Abstract
Molybdenum forms a range of oxides with different stoichiometries and crystal structures, which lead to different properties and performance in diverse applications. Herein, crystalline molybdenum oxide thin films with controlled phase composition are deposited by atomic layer deposition. The MoO2(thd)2 and O3 as precursors enable well-controlled growth of uniform and conformal films at 200–275 °C. The as-deposited films are rough and, in most cases, consist of a mixture of α- and β-MoO3 as well as an unidentified suboxide MoOx (2.75 ≤ x ≤ 2.89) phase. The phase composition can be tuned by changing deposition conditions. The film stoichiometry is close to MoO3 and the films are relatively pure, the main impurity being hydrogen (2–7 at-%), with ≤1 at-% of carbon and nitrogen. Post-deposition annealing is studied in situ by high-temperature X-ray diffraction in air, O2, N2, and forming gas (10% H2/90% N2) atmospheres. Phase-pure films of MoO2 and α-MoO3 are obtained by annealing at 450 °C in forming gas and O2, respectively. The ability to tailor the phase composition of MoOx films deposited by scalable atomic layer deposition method represents an important step towards various applications of molybdenum oxides.
Highlights
Molybdenum oxides (MoOx) form a versatile group of materials as their properties vary widely as a function of the molybdenum oxidation state [1]
We report the first Atomic layer deposition (ALD) process capable of depositing crystalline molybdenum oxide films without the use of plasma, using a new ALD precursor MoO2(thd)2 with O3 as the reactant
Molybdenum oxide thin films were deposited by atomic layer deposition (ALD) using dioxobis(2,2,6,6-tetramethylheptane-3,5dionato)molybdenum(VI) [MoO2(thd)2] and O3 as precursors
Summary
Molybdenum oxides (MoOx) form a versatile group of materials as their properties vary widely as a function of the molybdenum oxidation state [1]. In addition to the phase, film morphology is often crucial; in particular, high roughness or porosity of MoOx has been found beneficial for electrocatalysis, gas sensors, and lithium ion batteries, among other applications [40e43]. Deposition of crystalline (a-MoO3) films by ALD has only been reported from Mo(NtBu)2(NMe2) and O2 plasma at 250 C and above [51]. To the best of our knowledge, neither MoO2 nor any of the crystalline suboxide phases (2.75 x 2.89) have been achieved by ALD, with or without post-deposition annealing. We report the first ALD process capable of depositing crystalline molybdenum oxide films without the use of plasma, using a new ALD precursor MoO2(thd) with O3 as the reactant. Annealing was optimized to produce phase-pure films of a-MoO3 and MoO2
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