Organic switches for surfaces and devices

Albert C Fahrenbach; Scott C Warren; Jared T Incorvati; Alyssa-Jennifer Avestro; Jonathan C Barnes; J Fraser Stoddart; Bartosz A Grzybowski

doi:10.1002/adma.201201912

Organic switches for surfaces and devices

Albert C Fahrenbach, Scott C Warren, Jared T Incorvati, Alyssa-Jennifer Avestro, Jonathan C Barnes, J Fraser Stoddart, Bartosz A Grzybowski

Chemistry

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

Abstract

The pursuit to achieve miniaturization has tantalized researchers across the fields of chemistry, physics, biology, materials science and engineering for over half a century because of its many alluring potential applications. As alternatives to traditional "top-down" manufacturing, "bottom-up" approaches, originating from the (supra)molecular level, have enabled researchers to develop switches which can be manipulated on surfaces at nanoscale dimensions with deft precision using simple external triggers. Once on surfaces, these organic switches have been shown to modulate both the physical and chemical surface properties. In this Progress Report, we shed light on recent advances made in our laboratories towards integrated systems using all-organic switches on a variety of substrates. Design concepts are revealed, as well as the overall impact of all-organic switches on the properties of their substrates, while emphasizing the considerable promise and formidable challenges these advanced composite materials pose when it comes to conferring function on them.

Original language	English
Pages (from-to)	331-48
Number of pages	18
Journal	Advanced Materials
Volume	25
Issue number	3
DOIs	https://doi.org/10.1002/adma.201201912
Publication status	Published - 18 Jan 2013

Keywords

Electrical Equipment and Supplies
Mechanical Phenomena
Metal Nanoparticles/chemistry
Organic Chemicals/chemistry
Silicon Dioxide/chemistry
Surface Properties

Access to Document

10.1002/adma.201201912

Cite this

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title = "Organic switches for surfaces and devices",

abstract = "The pursuit to achieve miniaturization has tantalized researchers across the fields of chemistry, physics, biology, materials science and engineering for over half a century because of its many alluring potential applications. As alternatives to traditional {"}top-down{"} manufacturing, {"}bottom-up{"} approaches, originating from the (supra)molecular level, have enabled researchers to develop switches which can be manipulated on surfaces at nanoscale dimensions with deft precision using simple external triggers. Once on surfaces, these organic switches have been shown to modulate both the physical and chemical surface properties. In this Progress Report, we shed light on recent advances made in our laboratories towards integrated systems using all-organic switches on a variety of substrates. Design concepts are revealed, as well as the overall impact of all-organic switches on the properties of their substrates, while emphasizing the considerable promise and formidable challenges these advanced composite materials pose when it comes to conferring function on them.",

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author = "Fahrenbach, {Albert C} and Warren, {Scott C} and Incorvati, {Jared T} and Alyssa-Jennifer Avestro and Barnes, {Jonathan C} and Stoddart, {J Fraser} and Grzybowski, {Bartosz A}",

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year = "2013",

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doi = "10.1002/adma.201201912",

language = "English",

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journal = "Advanced Materials",

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T1 - Organic switches for surfaces and devices

AU - Fahrenbach, Albert C

AU - Warren, Scott C

AU - Incorvati, Jared T

AU - Avestro, Alyssa-Jennifer

AU - Barnes, Jonathan C

AU - Stoddart, J Fraser

AU - Grzybowski, Bartosz A

PY - 2013/1/18

Y1 - 2013/1/18

N2 - The pursuit to achieve miniaturization has tantalized researchers across the fields of chemistry, physics, biology, materials science and engineering for over half a century because of its many alluring potential applications. As alternatives to traditional "top-down" manufacturing, "bottom-up" approaches, originating from the (supra)molecular level, have enabled researchers to develop switches which can be manipulated on surfaces at nanoscale dimensions with deft precision using simple external triggers. Once on surfaces, these organic switches have been shown to modulate both the physical and chemical surface properties. In this Progress Report, we shed light on recent advances made in our laboratories towards integrated systems using all-organic switches on a variety of substrates. Design concepts are revealed, as well as the overall impact of all-organic switches on the properties of their substrates, while emphasizing the considerable promise and formidable challenges these advanced composite materials pose when it comes to conferring function on them.

AB - The pursuit to achieve miniaturization has tantalized researchers across the fields of chemistry, physics, biology, materials science and engineering for over half a century because of its many alluring potential applications. As alternatives to traditional "top-down" manufacturing, "bottom-up" approaches, originating from the (supra)molecular level, have enabled researchers to develop switches which can be manipulated on surfaces at nanoscale dimensions with deft precision using simple external triggers. Once on surfaces, these organic switches have been shown to modulate both the physical and chemical surface properties. In this Progress Report, we shed light on recent advances made in our laboratories towards integrated systems using all-organic switches on a variety of substrates. Design concepts are revealed, as well as the overall impact of all-organic switches on the properties of their substrates, while emphasizing the considerable promise and formidable challenges these advanced composite materials pose when it comes to conferring function on them.

KW - Electrical Equipment and Supplies

KW - Mechanical Phenomena

KW - Metal Nanoparticles/chemistry

KW - Organic Chemicals/chemistry

KW - Silicon Dioxide/chemistry

KW - Surface Properties

U2 - 10.1002/adma.201201912

DO - 10.1002/adma.201201912

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EP - 348

JO - Advanced Materials

JF - Advanced Materials

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