscopic system [11]. Charles Babbage in 1834 designed the first mechanical analytic engine [5], which is viewed as the forerunner of modern computer [19].…”

Section: Introductionmentioning

confidence: 99%

“…The fabrication of micro/nano-electromechanical systems (MEMS/NEMS) is made possible due to the advancing technologies and state-of-art in the fields of micro/nanometrescale processing and machining [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18]. As its characteristic frequency scales upwards with decreasing size [9], micro/nanometre-scale mechanical resonator/oscillator with high and ultrahigh characteristic frequency is suitable for those applications requiring both high responsivity and high frequency operation [10], such as charge detection [2], ultra-sensitive mass sensing [7,[12][13][14][15][16][17], signal processing/mixing [8] and possible quantum effect study on a macroscopic system [11].…”

Section: Introductionmentioning

confidence: 99%

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Nonlinear dynamic response of beam and its application in nanomechanical resonator

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Nonlinear dynamic response of nanomechanical resonator is of very important characteristics in its application. Two categories of the tension-dominant and curvaturedominant nonlinearities are analyzed. The dynamic nonlinearity of four beam structures of nanomechanical resonator is quantitatively studied via a dimensional analysis approach. The dimensional analysis shows that for the nanomechanical resonator of tension-dominant nonlinearity, its dynamic nonlinearity decreases monotonically with increasing axial loading and increases monotonically with the increasing aspect ratio of length to thickness; the dynamic nonlinearity can only result in the hardening effects. However, for the nanomechanical resonator of the curvature-dominant nonlinearity, its dynamic nonlinearity is only dependent on axial loading. Compared with the tension-dominant nonlinearity, the curvature-dominant nonlinearity increases monotonically with increasing axial loading; its dynamic nonlinearity The project was supported by the National Natural Science Foundation of China (10721202 and 11023001) can result in both hardening and softening effects. The analysis on the dynamic nonlinearity can be very helpful to the tuning application of the nanomechanical resonator.

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On the quantum‐to‐classical transition of a particle in a box

2014

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The exact formulation of the correspondence principle and in particular understanding the quantum-to-classical transition remains an open problem in quantum mechanics. In this paper we present our investigation into the quantumto-classical transition of the most trivial of quantum systems -a particle in a box. Whilst it is perhaps surprising, even this example can produce new physical insight into these fundamental problems. With modern fabrication techniques of nano-mechanical systems we will be able to experimentally investigate these results and directly observe the quantum-to-classical transition. This will enable us to build technologies that probe the fundamental questions of quantum mechanics, such as the maximum size of a quantum object.

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Evidence for Quantized Displacement in Macroscopic Nanomechanical Oscillators

Cited by 104 publications

References 34 publications

Considerations for the extension of coherent optical processors into the quantum computing regime

Considerations for the extension of coherent optical processors into the quantum computing regime

Nonlinear dynamic response of beam and its application in nanomechanical resonator

On the quantum‐to‐classical transition of a particle in a box

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