Enhanced thermoelectric figure of merit of individual Si nanowires with ultralow contact resistances

Gadea, Gerard; Gordillo, Jose Manuel Sojo; Pujadó, Mercè Pacios; Salleras, M.; Fonseca, L.; Morata, Àlex; Rubio, Albert

doi:10.1016/j.nanoen.2019.104191

Cited by 30 publications

(54 citation statements)

References 60 publications

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“…The most relevant point is the very low thermal conductivity of our SiNW forests, which is 1.8 ± 0.3 W/m K. Several works reported a low thermal conductivity, measured on single silicon nanowires. 8 , 13 , 25 , 40 , 41 In particular, nanowires fabricated by the top-down approach and smoothed by thermal oxidation showed a thermal conductivity over 10 W/(m K). 10 A thermal conductivity smaller than 10 W/(m K) has been measured on vertical nanowire arrays fabricated by lithography and DRIE 22 , 23 , 42 (9 W/(m K), 23 7.5 W/(m K), 22 and 10.1 W(m K) 42 ).…”

Section: Discussionmentioning

confidence: 99%

“… 42 Alternatively, both VLS and MACE processes can produce large amounts of nanowires without expensive high resolution lithography. VLS produces SiNW with enhanced thermoelectric properties (good Seebeck coefficient and electrical conductivity), with thermal conductivities around 20 W/(m K), 13 , 14 18 W/(m K), 13 and 22 W/(m K) 25 . The thermal conductivity of SiNW produced by MACE, measured on a single nanowire, 11 , 24 , 41 resulted in being smaller than that of VLS nanowires and comprised between 4 and 5 W/(m K).…”

Section: Discussionmentioning

confidence: 99%

“…The potentialities of silicon as a thermoelectric material have been assessed with devices based on one (or very few) nanowires. 11 , 13 , 14 However, the crucial point to be addressed for practical thermoelectric applications of silicon is to combine large amounts of nanostructures with suitable electrical and thermal connections, so that macroscopic thermoelectric generators (TEGs) capable of delivering enough electrical power can be produced. Large collections of silicon nanostructures can be achieved by bottom-up approaches, based on chemical-vapor deposition (CVD) through the vapor liquid solid (VLS) mechanism.…”

Section: Introductionmentioning

confidence: 99%

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High Power Thermoelectric Generator Based on Vertical Silicon Nanowires

et al. 2020

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Thermoelectric generators, which convert heat directly into electrical power, have great potentialities in the energy harvesting field. The exploitation of these potentialities is limited by the materials currently used, characterized by good thermoelectric properties, but also by several drawbacks. This work presents a silicon-based thermoelectric generator, made of a large collection of heavily p -doped silicon nanostructures. This macroscopic device (area of several mm 2 ) collects together the good thermoelectric features of silicon, in terms of high power factor, and a very reduced thermal conductivity, which resulted in being exceptionally low (1.8 W/(m K), close to the amorphous limit). The generated electrical power density is remarkably high for a Si-based thermoelectric generator, and it is suitable for scavenging applications which can exploit small temperature differences. A full characterization of the device (Seebeck coefficient, thermal conductivity, maximum power output) is reported and discussed.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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High Power Thermoelectric Generator Based on Vertical Silicon Nanowires

et al. 2020

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“…But it is noteworthy that for different temperatures, the ZT varies widely; the most valuable temperature is 300 K, which is the device's normal operate temperature. For Si, ZT = 0.2 is achieved at 620 K with the optimized contact in a recent work (Gadea Díez et al, 2020).…”

Section: Zt and Energy Conversion Efficiencymentioning

confidence: 94%

Si and SiGe Nanowire for Micro-Thermoelectric Generator: A Review of the Current State of the Art

et al. 2021

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In our environment, the large availability of wasted heat has motivated the search for methods to harvest heat. As a reliable way to supply energy, SiGe has been used for thermoelectric generators (TEGs) in space missions for decades. Recently, micro-thermoelectric generators (μTEG) have been shown to be a promising way to supply energy for the Internet of Things (IoT) by using daily waste heat. Combining the predominant CMOS compatibility with high electric conductivity and low thermal conductivity performance, Si nanowire and SiGe nanowire have been a candidate for μTEG. This review gives a comprehensive introduction of the Si, SiGe nanowires, and their possibility for μTEG. The basic thermoelectric principles, materials, structures, fabrication, measurements, and applications are discussed in depth.

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“…However, a large-scale application of thermoelectric devices requires the development of materials that have good thermoelectric features and are, at the same time, of low cost, technologically affordable and sustainable. Silicon has a very high power factor S 2 σ [1][2][3][4] (S is the Seebeck coefficient and σ is the electrical conductivity). This, combined with the reduced thermal conductivity when nanostructured [5][6][7][8][9][10], makes it very suitable for thermoelectric applications.…”

Section: Introductionmentioning

confidence: 99%

Seebeck coefficient of silicon nanowire forests doped by thermal diffusion

Elyamny¹,

Dimaggio²,

Pennelli³

2020

Beilstein J. Nanotechnol.

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Thermoelectric generators made by large arrays of nanowires perpendicular to a silicon substrate, that is, so-called silicon nanowire forests are fabricated on large areas by an inexpensive metal-assisted etching technique. After fabrication, a thermal diffusion process is used for doping the nanowire forest with phosphorous. A suitable experimental technique has been developed for the measurement of the Seebeck coefficient under static conditions, and results are reported for different doping parameters. These results are in good agreement with numerical simulations of the doping process applied to silicon nanowires. These devices, based on doped nanowire forests, offer a possible route for the exploitation of the high power factor of silicon, which, combined with the very low thermal conductivity of nanostructures, will yield a high efficiency of the conversion of thermal to electrical energy.

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Enhanced thermoelectric figure of merit of individual Si nanowires with ultralow contact resistances

Cited by 30 publications

References 60 publications

High Power Thermoelectric Generator Based on Vertical Silicon Nanowires

High Power Thermoelectric Generator Based on Vertical Silicon Nanowires

Si and SiGe Nanowire for Micro-Thermoelectric Generator: A Review of the Current State of the Art

Seebeck coefficient of silicon nanowire forests doped by thermal diffusion

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