Mechanical Properties of Li-Nb-O System Films

Aleksandr V. Kostyuchenko; Evgeny K. Belonogov; Valentin M. Ievlev; Alexander E. Nikonov; Evgeny A. Osipov; Pavel A. Osipov

doi:10.17308/kcmf.2025.27/13016

Aleksandr V. Kostyuchenko Voronezh State Technical University, 20 let Oktyabrya st., 84, Voronezh 394006, Russian Federation http://orcid.org/0000-0002-0049-3664
Evgeny K. Belonogov Voronezh State Technical University, 20 let Oktyabrya st., 84, Voronezh 394006, Russian Federation; Voronezh State University, 1, University pl., Voronezh 394018, Russian Federation http://orcid.org/0000-0002-0216-0986
Valentin M. Ievlev Voronezh State Technical University, 20 let Oktyabrya st., 84, Voronezh 394006, Russian Federation; Voronezh State University, 1, University pl., Voronezh 394018, Russian Federation; Moscow State University, 1, Leninskie Gory, Moscow 119991, Russian Federation http://orcid.org/0000-0002-3205-2580
Alexander E. Nikonov Voronezh State Technical University, 20 let Oktyabrya st., 84, Voronezh 394006, Russian Federation http://orcid.org/0009-0000-0852-2303
Evgeny A. Osipov Voronezh State Technical University, 20 let Oktyabrya st., 84, Voronezh 394006, Russian Federation http://orcid.org/0009-0002-1209-3833
Pavel A. Osipov Voronezh State Technical University, 20 let Oktyabrya st., 84, Voronezh 394006, Russian Federation http://orcid.org/0009-0003-3891-2646

DOI: https://doi.org/10.17308/kcmf.2025.27/13016

Keywords: Thin film, Lithium niobate, Thermal annealing, Crystallization, Structure, Surface morphology, Nanoindentation, Hardness, Cracking

Abstract

Objective: To quantitatively assess the hardness, elasticity, and plasticity, and to determine the influence of structure and substructure on these parameters in Li-Nb-O system films.

Experimental: Li-Nb-O system films with a thickness of ~0.8 μm were grown on non-heated substrates (oxidized single-crystal silicon wafers (SiO₂ layer ~0.4 μm), single-crystal lithium niobate with (0001) orientation) by ion beam sputtering of a lithium niobate target. Thermal annealing of Li-Nb-O films on substrates was performed in air for 10 min (until complete crystallization) at temperatures of 550, 650, 700, 750, 800, and 850 °C. The heterostructures (film/substrate) were cooled with the furnace. The phase composition of the films was investigated by X-ray diffraction (XRD) and selected area electron diffraction (SAED). The substructure was studied by transmission electron microscopy (TEM) and high-resolution TEM (HRTEM, Tecnai G2 30ST) of cross-sectional specimens prepared by ion milling using a Quanta 3D setup. The surface morphology was investigated by scanning electron microscopy (SEM, Teskan Mira) in the topological
contrast mode and atomic force microscopy (AFM, Solver47). Mechanical properties – hardness (H) and Young's modulus (E) – were determined from nanoindentation (NI, NanoHardness Tester CSM Instruments) measurements using a Berkovich diamond indenter under the following conditions: maximum load 10 mN, loading rate 10 mN/min, and unloading rate 15 mN/min.

Results: It was found that thermal annealing in an oxygen-containing atmosphere at 750°C induces crystallization of quasi-amorphous Li-Nb-O films and the synthesis of single-phase LN films with lattice parameters closest to those of stoichiometric single-crystal LN. The most probable mechanisms of irreversible deformation in LN films are: brittle fracture, plastic deformation of crystallites, and grain boundary sliding. LN films synthesized at 650-750°C are most susceptible to brittle fracture. Brittle fracture occurs due to the buildup of macrostresses in the films, resulting from different coefficients of thermal expansion (CTE) of the film and the substrate. The fracture toughness of the films increases significantly when using a substrate with a CTE close to that of the film. The hardness of nano- and microcrystalline LN films is always higher than the hardness of quasi-amorphous Li-Nb-O system films. The decrease in the hardness of а films synthesized at high annealing temperatures is due to a decrease in the concentration of point defects and an increase in the size of the crystallites

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Author Biographies

Aleksandr V. Kostyuchenko, Voronezh State Technical University, 20 let Oktyabrya st., 84, Voronezh 394006, Russian Federation

Cand. Sci. (Phys.–Math.), Associate Professor, Department of Solid State Electronics,
Voronezh State Technical University (Voronezh, Russian Federation)

Evgeny K. Belonogov, Voronezh State Technical University, 20 let Oktyabrya st., 84, Voronezh 394006, Russian Federation; Voronezh State University, 1, University pl., Voronezh 394018, Russian Federation

Dr. Sci. (Phys.–Math.), Professor, Department of Physics, Voronezh State Technical University
(Voronezh, Russian Federation)

Valentin M. Ievlev, Voronezh State Technical University, 20 let Oktyabrya st., 84, Voronezh 394006, Russian Federation; Voronezh State University, 1, University pl., Voronezh 394018, Russian Federation; Moscow State University, 1, Leninskie Gory, Moscow 119991, Russian Federation

Full Member of the Russian Academy
of Sciences, Dr. Sci. (Phys.–Math.), Professor, Head of the
Department of Interdisciplinary Materials Science,
Lomonosov Moscow State University (Moscow, Russian
Federation)

Alexander E. Nikonov, Voronezh State Technical University, 20 let Oktyabrya st., 84, Voronezh 394006, Russian Federation

Cand. Sci. (Phys.–Math.), Researcher of the Functional Materials Laboratory, Voronezh
State Technical University (Voronezh, Russian Federation)

Evgeny A. Osipov, Voronezh State Technical University, 20 let Oktyabrya st., 84, Voronezh 394006, Russian Federation

student, Department of Solid State Electronics, Voronezh State Technical University (Voronezh,
Russian Federation)

Pavel A. Osipov, Voronezh State Technical University, 20 let Oktyabrya st., 84, Voronezh 394006, Russian Federation

student, Department of Solid State Electronics, Voronezh State Technical University (Voronezh,
Russian Federation)

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