Prospects for bismuth nanowires as thermoelectrics

M. S. Dresselhaus; Z. Zhang; X. Sun; J. Y. Ying; J. Heremans; G. Dresselhaus; G. Chen

Prospects for bismuth nanowires as thermoelectrics

M. S. Dresselhaus^*
, Z. Zhang
, X. Sun
, J. Y. Ying
, J. Heremans
, G. Dresselhaus
, G. Chen

^*Corresponding author for this work

Research output: Contribution to journal › Conference article › peer-review

13 Scopus citations

Abstract

The small effective mass of Bi, high anisotropy of its Fermi surface, and the high aspect ratio (length/diameter) of Bi nanowires make this an excellent system for studying quantum confinement effects of a one-dimensional (1D) electron gas in relation to electrical conductivity, thermoelectric power, and thermal conductivity. A theoretical model based on the basic electronic band structure of bulk Bi is suitably modified to describe 1D bismuth nanowires and is used to predict the dependence of these transport properties on nanowire diameter, temperature and crystalline orientation of the bismuth nanowires. Experiments have been carried out on ultra-fine single crystal Bi nanowires (10-120 nm diameter) with a packing density as high as 7 × 10¹⁰ wires/cm² to test the quantum confinement assumptions of the model and the occurrence of a quantum confinement-induced semimetal-to-semiconductor transition as the wire diameter becomes less than 100 nm. Prospects for the use of bismuth nanowires for the thermoelectric applications are discussed.

Original language	English
Pages (from-to)	215-226
Number of pages	12
Journal	Materials Research Society Symposium - Proceedings
Volume	545
State	Published - 1999
Externally published	Yes

ASJC Scopus subject areas

General Materials Science
Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

Cite this

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title = "Prospects for bismuth nanowires as thermoelectrics",

abstract = "The small effective mass of Bi, high anisotropy of its Fermi surface, and the high aspect ratio (length/diameter) of Bi nanowires make this an excellent system for studying quantum confinement effects of a one-dimensional (1D) electron gas in relation to electrical conductivity, thermoelectric power, and thermal conductivity. A theoretical model based on the basic electronic band structure of bulk Bi is suitably modified to describe 1D bismuth nanowires and is used to predict the dependence of these transport properties on nanowire diameter, temperature and crystalline orientation of the bismuth nanowires. Experiments have been carried out on ultra-fine single crystal Bi nanowires (10-120 nm diameter) with a packing density as high as 7 × 1010 wires/cm2 to test the quantum confinement assumptions of the model and the occurrence of a quantum confinement-induced semimetal-to-semiconductor transition as the wire diameter becomes less than 100 nm. Prospects for the use of bismuth nanowires for the thermoelectric applications are discussed.",

author = "Dresselhaus, \{M. S.\} and Z. Zhang and X. Sun and Ying, \{J. Y.\} and J. Heremans and G. Dresselhaus and G. Chen",

year = "1999",

language = "English",

volume = "545",

pages = "215--226",

journal = "Materials Research Society Symposium - Proceedings",

issn = "0272-9172",

publisher = "Materials Research Society",

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TY - JOUR

T1 - Prospects for bismuth nanowires as thermoelectrics

AU - Dresselhaus, M. S.

AU - Zhang, Z.

AU - Sun, X.

AU - Ying, J. Y.

AU - Heremans, J.

AU - Dresselhaus, G.

AU - Chen, G.

PY - 1999

Y1 - 1999

N2 - The small effective mass of Bi, high anisotropy of its Fermi surface, and the high aspect ratio (length/diameter) of Bi nanowires make this an excellent system for studying quantum confinement effects of a one-dimensional (1D) electron gas in relation to electrical conductivity, thermoelectric power, and thermal conductivity. A theoretical model based on the basic electronic band structure of bulk Bi is suitably modified to describe 1D bismuth nanowires and is used to predict the dependence of these transport properties on nanowire diameter, temperature and crystalline orientation of the bismuth nanowires. Experiments have been carried out on ultra-fine single crystal Bi nanowires (10-120 nm diameter) with a packing density as high as 7 × 1010 wires/cm2 to test the quantum confinement assumptions of the model and the occurrence of a quantum confinement-induced semimetal-to-semiconductor transition as the wire diameter becomes less than 100 nm. Prospects for the use of bismuth nanowires for the thermoelectric applications are discussed.

AB - The small effective mass of Bi, high anisotropy of its Fermi surface, and the high aspect ratio (length/diameter) of Bi nanowires make this an excellent system for studying quantum confinement effects of a one-dimensional (1D) electron gas in relation to electrical conductivity, thermoelectric power, and thermal conductivity. A theoretical model based on the basic electronic band structure of bulk Bi is suitably modified to describe 1D bismuth nanowires and is used to predict the dependence of these transport properties on nanowire diameter, temperature and crystalline orientation of the bismuth nanowires. Experiments have been carried out on ultra-fine single crystal Bi nanowires (10-120 nm diameter) with a packing density as high as 7 × 1010 wires/cm2 to test the quantum confinement assumptions of the model and the occurrence of a quantum confinement-induced semimetal-to-semiconductor transition as the wire diameter becomes less than 100 nm. Prospects for the use of bismuth nanowires for the thermoelectric applications are discussed.

UR - https://www.scopus.com/pages/publications/0032591217

M3 - Conference article

AN - SCOPUS:0032591217

SN - 0272-9172

VL - 545

SP - 215

EP - 226

JO - Materials Research Society Symposium - Proceedings

JF - Materials Research Society Symposium - Proceedings

ER -

Prospects for bismuth nanowires as thermoelectrics

Abstract

ASJC Scopus subject areas

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