TY - JOUR
T1 - Engineering of SnO2-Graphene Oxide Nanoheterojunctions for Selective Room-Temperature Chemical Sensing and Optoelectronic Devices
AU - Pargoletti, Eleonora
AU - Hossain, Umme H.
AU - Di Bernardo, Iolanda
AU - Chen, Hongjun
AU - Tran-Phu, Thanh
AU - Chiarello, Gian Luca
AU - Lipton-Duffin, Josh
AU - Pifferi, Valentina
AU - Tricoli, Antonio
AU - Cappelletti, Giuseppe
N1 - Publisher Copyright:
© 2020 American Chemical Society.
PY - 2020/9/2
Y1 - 2020/9/2
N2 - The development of high-performing sensing materials, able to detect ppb-trace concentrations of volatile organic compounds (VOCs) at low temperatures, is required for the development of next-generation miniaturized wireless sensors. Here, we present the engineering of selective room-temperature (RT) chemical sensors, comprising highly porous tin dioxide (SnO2)-graphene oxide (GO) nanoheterojunction layouts. The optoelectronic and chemical properties of these highly porous (>90%) p-n heterojunctions were systematically investigated in terms of composition and morphologies. Optimized SnO2-GO layouts demonstrate significant potential as both visible-blind photodetectors and selective RT chemical sensors. Notably, a low GO content results in an excellent UV light responsivity (400 A W-1), with short rise and decay times, and RT high chemical sensitivity with selective detection of VOCs such as ethanol down to 100 ppb. In contrast, a high concentration of GO drastically decreases the RT response to ethanol and results in good selectivity to ethylbenzene. The feasibility of tuning the chemical selectivity of sensor response by engineering the relative amount of GO and SnO2 is a promising feature that may guide the future development of miniaturized solid-state gas sensors. Furthermore, the excellent optoelectronic properties of these SnO2-GO nanoheterojunctions may find applications in various other areas such as optoelectronic devices and (photo)electrocatalysis.
AB - The development of high-performing sensing materials, able to detect ppb-trace concentrations of volatile organic compounds (VOCs) at low temperatures, is required for the development of next-generation miniaturized wireless sensors. Here, we present the engineering of selective room-temperature (RT) chemical sensors, comprising highly porous tin dioxide (SnO2)-graphene oxide (GO) nanoheterojunction layouts. The optoelectronic and chemical properties of these highly porous (>90%) p-n heterojunctions were systematically investigated in terms of composition and morphologies. Optimized SnO2-GO layouts demonstrate significant potential as both visible-blind photodetectors and selective RT chemical sensors. Notably, a low GO content results in an excellent UV light responsivity (400 A W-1), with short rise and decay times, and RT high chemical sensitivity with selective detection of VOCs such as ethanol down to 100 ppb. In contrast, a high concentration of GO drastically decreases the RT response to ethanol and results in good selectivity to ethylbenzene. The feasibility of tuning the chemical selectivity of sensor response by engineering the relative amount of GO and SnO2 is a promising feature that may guide the future development of miniaturized solid-state gas sensors. Furthermore, the excellent optoelectronic properties of these SnO2-GO nanoheterojunctions may find applications in various other areas such as optoelectronic devices and (photo)electrocatalysis.
KW - UV photodetectors
KW - graphene oxide
KW - nanoheterojunctions
KW - room-temperature chemoresistive sensing
KW - selectivity
KW - tin dioxide
UR - http://www.scopus.com/inward/record.url?scp=85090292022&partnerID=8YFLogxK
U2 - 10.1021/acsami.0c09178
DO - 10.1021/acsami.0c09178
M3 - Article
SN - 1944-8244
VL - 12
SP - 39549
EP - 39560
JO - ACS applied materials & interfaces
JF - ACS applied materials & interfaces
IS - 35
ER -