Spark erosion: A high production rate method for producing Bi 0.5Sb 1.5Te 3 nanoparticles with enhanced thermoelectric performance

P. K. Nguyen; K. H. Lee; J. Moon; S. I. Kim; K. A. Ahn; L. H. Chen; S. M. Lee; R. K. Chen; S. Jin; A. E. Berkowitz

doi:10.1088/0957-4484/23/41/415604

Spark erosion: A high production rate method for producing Bi _0.5Sb _1.5Te ₃ nanoparticles with enhanced thermoelectric performance

P. K. Nguyen
, K. H. Lee
, J. Moon
, S. I. Kim
, K. A. Ahn
, L. H. Chen
, S. M. Lee
, R. K. Chen
, S. Jin
, A. E. Berkowitz

Department of Materials Science and Engineering

Research output: Contribution to journal › Article › peer-review

112 Scopus citations

Abstract

We report a new spark erosion technique for producing high-quality thermoelectric nanoparticles at a remarkably high rate and with enhanced thermoelectric properties. The technique was utilized to synthesize p-type Bi _0.5Sb _1.5Te ₃ nanoparticles with a production rate as high as 135gh ¹, using a relatively small laboratory apparatus and low energy consumption. The compacted nanocomposite samples made from these nanoparticles exhibit a well-defined, 20-50nm size nanograin microstructure, and show an enhanced figure of merit, ZT, of 1.36 at 360K. Such a technique is essential for providing inexpensive, oxidation-free nanoparticles which are required for the fabrication of high performance thermoelectric devices for power generation from waste heat, and for refrigeration.

Original language	English
Article number	415604
Journal	Nanotechnology
Volume	23
Issue number	41
DOIs	https://doi.org/10.1088/0957-4484/23/41/415604
State	Published - 19 Oct 2012

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Cite this

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title = "Spark erosion: A high production rate method for producing Bi 0.5Sb 1.5Te 3 nanoparticles with enhanced thermoelectric performance",

abstract = "We report a new spark erosion technique for producing high-quality thermoelectric nanoparticles at a remarkably high rate and with enhanced thermoelectric properties. The technique was utilized to synthesize p-type Bi 0.5Sb 1.5Te 3 nanoparticles with a production rate as high as 135gh 1, using a relatively small laboratory apparatus and low energy consumption. The compacted nanocomposite samples made from these nanoparticles exhibit a well-defined, 20-50nm size nanograin microstructure, and show an enhanced figure of merit, ZT, of 1.36 at 360K. Such a technique is essential for providing inexpensive, oxidation-free nanoparticles which are required for the fabrication of high performance thermoelectric devices for power generation from waste heat, and for refrigeration.",

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doi = "10.1088/0957-4484/23/41/415604",

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T2 - A high production rate method for producing Bi 0.5Sb 1.5Te 3 nanoparticles with enhanced thermoelectric performance

AU - Nguyen, P. K.

AU - Lee, K. H.

AU - Moon, J.

AU - Kim, S. I.

AU - Ahn, K. A.

AU - Chen, L. H.

AU - Lee, S. M.

AU - Chen, R. K.

AU - Jin, S.

AU - Berkowitz, A. E.

PY - 2012/10/19

Y1 - 2012/10/19

N2 - We report a new spark erosion technique for producing high-quality thermoelectric nanoparticles at a remarkably high rate and with enhanced thermoelectric properties. The technique was utilized to synthesize p-type Bi 0.5Sb 1.5Te 3 nanoparticles with a production rate as high as 135gh 1, using a relatively small laboratory apparatus and low energy consumption. The compacted nanocomposite samples made from these nanoparticles exhibit a well-defined, 20-50nm size nanograin microstructure, and show an enhanced figure of merit, ZT, of 1.36 at 360K. Such a technique is essential for providing inexpensive, oxidation-free nanoparticles which are required for the fabrication of high performance thermoelectric devices for power generation from waste heat, and for refrigeration.

AB - We report a new spark erosion technique for producing high-quality thermoelectric nanoparticles at a remarkably high rate and with enhanced thermoelectric properties. The technique was utilized to synthesize p-type Bi 0.5Sb 1.5Te 3 nanoparticles with a production rate as high as 135gh 1, using a relatively small laboratory apparatus and low energy consumption. The compacted nanocomposite samples made from these nanoparticles exhibit a well-defined, 20-50nm size nanograin microstructure, and show an enhanced figure of merit, ZT, of 1.36 at 360K. Such a technique is essential for providing inexpensive, oxidation-free nanoparticles which are required for the fabrication of high performance thermoelectric devices for power generation from waste heat, and for refrigeration.

UR - https://www.scopus.com/pages/publications/84866989137

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DO - 10.1088/0957-4484/23/41/415604

M3 - Article

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SN - 0957-4484

VL - 23

JO - Nanotechnology

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IS - 41

M1 - 415604

ER -

Spark erosion: A high production rate method for producing Bi _0.5Sb _1.5Te ₃ nanoparticles with enhanced thermoelectric performance

Abstract

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