TY - JOUR
T1 - Hierarchical Graphene-Dye Bilayers for Multimodal Optoelectronic Sensing and Decoupling of Complex Stimuli
AU - Khatib, Muhammad
AU - Rapoport, Shelley
AU - Zohar, Orr
AU - Mansour, Elias
AU - Zheng, Youbin
AU - Tang, Ning
AU - Saliba, Walaa
AU - Mulytin, Yana
AU - Huynh, Tan-Phat
AU - Haick, Hossam
N1 - Funding Information:
This research received funding from the Phase‐II Grand Challenges Explorations award of the Bill and Melinda Gates Foundation (OPP1109493) and Horizon 2020 ICT grant under the A‐Patch project. National Institute of Health Research UK.
Publisher Copyright:
© 2022 The Authors. Advanced Materials Technologies published by Wiley-VCH GmbH.
PY - 2022/8
Y1 - 2022/8
N2 - Signals obtained by chemical or calorimetric sensors are highly coupled and complex, making it very challenging to precisely detect and discriminate between simultaneous stimuli. The development of sensors that provide multiple sensory outputs is a good way to tackle such a long-lasting challenge. Herein, a new design of multimodal sensors capable of generating both colorimetric and electrical sensory outputs is introduced. This is achieved by coupling two functional nanolayers, graphene (electrically active) and dyes (colorimetric) in which each layer can work either autonomously or in conjugation with the other sensing layer. It is shown that the interfacial interaction of graphene with the wide variety of dyes creates unique interfacial sensing sites for the detection of chemicals. This endows each sensor or sensor array, in the format of (opto)electronic nose, with a “fingerprint” of varying bonding possibilities, enlarging the spectrum of gas–sensor interactions. Furthermore, it is shown that the hierarchical nanobilayer structure allows the separation and discrimination of volatile organic compounds (VOCs) based on their diffusion kinetics. Taken together, the bilayer design qualifies as a superior sensor compared to unimodal devices by offering improved detection limits, wider dynamic ranges, and higher sensitivity and selectivity in the binary discrimination of a wide range of stimuli (temperature, relative humidity, and VOCs).
AB - Signals obtained by chemical or calorimetric sensors are highly coupled and complex, making it very challenging to precisely detect and discriminate between simultaneous stimuli. The development of sensors that provide multiple sensory outputs is a good way to tackle such a long-lasting challenge. Herein, a new design of multimodal sensors capable of generating both colorimetric and electrical sensory outputs is introduced. This is achieved by coupling two functional nanolayers, graphene (electrically active) and dyes (colorimetric) in which each layer can work either autonomously or in conjugation with the other sensing layer. It is shown that the interfacial interaction of graphene with the wide variety of dyes creates unique interfacial sensing sites for the detection of chemicals. This endows each sensor or sensor array, in the format of (opto)electronic nose, with a “fingerprint” of varying bonding possibilities, enlarging the spectrum of gas–sensor interactions. Furthermore, it is shown that the hierarchical nanobilayer structure allows the separation and discrimination of volatile organic compounds (VOCs) based on their diffusion kinetics. Taken together, the bilayer design qualifies as a superior sensor compared to unimodal devices by offering improved detection limits, wider dynamic ranges, and higher sensitivity and selectivity in the binary discrimination of a wide range of stimuli (temperature, relative humidity, and VOCs).
KW - chemical sensor
KW - colorimetric sensor
KW - graphene
KW - multifunctional
KW - multimodal
UR - http://www.scopus.com/inward/record.url?scp=85135893690&partnerID=8YFLogxK
U2 - 10.1002/admt.202200920
DO - 10.1002/admt.202200920
M3 - Article
AN - SCOPUS:85135893690
SN - 2365-709X
JO - Advanced Materials Technologies
JF - Advanced Materials Technologies
ER -