Reciprocity in reflection and transmission: What is a ‘phonon diode’?

Maznev, A. A.; Every, A. G.; Wright, Oliver B.

doi:10.1016/j.wavemoti.2013.02.006

Cited by 199 publications

(139 citation statements)

References 34 publications

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“…35 42 and R=140 in a metal-superconductor hybrid. 43 It must be emphasized that although proving non-reciprocity is a prerequisite for observing thermal rectification, 44 some experiments may not satisfy the prerequisite due to technical difficulties. Thus, some of the previous experimental findings might not be genuine thermal rectifiers.…”

confidence: 99%

Detecting thermal rectification

Chiu

Huang

et al. 2016

AIP Advances

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Thermal rectification is a special heat transfer phenomenon that thermal conductance of a sample is higher in one direction than that in the reversed direction. Thermal rectifiers have been proposed to be the building blocks of phononic circuits, high performance thermoelectric devices, and energy-saving materials. Theoretically, thermal rectification has been suggested to be ubiquitous, occurring in wherever nonlinear interactions and broken inversion symmetry are present. However, currently available experimental methods have limited sensitivities and are unable to unravel the interesting effect in many systems. Here, by adopting the concept of nonlinear optics, we propose an improved experimental method to detect minuscule thermal rectification from large background thermal conductance. Experimentally, a SiC nanowire, a SiGe nanowire, and a multiwall BN nanotube are investigated and found their thermal rectification is smaller than 0.2% even after asymmetric mass-loading. The method would be very powerful in revealing interesting phonon properties of many materials.

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confidence: 99%

Detecting thermal rectification

Chiu

Huang

et al. 2016

AIP Advances

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“…The conditions under which Rayleigh reciprocity theorem holds can be broken in three different ways: (i) breaking linearity, (ii) biasing with a vector that is odd under time reversal, or (iii) breaking time invariance [6,7]. Large acoustic isolation has been obtained using option (i) in a non-linear medium paired with a frequency selective mirror [8,9], or with the help of nonlinear acoustic inclusions [10]; however, all these nonlinear solutions typically introduce severe signal distortions and only work for large acoustic intensities.…”

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confidence: 99%

Subwavelength ultrasonic circulator based on spatiotemporal modulation

2015

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“…There is an ongoing debate on what constitutes proper terminology. In this article, we take the more conservative approach of Maznev et al 16 and only consider non-reciprocal media capable of breaking the transmission symmetry property, that is, they transmit acoustic energy in only one direction regardless of the spatial spectrum of the incident acoustic excitation. In other words, we eliminate passive devices [9][10][11][12][13] that exhibit time-reversal symmetry.…”

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confidence: 99%

Non-reciprocal and highly nonlinear active acoustic metamaterials

2014

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Unidirectional devices that pass acoustic energy in only one direction have numerous applications and, consequently, have recently received significant attention. However, for most practical applications that require unidirectionality at audio and low frequencies, subwavelength implementations capable of the necessary time-reversal symmetry breaking remain elusive. Here we describe a design approach based on metamaterial techniques that provides highly subwavelength and strongly non-reciprocal devices. We demonstrate this approach by designing and experimentally characterizing a non-reciprocal active acoustic metamaterial unit cell composed of a single piezoelectric membrane augmented by a nonlinear electronic circuit, and sandwiched between Helmholtz cavities tuned to different frequencies. The design is thinner than a tenth of a wavelength, yet it has an isolation factor of 410 dB. The design method generates relatively broadband unidirectional devices and is a good candidate for numerous acoustic applications.

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Reciprocity in reflection and transmission: What is a ‘phonon diode’?

Cited by 199 publications

References 34 publications

Detecting thermal rectification

Detecting thermal rectification

Subwavelength ultrasonic circulator based on spatiotemporal modulation

Non-reciprocal and highly nonlinear active acoustic metamaterials

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