Field-Structured Chemiresistors

Field-Structured Chemiresistors

A significantly improved material is developed for application to chemiresistors, which are resistance‐based sensors for volatile organic compounds. This material is a polymer composite containing Au‐coated magnetic particles organized into electrically conducting pathways by magnetic fields. This i...

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Veröffentlicht in:Advanced functional materials 2010-05, Vol.20 (10), p.1577-1584
Hauptverfasser: Read, Douglas H., Martin, James E.
Format: Artikel
Sprache:eng
Schlagworte:
Amplification
chemical switches
composite materials
Conducting polymers
Conductors (devices)
Devices
Gold coatings
Logic circuits
Magnetic fields
magnetic materials
Materials science
Particulate composites
Polymer matrix composites
Polymers
Sensor arrays
Sensors
Stress concentration
structure-property relationships
Switches
VOCs
Volatile organic compounds
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container_end_page 1584
container_issue 10
container_start_page 1577
container_title Advanced functional materials
container_volume 20
creator Read, Douglas H.
Martin, James E.
description A significantly improved material is developed for application to chemiresistors, which are resistance‐based sensors for volatile organic compounds. This material is a polymer composite containing Au‐coated magnetic particles organized into electrically conducting pathways by magnetic fields. This improved material overcomes the various problems inherent to conventional carbon‐black chemiresistors, while achieving an unprecedented response magnitude. When exposed to chemical vapors, the polymer swells only slightly, yet this is amplified into large, reversible resistance changes, as much as (1 × 1011)% at a swelling of only 1.5%. These conductor–insulator transitions occur over such a narrow range of analyte vapor concentration that these devices can be described as chemical switches. The sensitivity and response range of these sensors can be tailored over a wide range by controlling the stress within the composite, including through the application of a magnetic field. Such tailorable sensors can be used to create sensor arrays that can accurately determine analyte concentration over a broad concentration range, or can be used to create logic circuits that signal a particular chemical environment. Polymer composites containing Au‐coated magnetic particles that are organized into electrically conducting pathways using magnetic fields are successfully used as chemiresistors. Absorption of chemical vapors elicits a reversible increase in the chemiresistor resistance. These sensors undergo a conductor–insulator transition over such a narrow concentration range that they can be described as chemical switches.
doi_str_mv 10.1002/adfm.200902286
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This material is a polymer composite containing Au‐coated magnetic particles organized into electrically conducting pathways by magnetic fields. This improved material overcomes the various problems inherent to conventional carbon‐black chemiresistors, while achieving an unprecedented response magnitude. When exposed to chemical vapors, the polymer swells only slightly, yet this is amplified into large, reversible resistance changes, as much as (1 × 1011)% at a swelling of only 1.5%. These conductor–insulator transitions occur over such a narrow range of analyte vapor concentration that these devices can be described as chemical switches. The sensitivity and response range of these sensors can be tailored over a wide range by controlling the stress within the composite, including through the application of a magnetic field. Such tailorable sensors can be used to create sensor arrays that can accurately determine analyte concentration over a broad concentration range, or can be used to create logic circuits that signal a particular chemical environment. Polymer composites containing Au‐coated magnetic particles that are organized into electrically conducting pathways using magnetic fields are successfully used as chemiresistors. Absorption of chemical vapors elicits a reversible increase in the chemiresistor resistance. 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source Wiley Online Library All Journals
subjects Amplification
chemical switches
composite materials
Conducting polymers
Conductors (devices)
Devices
Gold coatings
Logic circuits
Magnetic fields
magnetic materials
Materials science
Particulate composites
Polymer matrix composites
Polymers
Sensor arrays
Sensors
Stress concentration
structure-property relationships
Switches
VOCs
Volatile organic compounds
title Field-Structured Chemiresistors
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