RF sputtered SnO2: NiO thin films as sub-ppm H2S sensor operable at room temperature

•SnO2:NiO films exhibit an enhanced sensor response towards H2S (440 towards 10ppm) at room temperature.•Sensor response exhibited by SnO2:NiO films is 9 and 415 times greater than that exhibited by pure SnO2 and NiO films, respectively.•SnO2:NiO films detect as low as100ppb of H2S with a high senso...

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Bibliographic Details
Published in:Sensors and actuators. B, Chemical Chemical, 2017-04, Vol.242, p.389-403
Main Authors: Kaur, Manmeet, Dadhich, Bhavesh Kumar, Singh, Ranjit, KailasaGanapathi, Bagwaiya, Toshi, Bhattacharya, S., Debnath, A.K., Muthe, K.P., Gadkari, S.C.
Format: Article
Language:English
Subjects:
Chemical reactions
Diffraction
Gas detectors
Gas sensors
H2S sensors
Hydrogen sulfide
Low concentrations
Nickel oxides
Nickel sulfide
NiO
Organic chemistry
Oxidation
P-n junctions
Pollutants
Room temperature
Scanning electron microscopy
SnO2
Thin films
Tin dioxide
Viability
X ray photoelectron spectroscopy
X-ray diffraction
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Summary:•SnO2:NiO films exhibit an enhanced sensor response towards H2S (440 towards 10ppm) at room temperature.•Sensor response exhibited by SnO2:NiO films is 9 and 415 times greater than that exhibited by pure SnO2 and NiO films, respectively.•SnO2:NiO films detect as low as100ppb of H2S with a high sensor response of 16.5. A room temperature sub-ppm H2S sensor based on RF sputtered SnO2: NiO thin film has been demonstrated. For this, SnO2 thin films have been modified with ultrathin layers (30nm) of NiO. These films were characterized using Scanning electron Microsopy (SEM), X-ray diffraction (XRD) and X-ray photoelectron spectroscopy (XPS). Gas sensing properties of these films were systematically investigated and compared with those of pure SnO2 and NiO films. Sensing studies revealed that these films are highly sensitive to H2S at room temperature. The sensor response exhibited by NiO modified SnO2 film, is 9 and 415 times greater than that exhibited by pure SnO2 and NiO films, respectively. The sensor response in case of SnO2:NiO is due to contribution from two different mechanisms- (i) oxidation reaction between adsorbed oxygen and H2S and (ii) destruction of p-n junctions due to conversion of Nickel Oxide to metallic Nickel Sulphide (product of chemical reaction between NiO and H2S). Presence of XPS sulphide peaks at binding energies of ∼163eV corresponding to S-2p3/2 and S-2p1/2, on H2S exposure confirms the formation of Nickel Sulphide. Present experiments proved the ability of these films to detect low concentrations of H2S i.e. parts per billion reproducibly. These films were also found to be stable for extended period of time, hinting at commercial viability of the sensor.
ISSN:0925-4005
1873-3077
DOI:10.1016/j.snb.2016.11.054