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Hydrothermal Synthesis and Gas Sensing of Monoclinic MoO3 Nanosheets

Teodóra Nagyné-Kovács, Levente Studnicka, István Endre Lukács, Krisztina László, P. Pasierb, Imre Miklós Szilágyi, György Pokol

2020Nanomaterials79 citationsDOIOpen Access PDF

Abstract

Effects of different reaction parameters in the hydrothermal synthesis of molybdenum oxides (MoO3) were investigated and monoclinic (β-) MoO3 was prepared hydrothermally for the first time. Various temperatures (90/210 °C, and as a novelty 240 °C) and durations (3/6 h) were used. At 240 °C, cetyltrimethylammonium bromide (CTAB) and CrCl3 additives were also tested. Both the reaction temperatures and durations played a significant role in the formation of the products. At 90 °C, h-MoO3 was obtained, while at 240 °C the orthorhombic (α-) MoO3 formed with hexagonal rod-like and nanofibrous morphology, respectively. The phase transformation between these two phases was observed at 210 °C. At this temperature, the 3 h reaction time resulted in the mixture of h- and α-MoO3, but 6 h led to pure α-MoO3. With CTAB the product was bare o-MoO3, however, when CrCl3 was applied, pure metastable m-MoO3 formed with the well-crystallized nanosheet morphology. The gas sensing of the MoO3 polymorphs was tested to H2, which was the first such gas sensing study in the case of m-WO3. Monoclinic MoO3 was found to be more sensitive in H2 sensing than o-MoO3. This initial gas sensing study indicates that m-MoO3 has promising gas sensing properties and this MoO3 polymorph is promising to be studied in detail in the future.

Topics & Concepts

Monoclinic crystal systemHydrothermal circulationOrthorhombic crystal systemNanosheetMaterials scienceBromideHydrothermal synthesisPhase (matter)Ammonium bromideChemical engineeringMetastabilityCrystallographyCrystal structureNanotechnologyInorganic chemistryChemistryOrganic chemistryEngineeringPulmonary surfactantGas Sensing Nanomaterials and SensorsTransition Metal Oxide NanomaterialsZnO doping and properties