W. Włodarski scite author profile

Nitrogen dioxide (NO2) is a gas species that plays an important role in certain industrial, farming, and healthcare sectors. However, there are still significant challenges for NO2 sensing at low detection limits, especially in the presence of other interfering gases. The NO2 selectivity of current gas-sensing technologies is significantly traded-off with their sensitivity and reversibility as well as fabrication and operating costs. In this work, we present an important progress for selective and reversible NO2 sensing by demonstrating an economical sensing platform based on the charge transfer between physisorbed NO2 gas molecules and two-dimensional (2D) tin disulfide (SnS2) flakes at low operating temperatures. The device shows high sensitivity and superior selectivity to NO2 at operating temperatures of less than 160 °C, which are well below those of chemisorptive and ion conductive NO2 sensors with much poorer selectivity. At the same time, excellent reversibility of the sensor is demonstrated, which has rarely been observed in other 2D material counterparts. Such impressive features originate from the planar morphology of 2D SnS2 as well as unique physical affinity and favorable electronic band positions of this material that facilitate the NO2 physisorption and charge transfer at parts per billion levels. The 2D SnS2-based sensor provides a real solution for low-cost and selective NO2 gas sensing.

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Synthesis of nanometre-thick MoO₃sheets

Kalantar‐zadeh

Tang²,

Wang³

et al. 2010

Nanoscale

257

247

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The formation of MoO(3) sheets of nanoscale thickness is described. They are made from several fundamental sheets of orthorhombic alpha-MoO(3), which can be processed in large quantities via a low cost synthesis route that combines thermal evaporation and mechanical exfoliation. These fundamental sheets consist of double-layers of linked distorted MoO(6) octahedra. Atomic force microscopy (AFM) measurements show that the minimum resolvable thickness of these sheets is 1.4 nm which is equivalent to the thickness of two double-layers within one unit cell of the alpha-MoO(3) crystal.

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Graphene/Polyaniline Nanocomposite for Hydrogen Sensing

et al. 2010

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Here we report on the synthesis of a graphene/polyaniline (PANI) nanocomposite and its application in the development of a hydrogen (H2) gas sensor. Using a chemical synthetic route, graphene was prepared and ultrasonicated with a mixture of aniline monomer and ammonium persulfate to form PANI on its surface. The developed material was characterized by scanning electron microscopy (SEM), transmission electron microscopy, Raman spectroscopy, and X-ray photoemission spectroscopy. The SEM study revealed that the PANI in the composite has a nanofibrillar morphology. We investigated the H2 gas sensing performance of this material and compare it with that of the sensors based on only graphene sheets and PANI nanofibers. We found that the graphene/PANI nanocomposite-based device sensitivity is 16.57% toward 1% of H2 gas, which is much larger than the sensitivities of sensors based on only graphene sheets and PANI nanofibers.

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Graphene-like nano-sheets for surface acoustic wave gas sensor applications

Arsat

Breedon

Shafiei

et al. 2009

Chemical Physics Letters

358

194

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In Situ Raman Spectroscopy of H₂ Gas Interaction with Layered MoO₃

et al. 2011

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It is known that the unique layered structure of orthorhombic MoO3 (α-MoO3) facilitates the interaction with H2 gas molecules and that the surface-to-volume ratios of the crystallites play an important role in the process. MoO3 was deposited on a wide variety of transparent substrates using thermal evaporation in order to alter the surface-to-volume ratios of the crystallites. In situ Raman spectroscopy was employed to investigate the interaction between MoO3 and 1% H2 in both N2 and synthetic air environments, while incorporating Pd as a catalyst at room temperature. This study confirmed that the layered MoO3 with a high surface-to-volume ratio facilitated the H2 gas interaction. The Raman spectroscopy studies revealed that the H+ ions mainly interacted with the doubly coordinated oxygen atoms and caused the crystal transformation from the original α-MoO3 into the mixed structure of hydrogen molybdenum bronze and substoichiometric MoO3, eventually forming oxygen vacancies and water. It was also found that the presence of O2 during the H2 gas exposure caused the recombination of a number of oxygen vacancies and reduced the available surface catalytic sites for H2.

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Two dimensional α-MoO3 nanoflakes obtained using solvent-assisted grinding and sonication method: Application for H2 gas sensing

Alsaif

Balendhran

Field

et al. 2014

Sensors and Actuators B: Chemical

190

150

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XPS study of Nb-doped oxygen sensing TiO2 thin films prepared by sol-gel method

Atashbar¹,

Sun²,

et al. 1998

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Characterization of ZnO Nanobelt-Based Gas Sensor for ${\rm H}_{2}$, ${\rm NO}_{2}$, and Hydrocarbon Sensing

et al. 2007

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A conductometric H 2 , NO 2 , and hydrocarbon gas sensor based on single-crystalline zinc oxide (ZnO) nanobelts has been developed. The nanobelt sensitive layer was deposited using a radio frequency (RF) magnetron sputterer. The microcharacterization study reveals that the nanobelts have a single crystal hexagonal structure with average thickness and width of about 10 and 50 nm, respectively. The sensor was exposed to H 2 , NO 2 and propene gases at operating temperatures between 150 C and 450 C. The study showed that optimum operating temperatures for the sensor are in the range of 300 C-400 C for H 2 , 300 C-350 C for NO 2 , and 350 C-420 C for propene sensing.

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W. Włodarski

Physisorption-Based Charge Transfer in Two-Dimensional SnS₂ for Selective and Reversible NO₂ Gas Sensing

Synthesis of nanometre-thick MoO₃sheets

Graphene/Polyaniline Nanocomposite for Hydrogen Sensing

Graphene-like nano-sheets for surface acoustic wave gas sensor applications

In Situ Raman Spectroscopy of H₂ Gas Interaction with Layered MoO₃

Two dimensional α-MoO3 nanoflakes obtained using solvent-assisted grinding and sonication method: Application for H2 gas sensing

XPS study of Nb-doped oxygen sensing TiO2 thin films prepared by sol-gel method

Characterization of ZnO Nanobelt-Based Gas Sensor for ${\rm H}_{2}$, ${\rm NO}_{2}$, and Hydrocarbon Sensing

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Product

Resources

About

W. Włodarski

Physisorption-Based Charge Transfer in Two-Dimensional SnS2 for Selective and Reversible NO2 Gas Sensing

Synthesis of nanometre-thick MoO3sheets

Graphene/Polyaniline Nanocomposite for Hydrogen Sensing

Graphene-like nano-sheets for surface acoustic wave gas sensor applications

In Situ Raman Spectroscopy of H2 Gas Interaction with Layered MoO3

Two dimensional α-MoO3 nanoflakes obtained using solvent-assisted grinding and sonication method: Application for H2 gas sensing

XPS study of Nb-doped oxygen sensing TiO2 thin films prepared by sol-gel method

Characterization of ZnO Nanobelt-Based Gas Sensor for ${\rm H}_{2}$, ${\rm NO}_{2}$, and Hydrocarbon Sensing

Contact Info

Product

Resources

About

Physisorption-Based Charge Transfer in Two-Dimensional SnS₂ for Selective and Reversible NO₂ Gas Sensing

Synthesis of nanometre-thick MoO₃sheets

In Situ Raman Spectroscopy of H₂ Gas Interaction with Layered MoO₃