Probing the highly efficient room temperature ammonia gas sensing properties of a luminescent ZnO nanowire array prepared via an AAO-assisted template route

Kumar, Narendra; Srivastava, Arvind K.; Nath, R.; Gupta, Bipin Kumar; Varma, G. D.

doi:10.1039/c3dt53305k

Cited by 51 publications

(22 citation statements)

References 56 publications

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“…The sensitization mechanism for most of the semiconducting metal oxides works on the principle of changing the conductivity of the sensor materials due to the interaction between the gas and the oxygen ions adsorbed on the surface ( -O 2 , O -, O 2-), which appears when the sensor is exposed to atmospheric oxygen. This leads to the formation of an area of depletion as a result of extracting electrons from the conduction band, thus increasing the barrier of sensor and thereby increasing the sensor resistance [18]. When the sensor is exposed to ammonia gas (NH 3 ), the gas reacts with oxygen ions and the electrons are released to the conduction band, which leads to a decrease in the electrical resistance of the sensor, according to the following equations [19]:…”

Section: -3 Gas Sensor Characteristicsmentioning

confidence: 99%

Preparation and Characterization of In2O3-CuO Nanocomposite Thin Films as NH3 Gas Sensor

Hameed

AL-Jumaili

2021

eijs

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An NH3 gas sensor was prepared from nanocomposite films of indium oxide-copper oxide mixtures with ratios of 0 , 10 , and 20 Vol % of copper oxide. The films were deposited on a glass substrate using chemical spray pyrolysis method (CSP) at 400oC. The structural properties were studied by using X-ray diffraction (XRD) and atomic force microscopy ( AFM). The structural results showed that the prepared thin films are polycrystalline, with nano grain size. By mixing copper oxide with indium oxide, the grain size of the prepared thin films was decreased and the surface roughness was increased. The UV-Visible spectrometer analysis showed that the prepared thin films have high transmittance. This transmittance was decreased by mixing copper oxide with indium oxide. The direct optical energy gap ranged 3.5 - 3 eV, which was decreased with increasing copper oxide concentration. The sensitivity of the prepared gas sensor was measured towards NH3 gas at a concentration of 71ppm with operating temperatures of 100, 150, 200, 250 and 30) oC, according to the change of sensor resistance. This sensitivity of the mixture oxides showed a value of about nine times greater than that of individual indium oxide thin films. The results of the optimum gas sensor properties demonstrated a sensitivity value of 75.06%, response time of 10s, and recovery time of 11 s, at a mixing ratio of 20% of copper oxide and an operating temperature of 200oC.

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Section: -3 Gas Sensor Characteristicsmentioning

confidence: 99%

Preparation and Characterization of In2O3-CuO Nanocomposite Thin Films as NH3 Gas Sensor

Hameed

AL-Jumaili

2021

eijs

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“…When the SnO 2 is exposed to air at room temperature, oxygen molecules on the surface capture electrons 90 from the conduction band of SnO 2 , and electrons divert from the oxygen vacancies of SnO 2 to the oxygen molecule form more chemisorbed oxygen species O 2 in the surface. [68][69][70] The reactions of eqs 1-3 take place on the surface of SnO 2 as follows: (3) wherein V O is oxygen vacancy, and V O · · · · is single electropositive oxygen vacancy. It has been reported that higher oxygen vacancy density would induce more surface absorbed oxygen species.…”

Section: Sensing Mechanismmentioning

confidence: 99%

Role of the heterojunctions in In₂O₃-composite SnO₂nanorod sensors and their remarkable gas-sensing performance for NO_xat room temperature

et al. 2015

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Establishing heterostructures, as a good strategy to improve gas sensing performance, has been studied extensively. In this research, In2O3-composite SnO2 nanorod (ICTOs) heterostructures have been prepared via electrospinning, followed by calcination. It is found that In2O3 can improve the carrier density and oxygen deficiency of SnO2. In particular, the 3ICTO (Sn : In atom ratio of 25 : 0.3) nanorods with special particle distributions show an excellent sensing response towards different concentrations of NOx at room temperature. The highest sensing response is up to 8.98 for 100 ppm NOx with a fast response time of 4.67 s, which is over 11 times higher than that of pristine SnO2 nanorods at room temperature and the lowest detection limit is down to 0.1 ppm. More significantly, it presents good stability after 30 days for NOx of low concentration (0.1 ppm and 0.5 ppm). In addition, the rational band structure model combined with the surface depletion model which describe the NOx gas sensing mechanism of 3ICTO are presented. The 3ICTO nanorods may be promising in the application of gas sensors.

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“…Increasing the concentration of ammonia in air causes severe adverse effects in the human respiratory system, eyes and skin. Over the past decade, several techniques for the detection of NH3have been reported based on measurements of electrical current in nano structured metal oxides [3], conducting polymers [4], carbon nanotubes [5] and nano structured graphene [6].Optical fiber based sensors have some unique advantages over their electrical analogues such as remote and real time monitoring, immunity to various sources of disturbance such as electromagnetic interference, radioactivity, and explosive environments. Amongst the optical fiber techniques, sensors based on the whispering gallery modes (WGMs) in spherical microresonators have found many applications in the fields of molecular adsorption [7],refractive index [8],temperature [8] and gas sensing [9] due to their ultra-high quality factors, low absorption losses and inexpensive fabrication.…”

Section: Introductionmentioning

confidence: 99%

Porous silica coated spherical microresonator for vapor phase sensing of ammonia at a sub-ppm level

Mallik¹,

Farrell²,

Liu³

et al. 2016

SPIE Proceedings

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A new type of fiber optic sensor for the detection and quantification of ammonia (NH3) vapor levels is proposed and experimentally demonstrated. This sensor is based on a spherical silica micro resonator coated with porous silica gel. Whispering gallery modes (WGMs) in the micro resonator are excited by evanescent coupling to a tapered fiber with a 3.3 µm waist diameter. The optical properties of the porous silica layer change when it is exposed to ammonia vapor, leading to a spectral shift of the WGM resonant wavelengths. The sensitivity of the proposed sensor has been tested by exposing it to different low level concentrations of ammonia: 4 ppm, 8 ppm, 12 ppm and 30 ppm at a constant relative humidity (50% RH) and constant temperature (23  C). The detection limit is calculated from experimental results as 57 ppb of ammonia for a 282 µm diameter porous silica coated microsphere.

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Probing the highly efficient room temperature ammonia gas sensing properties of a luminescent ZnO nanowire array prepared via an AAO-assisted template route

Cited by 51 publications

References 56 publications

Preparation and Characterization of In2O3-CuO Nanocomposite Thin Films as NH3 Gas Sensor

Preparation and Characterization of In2O3-CuO Nanocomposite Thin Films as NH3 Gas Sensor

Role of the heterojunctions in In₂O₃-composite SnO₂nanorod sensors and their remarkable gas-sensing performance for NO_xat room temperature

Porous silica coated spherical microresonator for vapor phase sensing of ammonia at a sub-ppm level

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Probing the highly efficient room temperature ammonia gas sensing properties of a luminescent ZnO nanowire array prepared via an AAO-assisted template route

Cited by 51 publications

References 56 publications

Preparation and Characterization of In2O3-CuO Nanocomposite Thin Films as NH3 Gas Sensor

Preparation and Characterization of In2O3-CuO Nanocomposite Thin Films as NH3 Gas Sensor

Role of the heterojunctions in In2O3-composite SnO2nanorod sensors and their remarkable gas-sensing performance for NOxat room temperature

Porous silica coated spherical microresonator for vapor phase sensing of ammonia at a sub-ppm level

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Role of the heterojunctions in In₂O₃-composite SnO₂nanorod sensors and their remarkable gas-sensing performance for NO_xat room temperature