High-power density piezoelectric energy harvesting using radially strained ultrathin trigonal tellurium nanowire assembly

Tae Il Lee; Sangmin Lee; Eungkyu Lee; Sungwoo Sohn; Yean Lee; Sujeong Lee; Geondae Moon; Dohyang Kim; Youn Sang Kim; Jae Min Myoung; Zhong Lin Wang

doi:10.1002/adma.201300657

High-power density piezoelectric energy harvesting using radially strained ultrathin trigonal tellurium nanowire assembly

Tae Il Lee, Sangmin Lee, Eungkyu Lee, Sungwoo Sohn, Yean Lee, Sujeong Lee, Geondae Moon, Dohyang Kim, Youn Sang Kim, Jae Min Myoung, Zhong Lin Wang

Department of Materials Science and Engineering

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

136 Citations (Scopus)

Abstract

A high-yield solution-processed ultrathin (<10 nm) trigonal tellurium (t-Te) nanowire (NW) is introduced as a new class of piezoelectric nanomaterial with a six-fold higher piezoelectric constant compared to conventional ZnO NWs for a high-volume power-density nanogenerator (NG). While determining the energy-harvesting principle in a NG consisting of t-Te NW, it is theoretically and experimentally found that t-Te NW is piezoelectrically activated only by creating strain in its radial direction, along which it has an asymmetric crystal structure. Based upon this mechanism, a NG with a monolayer consisting of well-aligned t-Te NWs and a power density of 9 mW/cm³ is fabricated.

Original language	English
Pages (from-to)	2920-2925
Number of pages	6
Journal	Advanced Materials
Volume	25
Issue number	21
DOIs	https://doi.org/10.1002/adma.201300657
Publication status	Published - 2013 Jun 4

All Science Journal Classification (ASJC) codes

Materials Science(all)
Mechanics of Materials
Mechanical Engineering

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10.1002/adma.201300657

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title = "High-power density piezoelectric energy harvesting using radially strained ultrathin trigonal tellurium nanowire assembly",

abstract = "A high-yield solution-processed ultrathin (<10 nm) trigonal tellurium (t-Te) nanowire (NW) is introduced as a new class of piezoelectric nanomaterial with a six-fold higher piezoelectric constant compared to conventional ZnO NWs for a high-volume power-density nanogenerator (NG). While determining the energy-harvesting principle in a NG consisting of t-Te NW, it is theoretically and experimentally found that t-Te NW is piezoelectrically activated only by creating strain in its radial direction, along which it has an asymmetric crystal structure. Based upon this mechanism, a NG with a monolayer consisting of well-aligned t-Te NWs and a power density of 9 mW/cm3 is fabricated.",

author = "Lee, {Tae Il} and Sangmin Lee and Eungkyu Lee and Sungwoo Sohn and Yean Lee and Sujeong Lee and Geondae Moon and Dohyang Kim and Kim, {Youn Sang} and Myoung, {Jae Min} and Wang, {Zhong Lin}",

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doi = "10.1002/adma.201300657",

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T1 - High-power density piezoelectric energy harvesting using radially strained ultrathin trigonal tellurium nanowire assembly

AU - Lee, Tae Il

AU - Lee, Sangmin

AU - Lee, Eungkyu

AU - Sohn, Sungwoo

AU - Lee, Yean

AU - Lee, Sujeong

AU - Moon, Geondae

AU - Kim, Dohyang

AU - Kim, Youn Sang

AU - Myoung, Jae Min

AU - Wang, Zhong Lin

PY - 2013/6/4

Y1 - 2013/6/4

N2 - A high-yield solution-processed ultrathin (<10 nm) trigonal tellurium (t-Te) nanowire (NW) is introduced as a new class of piezoelectric nanomaterial with a six-fold higher piezoelectric constant compared to conventional ZnO NWs for a high-volume power-density nanogenerator (NG). While determining the energy-harvesting principle in a NG consisting of t-Te NW, it is theoretically and experimentally found that t-Te NW is piezoelectrically activated only by creating strain in its radial direction, along which it has an asymmetric crystal structure. Based upon this mechanism, a NG with a monolayer consisting of well-aligned t-Te NWs and a power density of 9 mW/cm3 is fabricated.

AB - A high-yield solution-processed ultrathin (<10 nm) trigonal tellurium (t-Te) nanowire (NW) is introduced as a new class of piezoelectric nanomaterial with a six-fold higher piezoelectric constant compared to conventional ZnO NWs for a high-volume power-density nanogenerator (NG). While determining the energy-harvesting principle in a NG consisting of t-Te NW, it is theoretically and experimentally found that t-Te NW is piezoelectrically activated only by creating strain in its radial direction, along which it has an asymmetric crystal structure. Based upon this mechanism, a NG with a monolayer consisting of well-aligned t-Te NWs and a power density of 9 mW/cm3 is fabricated.

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JO - Advanced Materials

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High-power density piezoelectric energy harvesting using radially strained ultrathin trigonal tellurium nanowire assembly

Abstract

All Science Journal Classification (ASJC) codes

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