Porous In2O3 powders prepared by ultrasonic-spray pyrolysis as a NO2-sensing material: Utilization of polymethylmethacrylate microspheres synthesized by ultrasonic-assisted emulsion polymerization as a template

Hyodo, Takeo; Furuno, Shu Ichi; Fujii, Eriko; Matsuo, Keitaro; Motokucho, Suguru; Kojio, Ken; Shimizu, Yasuhiro

doi:10.1016/j.snb.2013.02.090

Cited by 36 publications

(12 citation statements)

References 30 publications

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“…In 2 O 3 is an n-type direct band gap semiconductor originated from the oxygen vacancies (abundance dynamic sites) present on its surface, which act as donor levels to provide free electrons to the conduction band of In 2 O 3 and hence, increases the adsorption of NO 2 [15][16][17]. So, various In 2 O 3 -based sensors have been explored for NO 2 gas sensing [18][19][20][21][22][23][24][25]. Among these sensors, few are working at high temperature and therefore, not feasible to use for gas sensing due to risk associated at high temperature [18][19][20][21].…”

Section: Introductionmentioning

confidence: 99%

Ultra-high sensitive and ultra-low NO2 detection at low-temperature based on ultrathin In2O3 nanosheets

Cao¹,

Chen²,

Cai³

et al. 2021

J Mater Sci: Mater Electron

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In this study, the high oxygen vacancy-rich ultrathin indium oxide (In 2 O 3 ) nanosheets are synthesized by low-cost and environmental-friendly solvothermal method. The gas sensing properties of In 2 O 3 nanosheets to low concentration of nitrogen dioxide (NO 2 ) (concentration in 5 ppb to 5 ppm) at 50 °C are investigated. All In 2 O 3 samples are successfully characterized using various techniques to obtain the information related to phase, morphological, oxygen vacancies, and surface area, etc. It is observed that among all the samples, the In 2 O 3 -350 exhibited benchmarked response of around 3223 at 2 ppm NO 2 gas, with theoretical detection limit down to ppb level. The sensor has shown superior sensing characteristics, such as wide sensing bandwidth, excellent selectivity, high long-term stability, and good repeatability. It is considered that the high oxygen deficiency present on In 2 O 3 nanosheets acts as favorable reaction sites for such remarkable sensing performance, and therefore, these improved gas-sensing properties make the In 2 O 3 nanosheets suitable to detect NO 2 at low-temperature.

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Section: Introductionmentioning

confidence: 99%

Ultra-high sensitive and ultra-low NO2 detection at low-temperature based on ultrathin In2O3 nanosheets

Cao¹,

Chen²,

Cai³

et al. 2021

J Mater Sci: Mater Electron

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“…70 nm) by ultrasonic-assisted emulsion polymerization technique using an appropriate amount of methyl methacrylate monomer and sodium lauryl sulfate (SLS) as a surfactant. The fabricated sensors using the In 2 O 3 powders fabricated by ultrasonic spray pyrolysis employing the smaller PMMA microspheres as a template in a precursor solution largely enhanced the NO 2 response [36,37]. Table 1 summarizes typical examples of NO 2 detection using In 2 O 3 -based gas sensors [17][18][19][20][21][22][23][24][25][26]38].…”

Section: Introductionmentioning

confidence: 99%

Enhanced NO2-Sensing Properties of Au-Loaded Porous In2O3 Gas Sensors at Low Operating Temperatures

et al. 2020

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NO2-sensing properties of semiconductor gas sensors using porous In2O3 powders loaded with and without 0.5 wt% Au (Au/In2O3 and In2O3 sensors, respectively) were examined in wet air (70% relative humidity at 25 °C). In addition, the effects of Au loading on the increased NO2 response were discussed on the basis of NO2 adsorption/desorption properties on the oxide surface. The NO2 response of the Au/In2O3 sensor monotonically increased with a decrease in the operating temperature, and the Au/In2O3 sensor showed higher NO2 responses than those of the In2O3 sensor at a temperature of 100 °C or lower. In addition, the response time of the Au/In2O3 sensor was much shorter than that of the In2O3 sensor at 30 °C. The analysis based on the Freundlich adsorption mechanism suggested that the Au loading increased the adsorption strength of NO2 on the In2O3 surface. Moreover, the Au loading was also quite effective in decreasing the baseline resistance of the In2O3 sensor in wet air (i.e., increasing the number of free electrons in the In2O3), which resulted in an increase in the number of negatively charged NO2 species on the In2O3 surface. The Au/In2O3 sensor showed high response to the low concentration of NO2 (ratio of resistance in target gas to that in air: ca. 133 to 0.1 ppm) and excellent NO2 selectivity against CO and ethanol, especially at 100 °C.

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“…Therefore, many researchers have reported the enhanced sensing performances by the structural modification of the sensing layer with rod-like (Wei et al, 2014;Takacs et al, 2015), plate-like (Chen et al, 2014;Guo, 2016), flower-like (Wang et al, 2014(Wang et al, , 2015, or urchin-like structured oxide (Tang et al, 2013). Our group has also studied the introduction of ordered porous structures into metal-oxide layers of semiconductor-type gas sensors to enhance their gas diffusivity and surface area during the last 20 years (Hyodo et al, 2001(Hyodo et al, , 2002(Hyodo et al, , 2003(Hyodo et al, , 2005(Hyodo et al, , 2010(Hyodo et al, , 2013(Hyodo et al, , 2017Hashimoto et al, 2008;Hieda et al, 2008;Firooz et al, 2010). For example, we synthesized mesoporous SnO 2 powders by utilizing the self-assembly of surfactants with a size of several nanometers, and their sensors showed the quite large H 2 response due to an increase in the specific surface area (Hyodo et al, 2001(Hyodo et al, , 2002(Hyodo et al, , 2003.…”

Section: Introductionmentioning

confidence: 99%

“…In addition, we also attempted the fabrication of the macroporous In 2 O 3 powders by ultrasonic spray pyrolysis employing a precursor solution containing PMMA microspheres (ps: 150 nm), and their sensors showed much larger NO 2 response and quicker NO 2 response/recovery speeds than those of the conventional In 2 O 3 sensor prepared by the similar preparation technique employing a PMMA-free In(NO 3 ) 3 aqueous solution (Hashimoto et al, 2008;Hyodo et al, 2010). Recently, we focused on the preparation of smallersized PMMA microspheres by an ultrasonic-assisted emulsion polymerization technique, and demonstrated an increase in the amount of sodium lauryl sulfate as a surfactant in the polymerization process of methyl methacrylate monomers decreased the size of the synthesized PMMA microspheres (Hyodo et al, 2013). In addition, the fabricated porous (pr-) In 2 O 3 sensor employing smaller-sized PMMA microspheres (ps: 26 nm) as a template in a precursor solution of ultrasonic spray pyrolysis was effective in improving the magnitude of NO 2 response to a low concentration of NO 2 (e.g., 1 ppm) at relatively low temperature (150 • C) (Hyodo et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Improvement in NO2 Sensing Properties of Semiconductor-Type Gas Sensors by Loading of Au Into Porous In2O3 Powders

et al. 2019

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Porous (pr-) In 2 O 3 powders loaded with and without noble metals (Au, Pd, or Pt) were prepared by ultrasonic spray pyrolysis employing the PMMA microspheres as a template (typical particle size (ps): 28 or 70 nm with a diameter), and their NO 2 sensing properties were examined. The Au loading on the pr-In 2 O 3 was effective to increase the NO 2 response at lower operating temperature (≤200 • C), while the metal loading of Pd or Pt were hardly effective. In addition, a decrease in the PMMA microspheres (from 70 to 28 nm in ps) largely increased the NO 2 response, and an optimized amount of Au loaded on the pr-In 2 O 3 sensor was 1.0 wt%. The decrease in the thickness of the sensing layer improved the NO 2 response and response speed. It was suggested that the Au loading enhanced the amount of the negatively adsorbed NO 2 on the bottom part of the sensing layer, leading to the increase in the NO 2 response. Furthermore, the introduction of additional macropores (ps: 150 nm) to the 1.0 wt% Au loaded pr-In 2 O 3 sensor increased the response to a low concentration of NO 2 (0.025 ppm) at 30 • C. Therefore, it was found that easy gas diffusion from the surface to the bottom part of the sensing layer increased the effective concentration of NO 2 , and thus the NO 2 response was increased.

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Porous In2O3 powders prepared by ultrasonic-spray pyrolysis as a NO2-sensing material: Utilization of polymethylmethacrylate microspheres synthesized by ultrasonic-assisted emulsion polymerization as a template

Cited by 36 publications

References 30 publications

Ultra-high sensitive and ultra-low NO2 detection at low-temperature based on ultrathin In2O3 nanosheets

Ultra-high sensitive and ultra-low NO2 detection at low-temperature based on ultrathin In2O3 nanosheets

Enhanced NO2-Sensing Properties of Au-Loaded Porous In2O3 Gas Sensors at Low Operating Temperatures

Improvement in NO2 Sensing Properties of Semiconductor-Type Gas Sensors by Loading of Au Into Porous In2O3 Powders

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