Unconventional janus properties of enokitake-like gold nanowire films

Wenlong Cheng; Yan Wang; Shu Gong; Daniel Gómez; Yunzhi Ling; Lim Wei Yap; George P. Simon

doi:10.1021/acsnano.8b04748

Unconventional janus properties of enokitake-like gold nanowire films

Wenlong Cheng^*, Yan Wang, Shu Gong, Daniel Gómez, Yunzhi Ling, Lim Wei Yap, George P. Simon

^*Corresponding author for this work

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

67 Scopus citations

Abstract

We report on unconventional Janus material properties of vertically aligned gold nanowire films that conduct electricity and interact with light and water in drastically different ways on its two opposing sides. These Janus-like properties originate from enokitake-like nanowire structures, causing the nanoparticle side (“head”) to behave like bulk gold, yet the opposing nanowire side (“tail”) behaves as discontinuous nanophases. Due to this Janus film structure, its head side is hydrophilic but its tail side is hydrophobic; its head side reflects light like bulk gold, yet its tail side is a broadband superabsorber; its tail side is less conductive but with tunable resistance. More importantly, the elastomer-bonded Janus film exhibits unusual mechatronic properties when being stretched, bent, and pressed. The tail-bonded elastomeric sheet can be stretched up to ∼800% strain while remaining conductive, which is about 10-fold that of head-bonded film. In addition, it is also more sensitive to bending forces and point loads than the corresponding tail-bonded film. We further demonstrate the versatility of nanowire-based Janus films for pressure sensors using bilayer structures in three different assembly layouts.

Original language	English
Pages (from-to)	8717-8722
Number of pages	6
Journal	ACS Nano
Volume	12
Issue number	8
DOIs	https://doi.org/10.1021/acsnano.8b04748
State	Published - 28 Aug 2018
Externally published	Yes

Keywords

Gold nanowire
Janus property
Metallic Janus film
Soft electronics
Stretchable

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10.1021/acsnano.8b04748

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title = "Unconventional janus properties of enokitake-like gold nanowire films",

abstract = "We report on unconventional Janus material properties of vertically aligned gold nanowire films that conduct electricity and interact with light and water in drastically different ways on its two opposing sides. These Janus-like properties originate from enokitake-like nanowire structures, causing the nanoparticle side (“head”) to behave like bulk gold, yet the opposing nanowire side (“tail”) behaves as discontinuous nanophases. Due to this Janus film structure, its head side is hydrophilic but its tail side is hydrophobic; its head side reflects light like bulk gold, yet its tail side is a broadband superabsorber; its tail side is less conductive but with tunable resistance. More importantly, the elastomer-bonded Janus film exhibits unusual mechatronic properties when being stretched, bent, and pressed. The tail-bonded elastomeric sheet can be stretched up to ∼800% strain while remaining conductive, which is about 10-fold that of head-bonded film. In addition, it is also more sensitive to bending forces and point loads than the corresponding tail-bonded film. We further demonstrate the versatility of nanowire-based Janus films for pressure sensors using bilayer structures in three different assembly layouts.",

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author = "Wenlong Cheng and Yan Wang and Shu Gong and Daniel G{\'o}mez and Yunzhi Ling and Yap, {Lim Wei} and Simon, {George P.}",

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AU - Gong, Shu

AU - Gómez, Daniel

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AU - Yap, Lim Wei

AU - Simon, George P.

PY - 2018/8/28

Y1 - 2018/8/28

N2 - We report on unconventional Janus material properties of vertically aligned gold nanowire films that conduct electricity and interact with light and water in drastically different ways on its two opposing sides. These Janus-like properties originate from enokitake-like nanowire structures, causing the nanoparticle side (“head”) to behave like bulk gold, yet the opposing nanowire side (“tail”) behaves as discontinuous nanophases. Due to this Janus film structure, its head side is hydrophilic but its tail side is hydrophobic; its head side reflects light like bulk gold, yet its tail side is a broadband superabsorber; its tail side is less conductive but with tunable resistance. More importantly, the elastomer-bonded Janus film exhibits unusual mechatronic properties when being stretched, bent, and pressed. The tail-bonded elastomeric sheet can be stretched up to ∼800% strain while remaining conductive, which is about 10-fold that of head-bonded film. In addition, it is also more sensitive to bending forces and point loads than the corresponding tail-bonded film. We further demonstrate the versatility of nanowire-based Janus films for pressure sensors using bilayer structures in three different assembly layouts.

AB - We report on unconventional Janus material properties of vertically aligned gold nanowire films that conduct electricity and interact with light and water in drastically different ways on its two opposing sides. These Janus-like properties originate from enokitake-like nanowire structures, causing the nanoparticle side (“head”) to behave like bulk gold, yet the opposing nanowire side (“tail”) behaves as discontinuous nanophases. Due to this Janus film structure, its head side is hydrophilic but its tail side is hydrophobic; its head side reflects light like bulk gold, yet its tail side is a broadband superabsorber; its tail side is less conductive but with tunable resistance. More importantly, the elastomer-bonded Janus film exhibits unusual mechatronic properties when being stretched, bent, and pressed. The tail-bonded elastomeric sheet can be stretched up to ∼800% strain while remaining conductive, which is about 10-fold that of head-bonded film. In addition, it is also more sensitive to bending forces and point loads than the corresponding tail-bonded film. We further demonstrate the versatility of nanowire-based Janus films for pressure sensors using bilayer structures in three different assembly layouts.

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Unconventional janus properties of enokitake-like gold nanowire films

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Keywords

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