High Temperature Near-Field NanoThermoMechanical Rectification

Elzouka, Mahmoud; Ndao, Sidy

doi:10.1038/srep44901

Cited by 37 publications

(24 citation statements)

References 36 publications

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“…Recent room temperature measurements 280 showed r as large as 100-1000 for SiO 2 -SiO 2 surfaces or Au-Au surfaces as the gap was reduced to L < 100 nm. For larger values of L ¼ 3 lm, Elzouka and Ndoa 281 reported thermal rectifications of 10% at DT ¼ 150 K using the asymmetric thermal expansion of a MEMS structure to control L. Overall, for the purpose of thermal switching it is likely more practical (and effective 282 ) to bring materials fully in and out of contact (see Sec. III A 4) than to rely on near field mechanisms, since it is difficult to maintain and control such small yet finite L over macroscopic distances.…”

Section: Near Field Radiationmentioning

confidence: 99%

Thermal diodes, regulators, and switches: Physical mechanisms and potential applications

Wehmeyer

Yabuki

Monachon

et al. 2017

Applied Physics Reviews

377

261

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Interest in new thermal diodes, regulators, and switches has been rapidly growing because these components have the potential for rich transport phenomena that cannot be achieved using traditional thermal resistors and capacitors. Each of these thermal components has a signature functionality: Thermal diodes can rectify heat currents, thermal regulators can maintain a desired temperature, and thermal switches can actively control the heat transfer. Here, we review the fundamental physical mechanisms of switchable and nonlinear heat transfer which have been harnessed to make thermal diodes, switches, and regulators. The review focuses on experimental demonstrations, mainly near room temperature, and spans the fields of heat conduction, convection, and radiation. We emphasize the changes in thermal properties across phase transitions and thermal switching using electric and magnetic fields. After surveying fundamental mechanisms, we present various nonlinear and active thermal circuits that are based on analogies with well-known electrical circuits, and analyze potential applications in solid-state refrigeration and waste heat scavenging.

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Section: Near Field Radiationmentioning

confidence: 99%

Thermal diodes, regulators, and switches: Physical mechanisms and potential applications

Wehmeyer

Yabuki

Monachon

et al. 2017

Applied Physics Reviews

377

261

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“…1a. It consists of a high-temperature emitter and low-temperature receiver made of Si, with boron doping of ~ 4.6×10 19 cm -3 , separated by low thermal conductivity SU-8 3005 micropillars (0.2 Wm -1 K -1 ) 22 the emitter and receiver, thus minimizing the contribution of parasitic conduction to the total heat rate 23 . The micropillar and pit areas respectively cover 0.01% and less than 1.2% of the total surface of the device.…”

Section: Performing Nfrht Measurements Direct Gap Spacing Characterimentioning

confidence: 99%

A near-field radiative heat transfer device

2019

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Recently, many works have experimentally demonstrated near-field radiative heat transfer (NFRHT) exceeding the far-field blackbody limit between planar surfaces [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15] . Due to the difficulties associated with maintaining the nanosize gaps required for measuring a nearfield enhancement, these demonstrations have been limited to experiments that cannot be implemented into actual applications. This poses a significant bottleneck to the advancement of NFRHT research. Here, we describe devices bridging laboratory-scale measurements and potential NFRHT engineering applications in energy conversion 16,17 and thermal management 18-20 . We report a maximum NFRHT enhancement of ~ 28.5 over the blackbody limit with devices made of millimeter-sized doped silicon (Si) surfaces separated by vacuum gap spacings down to ~ 110 nm. The devices capitalize on micropillars, separating the high-temperature emitter and low-temperature receiver, manufactured within micrometer-deep pits. These micropillars, which are ~ 4.5 to 45 times longer than the nanosize vacuum spacing where radiation transfer takes place, minimize parasitic heat conduction without sacrificing device structural integrity. The robustness of our devices enables gap spacing visualization via scanning electron microscopy (SEM) prior to *

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“…Microfabrication process. The proposed microdevices were fabricated using cleanroom standard microfabrication techniques starting with a four-inch-diameter <100> silicon on insulator (SOI) wafer 16 . The SOI wafer consisted of a 400-μm thick handle silicon substrate, a 1-μm thick buried silicon dioxide layer, and a 20-μm thick boron-doped silicon device layer.…”

Section: Design and Methodologymentioning

confidence: 99%

“…The characterization and heat transfer measurements of the thermal logic gates were performed inside a vacuum probe station at vacuum levels below 10 −5 mbar, in order to eliminate convection and conduction heat losses 16 . The platinum microheaters patterned on the mechanisms were powered independently via two source-meter units (Keithley 2602 B andKeithley 2611 B).…”

Section: Experimental Procedures and Measurementsmentioning

confidence: 99%

NanoThermoMechanical AND and OR Logic Gates

Hamed

Ndao

2020

Sci Rep

Self Cite

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today's electronics cannot perform in harsh environments (e.g., elevated temperatures and ionizing radiation environments) found in many engineering applications. Based on the coupling between near-field thermal radiation and MEMS thermal actuation, we presented the design and modeling of nanothermoMechanical AnD, oR, and not logic gates as an alternative, and showed their ability to be combined into a full thermal adder to perform complex operations. in this work, we introduce the fabrication and characterization of the first ever documented Thermal AND and OR logic gates. The results show thermal logic operations can be achieved successfully through demonstrated and easy-tomanufacture nanothermoMechanical logic gates.Today's electronics have limited performance and reliability in harsh environments (e.g., elevated temperatures and ionizing radiation environments) found in many engineering applications such as space exploration (e.g., Venus) and geothermal energy exploitation deep beneath the earth; consequently, developing alternative computing technologies is necessary. Thermal computing, data processing based on heat instead of electricity, is proposed as a practical solution and opens a new scientific area at the interface between thermal and computational sciences. The traditional linear and passive thermal components, such as thermal resistors and capacitors, are not sufficient to introduce an integrated thermal logic circuit. It is needed to realize switchable and nonlinear thermal components as their electronic counterparts, which leads to tunable thermal control devices and paves the way for thermal computation technology and thermal information treatment.Much research efforts have been done to realize thermal diodes, switches, transistors, and thermal logic gates 1-3 . The non-linear behavior of the temperature/phase-dependent thermal conductivity of certain materials was successfully employed to demonstrate thermal switch and regulators 4-9 . Additionally, thermal switches and regulators were realized by tailoring heat conduction through solid/solid and solid/liquid physical contact 10,11 , and by manipulating convection heat transfer mechanisms [12][13][14][15] . Another research efforts, which employed thermal radiation, were promising solutions 16-21 . However, the challenge is to develop individual thermal rectifiers or diodes and thermal logic circuits that are not limited to a small operating temperatures or specific materials. Previously, we built and simulated a thermal calculator based on clustered NanoThermoMechanical logic gates that could perform similar operations as their electronic counterparts. We presented the design and modeling of the NanoThermoMechanical AND, OR, and NOT logic gates, achieved through the coupling between near-field thermal radiation (NFTR) and MEMS thermal actuation 22 . NFTR transfers heat via thermal radiation between two surfaces separated by a very small vacuum gap (i.e., comparable to the radiation wavelength). NFTR's intensity increases exponentially with a d...

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High Temperature Near-Field NanoThermoMechanical Rectification

Cited by 37 publications

References 36 publications

Thermal diodes, regulators, and switches: Physical mechanisms and potential applications

Thermal diodes, regulators, and switches: Physical mechanisms and potential applications

A near-field radiative heat transfer device

NanoThermoMechanical AND and OR Logic Gates

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