Basanta Bhowmik scite author profile

Oxygen vacancy (OV) controlled TiO2 nanotubes, having diameters of 50–70 nm and lengths of 200–250 nm, were synthesized by electrochemical anodization in the mixed electrolyte comprising NH4F and ethylene glycol with selective H2O content. The structural evolution of TiO2 nanoforms has been studied by field emission scanning electron microscopy. Variation in the formation of OVs with the variation of the structure of TiO2 nanoforms has been evaluated by photoluminescence and X-ray photoelectron spectroscopy. The sensor characteristics were correlated to the variation of the amount of induced OVs in the nanotubes. The efficient room temperature sensing achieved by the control of OVs of TiO2 nanotube array has paved the way for developing fast responding alcohol sensor with corresponding response magnitude of 60.2%, 45.3%, and 36.5% towards methanol, ethanol, and 2-propanol, respectively.

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Micro/nanostructured gas sensors: the physics behind the nanostructure growth, sensing and selectivity mechanisms

Chowdhury

Bhowmik

2021

Nanoscale Adv.

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Highly Selective Low-Temperature Acetone Sensor Based on Hierarchical 3-D TiO₂Nanoflowers

et al. 2016

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Stoichiometry, Length, and Wall Thickness Optimization of TiO₂ Nanotube Array for Efficient Alcohol Sensing

Hazra

Bhowmik

Dutta

et al. 2015

ACS Appl. Mater. Interfaces

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The present study concerns development of an efficient alcohol sensor by controlling the stoichiometry, length, and wall thickness of electrochemically grown TiO2 nanotube array for its use as the sensing layer. Judicious variation of H2O content (0, 2, 10 and 100% by volume) in the mixed electrolyte comprising ethylene glycol and NH4F resulted into the desired variation of stoichiometry. The sensor study was performed within the temperature range of 27 to 250 °C for detecting the alcohols in the concentration range of 10-1000 ppm. The nanotubes grown with the electrolyte containing 2 vol % H2O offered the maximum response magnitude. For this stoichiometry, variation of corresponding length (1.25-2.4 μm) and wall thickness (19.8-9 nm) of the nanotubes was achieved by varying the anodization time (4-16 h) and temperatures (42-87 °C), respectively. While the variation of length influenced the sensing parameters insignificantly, the best response magnitude was achieved for ∼13 nm wall thickness. The underlying sensing mechanism was correlated with the experimental findings on the basis of structural parameters of the nanotubes.

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Low temperature acetone detection by p-type nano-titania thin film: Equivalent circuit model and sensing mechanism

Bhowmik

Dutta

Hazra

et al. 2014

Solid-State Electronics

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Basanta Bhowmik

Room temperature alcohol sensing by oxygen vacancy controlled TiO2 nanotube array

Micro/nanostructured gas sensors: the physics behind the nanostructure growth, sensing and selectivity mechanisms

Highly Selective Low-Temperature Acetone Sensor Based on Hierarchical 3-D TiO₂Nanoflowers

Stoichiometry, Length, and Wall Thickness Optimization of TiO₂ Nanotube Array for Efficient Alcohol Sensing

Low temperature acetone detection by p-type nano-titania thin film: Equivalent circuit model and sensing mechanism

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Basanta Bhowmik

Room temperature alcohol sensing by oxygen vacancy controlled TiO2 nanotube array

Micro/nanostructured gas sensors: the physics behind the nanostructure growth, sensing and selectivity mechanisms

Highly Selective Low-Temperature Acetone Sensor Based on Hierarchical 3-D TiO2Nanoflowers

Stoichiometry, Length, and Wall Thickness Optimization of TiO2 Nanotube Array for Efficient Alcohol Sensing

Low temperature acetone detection by p-type nano-titania thin film: Equivalent circuit model and sensing mechanism

Contact Info

Product

Resources

About

Highly Selective Low-Temperature Acetone Sensor Based on Hierarchical 3-D TiO₂Nanoflowers

Stoichiometry, Length, and Wall Thickness Optimization of TiO₂ Nanotube Array for Efficient Alcohol Sensing