New Trends in Lithium Niobate

doi:10.3390/books978-3-0365-3339-1

Reprint

Download Flyer

New Trends in Lithium Niobate

From Bulk to Nanocrystals

Edited by

February 2022

382 pages

ISBN978-3-0365-3340-7 (Hardback)
ISBN978-3-0365-3339-1 (PDF)

https://doi.org/10.3390/books978-3-0365-3339-1

Free download (PDF)

This book is a reprint of the Special Issue New Trends in Lithium Niobate: From Bulk to Nanocrystals that was published in

Chemistry & Materials Science

Engineering

Environmental & Earth Sciences

Summary

The present volume “New Trends in Lithium Niobate: From Bulk to Nanocrystals” contains the materials of a Special Issue of the MDPI journal Crystals dedicated to the memory of Prof. Dr. Ortwin F. Schirmer and provides a new synopsis of his research focusing on LiNbO₃. It also includes recent developments, exemplifying the continued interest in this outstanding ferroelectric, non-linear optical and holographic crystal as a workhorse for testing and realizing new ideas and applications.This book starts with reviews on intrinsic and extrinsic crystal defects in LiNbO₃of single-crystal, thin-film or nano-powder forms, studied by various optical, magnetic resonance and nuclear methods, clarifying in particular the reasons for the suppression of anion vacancy formation upon thermal reduction, mechano-chemical processing or irradiations of various types. The reviews are followed by research papers on the experimental and theoretical investigation of small polarons, together with recent results on the properties of Li(Nb,Ta)O₃ mixed crystals. Among the various contributions dealing with nonlinear optical applications, papers on device development, entangled photon pair generation and thin films on the Lithium Niobate On Insulator (LNOI) platform can also be found.

Format

Hardback

License

Keywords

lithium niobate; small polaron hopping; transient absorption; mode-locked laser; nonlinear mirror mode locking; lithium niobate; lithium niobate; lithium tantalate; crystal structure; chemical composition; ferroelectrics; second harmonic generation; lead-free piezoelectrics; lithium niobate; lithium tantalate; intrinsic defects; extrinsic defects; elemental doping; ferromagnetism; diluted-magnetic oxides; LiNbO₃; LiTaO₃; oxide crystals; lanthanides; luminescence; lithium niobate; LNOI; ferroelectric domains; domain-wall conduction; AFM; thin film lithium niobate; TFLN; LNOI; x-cut LN; ferroelectric domains; domain walls; piezoresponse force microscopy; second-harmonic generation; Raman scattering; electro-optics; whispering gallery resonators; lithium niobate; lithium niobate; polarons; photorefractivity; Marcus-Holstein’s theory; Monte Carlo simulations; lithium niobate; strontium titanate; self-trapped electrons; polarons; oxygen vacancies; defects; luminescence; impurity; intrinsic defect; paramagnetic ion; lithium niobate; lithium tantalate; electron paramagnetic resonance; electron nuclear double resonance; lithium vacancy; lithium; niobate; epitaxy; thin film; liquid phase epitaxy; molecular beam epitaxy; sputtering; pulsed laser deposition; chemical vapor deposition; lithium niobate-tantalate; piezoelectric; acoustic; high-temperature; sensor; Q-factor; BAW resonator; lithium niobate; parametric down-conversion; photon-pair generation; extended phase matching; microring resonator; varFDTD; lithium tantalate thin film; electro-optical devices; lithium niobate; intrinsic defects; extrinsic defects; lattice location; radiation damage; ion beam analysis; hyperfine interactions; lithium niobate; polarons; charge localization; lattice deformation; optical response; density-functional theory; Bethe-Salpeter equation; nanoparticles; nanopowders; lithium niobate-tantalate; X-ray diffraction; Raman spectroscopy; temperature dependence of electroconductivity; LiNbO₃; polarons; bipolarons; defect structure and generation; Li diffusion; lithium niobate; bulk crystals; thin films; nanocrystals