Augusto Gonçalo Jose Machatine scite author profile

A layer of ~30 nm V2O5/100 nm-SiO2 on Si was employed in the in situ Raman spectroscopy in the presence of NH3 effluent from a thermal decomposition of ammonium acetate salt with the salt heated at 100 °C. When the layer is placed at 25 °C, we observe a reversible red-shift of 194 cm−1 V2O5 phonon by 2 cm−1 upon NH3 gas injection to saturation, as well as a reversible blue-shift of the 996 cm−1 by 4 cm−1 upon NH3 injection. However when the sensing layer is placed at 100 °C, the 194 cm−1 remains un-shifted while the 996 cm−1 phonon is red-shifted. There is a decrease/increase in intensity of the 145 cm−1 phonon at 25 °C/100 °C when NH3 interacts with V2O5 surface. Using the traditional and quantitative gas sensor tester system, we find that the V2O5 sensor at 25 °C responds faster than at 100 °C up to 20 ppm of NH3 beyond which it responds faster at 100 °C than at 25 °C. Overall rankings of the NH3 gas sensing features between the two techniques showed that the in situ Raman spectroscopy is faster in response compared with the traditional chemi-resistive tester. Hooke’s law, phonon confinement in ~51 nm globular particles with ~20 nm pore size and physisorption/chemisorption principles have been employed in the explanation of the data presented.

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Influence of anodization time on the surface modifications on α-Fe₂O₃photoanode upon anodization

Maabong

Braun

et al. 2016

J. Mater. Res.

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In searching for a suitable semiconductor material for hydrogen production via photoelectrochemical water splitting, a-Fe 2 O 3 received significant attention as a promising photoanode due to its band gap (;2.1 eV), good stability, low cost, and natural occurrence. a-Fe 2 O 3 thin films were prepared by economic and facile dip coating method and subsequently subjected to an anodic potential of 700 mV versus Ag/AgCl in 1M KOH for different anodization times (1, 10, and 900 min) under illumination. X-ray diffractometry revealed increase in crystallites size from ;31 nm for nanoparticles in pristine state to ;38 and 44 nm after anodization for 1 and 900 min, respectively. A clear positive correlation between anodization time and grain (particle) size was observed from field emission gun scanning electron microscopy and atomic force microscopy (AFM); longer exposure time to anodizing conditions resulted in larger grains. Grain size increased from ;57.9 nm in pristine state to ;153.5 nm after anodization for 900 min. A significant smoothening of the surface with increase in anodization time was evident from AFM analysis.

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Bound and free excitons in ZnO. Optical selection rules in the absence and presence of time reversal symmetry

Wagner

Kunert

Machatine

et al. 2009

Microelectronics Journal

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Phonons in sapphire Al2O3 substrate for ZnO and GaN

Kunert

Machatine

Hoffmann

et al. 2007

Materials Science and Engineering: C

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