Laser-Deposited Carbon Aerogel Derived from Graphene Oxide Enables NO2-Selective Parts-per-Billion Sensing

Sebastian Nufer; Peter J. Lynch; Matthew J. Large; Sean P. Ogilvie; Jonathan P. Salvage; Mario Pelaez-Fernandez; Thomas Waters; Izabela Jurewicz; Edgar Muñoz; Raul Arenal; Ana M. Benito; Wolfgang K. Maser; Nikos Tagmatarchis; Christopher P. Ewels; Adam Brunton; Alan B. Dalton

doi:10.1021/acsami.0c09112

Laser-Deposited Carbon Aerogel Derived from Graphene Oxide Enables NO₂-Selective Parts-per-Billion Sensing

Sebastian Nufer, Peter J. Lynch, Matthew J. Large, Sean P. Ogilvie, Jonathan P. Salvage, Mario Pelaez-Fernandez, Thomas Waters, Izabela Jurewicz, Edgar Muñoz, Raul Arenal, Ana M. Benito, Wolfgang K. Maser, Nikos Tagmatarchis, Christopher P. Ewels, Adam Brunton, Alan B. Dalton

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

Abstract

Laser-deposited carbon aerogel is a low-density porous network of carbon clusters synthesized using a laser process. A one-step synthesis, involving deposition and annealing, results in the formation of a thin porous conductive film which can be applied as a chemiresistor. This material is sensitive to NO2 compared to ammonia and other volatile organic compounds and is able to detect ultra-low concentrations down to at least 10 parts-per-billion. The sensing mechanism, based on the solubility of NO2 in the water layer adsorbed on the aerogel, increases the usability of the sensor in practically relevant ambient environments. A heating step, achieved in tandem with a microheater, allows the recovery to the baseline, making it operable in real world environments. This, in combination with its low cost and scalable production, makes it promising for Internet-of-Things air quality monitoring.

Original language	English
Pages (from-to)	39541-39548
Number of pages	8
Journal	ACS Applied Materials and Interfaces
Volume	12
Issue number	35
DOIs	https://doi.org/10.1021/acsami.0c09112
Publication status	Published - 22 Jul 2020

Keywords

carbon aerogel
chemiresistor
gas sensor
nitrogen dioxide
selective
Scanning electron microscopy
SEM

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ACS-AMI-accepted-JPS-2020Accepted author manuscript, 994 KB

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Nufer, S., Lynch, P. J., Large, M. J., Ogilvie, S. P., Salvage, J. P., Pelaez-Fernandez, M., Waters, T., Jurewicz, I., Muñoz, E., Arenal, R., Benito, A. M., Maser, W. K., Tagmatarchis, N., Ewels, C. P., Brunton, A., & Dalton, A. B. (2020). Laser-Deposited Carbon Aerogel Derived from Graphene Oxide Enables NO₂-Selective Parts-per-Billion Sensing. ACS Applied Materials and Interfaces, 12(35), 39541-39548. https://doi.org/10.1021/acsami.0c09112

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title = "Laser-Deposited Carbon Aerogel Derived from Graphene Oxide Enables NO2-Selective Parts-per-Billion Sensing",

abstract = "Laser-deposited carbon aerogel is a low-density porous network of carbon clusters synthesized using a laser process. A one-step synthesis, involving deposition and annealing, results in the formation of a thin porous conductive film which can be applied as a chemiresistor. This material is sensitive to NO2 compared to ammonia and other volatile organic compounds and is able to detect ultra-low concentrations down to at least 10 parts-per-billion. The sensing mechanism, based on the solubility of NO2 in the water layer adsorbed on the aerogel, increases the usability of the sensor in practically relevant ambient environments. A heating step, achieved in tandem with a microheater, allows the recovery to the baseline, making it operable in real world environments. This, in combination with its low cost and scalable production, makes it promising for Internet-of-Things air quality monitoring.",

keywords = "carbon aerogel, chemiresistor, gas sensor, nitrogen dioxide, selective, Scanning electron microscopy, SEM",

author = "Sebastian Nufer and Lynch, {Peter J.} and Large, {Matthew J.} and Ogilvie, {Sean P.} and Salvage, {Jonathan P.} and Mario Pelaez-Fernandez and Thomas Waters and Izabela Jurewicz and Edgar Mu{\~n}oz and Raul Arenal and Benito, {Ana M.} and Maser, {Wolfgang K.} and Nikos Tagmatarchis and Ewels, {Christopher P.} and Adam Brunton and Dalton, {Alan B.}",

year = "2020",

month = jul,

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doi = "10.1021/acsami.0c09112",

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Nufer, S, Lynch, PJ, Large, MJ, Ogilvie, SP, Salvage, JP, Pelaez-Fernandez, M, Waters, T, Jurewicz, I, Muñoz, E, Arenal, R, Benito, AM, Maser, WK, Tagmatarchis, N, Ewels, CP, Brunton, A & Dalton, AB 2020, 'Laser-Deposited Carbon Aerogel Derived from Graphene Oxide Enables NO₂-Selective Parts-per-Billion Sensing', ACS Applied Materials and Interfaces, vol. 12, no. 35, pp. 39541-39548. https://doi.org/10.1021/acsami.0c09112

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T1 - Laser-Deposited Carbon Aerogel Derived from Graphene Oxide Enables NO2-Selective Parts-per-Billion Sensing

AU - Nufer, Sebastian

AU - Lynch, Peter J.

AU - Large, Matthew J.

AU - Ogilvie, Sean P.

AU - Salvage, Jonathan P.

AU - Pelaez-Fernandez, Mario

AU - Waters, Thomas

AU - Jurewicz, Izabela

AU - Muñoz, Edgar

AU - Arenal, Raul

AU - Benito, Ana M.

AU - Maser, Wolfgang K.

AU - Tagmatarchis, Nikos

AU - Ewels, Christopher P.

AU - Brunton, Adam

AU - Dalton, Alan B.

PY - 2020/7/22

Y1 - 2020/7/22

N2 - Laser-deposited carbon aerogel is a low-density porous network of carbon clusters synthesized using a laser process. A one-step synthesis, involving deposition and annealing, results in the formation of a thin porous conductive film which can be applied as a chemiresistor. This material is sensitive to NO2 compared to ammonia and other volatile organic compounds and is able to detect ultra-low concentrations down to at least 10 parts-per-billion. The sensing mechanism, based on the solubility of NO2 in the water layer adsorbed on the aerogel, increases the usability of the sensor in practically relevant ambient environments. A heating step, achieved in tandem with a microheater, allows the recovery to the baseline, making it operable in real world environments. This, in combination with its low cost and scalable production, makes it promising for Internet-of-Things air quality monitoring.

AB - Laser-deposited carbon aerogel is a low-density porous network of carbon clusters synthesized using a laser process. A one-step synthesis, involving deposition and annealing, results in the formation of a thin porous conductive film which can be applied as a chemiresistor. This material is sensitive to NO2 compared to ammonia and other volatile organic compounds and is able to detect ultra-low concentrations down to at least 10 parts-per-billion. The sensing mechanism, based on the solubility of NO2 in the water layer adsorbed on the aerogel, increases the usability of the sensor in practically relevant ambient environments. A heating step, achieved in tandem with a microheater, allows the recovery to the baseline, making it operable in real world environments. This, in combination with its low cost and scalable production, makes it promising for Internet-of-Things air quality monitoring.

KW - carbon aerogel

KW - chemiresistor

KW - gas sensor

KW - nitrogen dioxide

KW - selective

KW - Scanning electron microscopy

KW - SEM

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EP - 39548

JO - ACS Applied Materials and Interfaces

JF - ACS Applied Materials and Interfaces

SN - 1944-8244

IS - 35

ER -

Laser-Deposited Carbon Aerogel Derived from Graphene Oxide Enables NO₂-Selective Parts-per-Billion Sensing

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Keywords

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