Fabrication and Characterization of Proton Exchanged Waveguides in Periodically Poled Congruent Lithium Niobate

“…Both polar surfaces of the 0.5 mm thick CLN wafer cut perpendicular to polar axis were subjected to PE procedure which was carried out in benzoic acid with 1% lithium benzoate at 300 • C. Different exposures resulted in formation of so-called β 2 non-ferroelectric phase in the surface layers with thickness ranged from 0.5 to 3.0 µm [13].…”

Abnormal Domain Growth in Lithium Niobate with Surface Layer Modified by Proton Exchange

“…Both polar surfaces of the 0.5 mm thick CLN wafer cut perpendicular to polar axis were subjected to PE procedure which was carried out in benzoic acid with 1% lithium benzoate at 300 • C. Different exposures resulted in formation of so-called β 2 non-ferroelectric phase in the surface layers with thickness ranged from 0.5 to 3.0 µm [13].…”

Abnormal Domain Growth in Lithium Niobate with Surface Layer Modified by Proton Exchange

“…• C resulting in formation of two non-ferroelectric phases, so-called β 1 and β 2 , in the surface layer with a total thickness about 2.0 µm [9]. It has been shown experimentally that the modified surface layers possess a step-like profile of refractive indices thus representing well-defined dielectric surface layers just appropriate for studying the influence of the uniform surface dielectric gap on the domain kinetics.…”

Influence of Surface Layers Modified by Proton Exchange on Domain Kinetics of Lithium Niobate

“…The spinning of photoresist and deposition of the dielectric film, as well as surface modification by proton exchange 54,55,62,63 and ion irradiation 64 were used. The tailored thickness of the dielectric gap allows one to control the period of the self-organized nanodomain structures.…”

Self-assembled domain structures: From micro- to nanoscale