Optical and electrical properties of MoO₂ and MoO₃ thin films prepared from the chemically driven isothermal close space vapor transport technique

Abstract: Chemically -driven isothermal close space vapour transport was used to prepare pure MoO2 films which were eventually converted to MoO3 by annealing in air. According to temperaturedependent Raman measurements, the MoO2/MoO3 phase transformation was found to occur in the 225 -350 o C range; no other phases were detected during the transition. A clear change in composition and Raman spectra, as well as noticeable modifications of the band gap and the absorption coefficient confirmed the conversion from MoO2 to M… Show more

“…It is also evident that, at this calcination temperature, the intensity of the peak corresponding to NiO attenuated, while that of MoO 3 increased. This is reasonable since MoO 2 is stable in the temperature range of 225–350 °C, and in other studies, nanostructured MoO 3 has been found to exhibit stability between 230 °C and 490 °C [ 31 ]. The comparative analysis of the XRD patterns suggest that between 300 °C and 400 °C, a portion of MoO 2 changed to MoO 3 and reacted with NiO to produce NiMoO 4 .…”

“…The relatively small band gap of the material prepared at 300 °C is due to the significant presence of MoO 2 . Conflicting reports about the band gap of MoO 2 can be found in the literature, where some authors suggested that MoO 2 exhibits a metallic behavior, while other findings purported that this material conveys a mixed semi-conductive/metallic behavior [ 31 , 47 ]. However, reduced MoO 3 materials have been reported to attain a band gap between 2.4 and 2.7 eV, and recently Melo et al reported a value of 1.83 eV for pure MoO 2 [ 31 ].…”

“…Conflicting reports about the band gap of MoO 2 can be found in the literature, where some authors suggested that MoO 2 exhibits a metallic behavior, while other findings purported that this material conveys a mixed semi-conductive/metallic behavior [ 31 , 47 ]. However, reduced MoO 3 materials have been reported to attain a band gap between 2.4 and 2.7 eV, and recently Melo et al reported a value of 1.83 eV for pure MoO 2 [ 31 ]. Therefore, it is the large presence of MoO 2 that explains the comparatively small band gap of the sample prepared at 300 °C.…”

Part I: NiMoO4 Nanostructures Synthesized by the Solution Combustion Method: A Parametric Study on the Influence of Synthesis Parameters on the Materials’ Physicochemical, Structural, and Morphological Properties

“…It is also evident that, at this calcination temperature, the intensity of the peak corresponding to NiO attenuated, while that of MoO 3 increased. This is reasonable since MoO 2 is stable in the temperature range of 225–350 °C, and in other studies, nanostructured MoO 3 has been found to exhibit stability between 230 °C and 490 °C [ 31 ]. The comparative analysis of the XRD patterns suggest that between 300 °C and 400 °C, a portion of MoO 2 changed to MoO 3 and reacted with NiO to produce NiMoO 4 .…”

“…The relatively small band gap of the material prepared at 300 °C is due to the significant presence of MoO 2 . Conflicting reports about the band gap of MoO 2 can be found in the literature, where some authors suggested that MoO 2 exhibits a metallic behavior, while other findings purported that this material conveys a mixed semi-conductive/metallic behavior [ 31 , 47 ]. However, reduced MoO 3 materials have been reported to attain a band gap between 2.4 and 2.7 eV, and recently Melo et al reported a value of 1.83 eV for pure MoO 2 [ 31 ].…”

“…Conflicting reports about the band gap of MoO 2 can be found in the literature, where some authors suggested that MoO 2 exhibits a metallic behavior, while other findings purported that this material conveys a mixed semi-conductive/metallic behavior [ 31 , 47 ]. However, reduced MoO 3 materials have been reported to attain a band gap between 2.4 and 2.7 eV, and recently Melo et al reported a value of 1.83 eV for pure MoO 2 [ 31 ]. Therefore, it is the large presence of MoO 2 that explains the comparatively small band gap of the sample prepared at 300 °C.…”

Part I: NiMoO4 Nanostructures Synthesized by the Solution Combustion Method: A Parametric Study on the Influence of Synthesis Parameters on the Materials’ Physicochemical, Structural, and Morphological Properties

“…The reason could be the formation of Al 2 O 3 in the reaction of Al with O. The refractive index of alumina is lower than that of MoO 3 in the measured range of wavelengths [37][38][39], so the increase in the amount of Al 2 O 3 content in the film may reduce the total absorbance of the films, as observed experimentally. This is in agreement with the GIWAXS results that indicate formation of Al 2 O 3 in the Al-based films.…”

Structural, Optical and Electrical Properties of Al+MoO3 and Au+MoO3 Thin Films Prepared by Magnetron Codeposition

“…To enhance the optical properties, materials with a greatest potential to be applied as an absorbing layer are the transition metal oxides (TMO’s) and among the most studied are molybdenum oxides (MoO x ) [ 12 ]. Depending on the desired applications, MoO x can be deposited or synthesized by physical or chemical techniques, respectively [ 13 ]. The deposition or synthesis techniques allow us to modify the characteristics of the oxide in order to enhance the desired properties according to the application [ 14 ].…”

Extinction Coefficient Modulation of MoO3 Films Doped with Plasmonic Nanoparticles: From an Effective Medium Theory Description