Measurement of electrooptic constants in proton-exchanged LiTaO3 optical waveguides

LiTaO3 is considered resistant to optical damage and it has a small dispersion. Thus, LiTaO3 is expected as a solution to such problems as dc drift and optical damage in an LiNbO3 waveguide. This paper describes a design method for a singlemode, three‐dimensional optical waveguide by means of proton...

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Published inElectronics & communications in Japan. Part 2, Electronics Vol. 77; no. 5; pp. 1 - 11
Main Authors Kakio, Shoji, Minakata, Makoto
Format Journal Article
LanguageEnglish
Published New York Wiley Subscription Services, Inc., A Wiley Company 01.05.1994
Subjects
electrooptic constants
LiTaO3 waveguide
phase modulation method
Proton exchange
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Summary:LiTaO3 is considered resistant to optical damage and it has a small dispersion. Thus, LiTaO3 is expected as a solution to such problems as dc drift and optical damage in an LiNbO3 waveguide. This paper describes a design method for a singlemode, three‐dimensional optical waveguide by means of proton exchange and annealing on a Z‐cut LiTaO3 substrate. A phase modulator with a different annealing time was designed and r33S was measured by the phase modulation method. It is found that the measured value of 6 pm/V immediately after exchange is recovered to 22 pm/V (about 70 percent of the bulk value) by annealing for more than 30 min at 400°C. By the resonance method, r33T was measured. the result is larger by 30 percent than the measured r33S. After annealing for 30 min, the value was almost equal to the bulk value. Further, by the SIMS (secondary ionmass spectroscopy) analysis, the change of the concentration profiles of Li and H+ before and after annealing is determined. It is found that Li returns to the surface from the interior of the substrate by annealing and H+ is diffused in the depth direction. This suggests that the crystallography of the proton‐exchanged layer approaches that before exchange so that the degradation of r constants is recovered.
Bibliography:istex:E0D81A1D733D01029B5BC75F9FDAB4AC3F6372F3
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ArticleID:ECJB4420770501
Presently with Yamanashi University.
Makoto Minakata graduated in Electrical Engineering from Tohoku University in 1968 and received his Doctor of Engineering degree from there in 1974. In 1974 he joined Nippon Telegraph and Telephone, Musashino Electrical Communication Laboratories. He was engaged in research on optical communication, components and materials, and highspeed electron transport. Since then, he has been engaged in research on optical control devices, optical integrated circuits, and compound semiconductor devices. Since 1984, he has been with Tohoku University, Research Institute of Electrical Communication, where he is an Associate Professor. Presently, he has research interests in physics of dielectric optical waveguides and high‐speed optical modulation/demodulation. He is the co‐author of Optical Communication (Corona Publ.). He is a member of the Applied Physics Society; Laser Society; and IEEE.
Shoji Kakio received his B.S. degree in 1990 from Yamanashi University and his M.S. degree in 1992 from Tohoku University. He is engaged in research on protonexchanged optical waveguides. In 1992, he became a Research Associate at Yamanashi University. He is a member of the Applied Physics Society and the Japan Acoustic Society.
ISSN:8756-663X
1520-6432
DOI:10.1002/ecjb.4420770501