Molybdenum oxide (MoO3), because of its exceptional properties, has been the subject of much revived interest as a promising candidate for a broad range of applications such as catalysis [1,2], batteries [3, 4], supercapacitors [5], photo and electrochromic devices [6, 7], gas sensors [8], memory devices [9], organic light emitting diodes (OLEDs) [10], Dielectric/ insulation applications [11], oxide solar cells [12], etc. MoO3 has four polymorph modifications, which include α-MoO3 (orthorhombic), β- MoO3 (monoclinic), high-pressure MoO3-II and h-MoO3 (hexagonal). Among these, the α-MoO3 is a stable polymorph with a bilayer of distorted octahedra having excellent physical properties [13]. It has also been studied in the form of thin films, nanobelts, and nanorods[14-17].
Molybdenum oxide (MoO3), because of its exceptional properties, has been the subject of much revived interest as a promising candidate for a broad range of applications such as catalysis [1,2], batteries [3, 4], supercapacitors [5], photo and electrochromic devices [6, 7], gas sensors [8], memory devices [9], organic light emitting diodes (OLEDs) [10], Dielectric/ insulation applications [11], oxide solar cells [12], etc. MoO3 has four polymorph modifications, which include α-MoO3 (orthorhombic), β- MoO3 (monoclinic), high-pressure MoO3-II and h-MoO3 (hexagonal). Among these, the α-MoO3 is a stable polymorph with a bilayer of distorted octahedra having excellent physical properties [13]. It has also been studied in the form of thin films, nanobelts, and nanorods[14-17].
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