Title :
All-fiber acoustooptic phase modulators using chemical vapor deposition zinc oxide films
Author :
Koch, Michael H. ; Janos, Mark ; Lamb, Robert N. ; Sceats, Mark G. ; Minasian, Robert A.
Author_Institution :
Sch. of Chem., New South Wales Univ., Sydney, NSW, Australia
fDate :
3/1/1998 12:00:00 AM
Abstract :
For the first time we report an all-fiber acoustooptic phase modulator using a zinc oxide (ZnO) film deposited by modified single source chemical vapor deposition. This technique allows deposition over the full 360° fiber surface without the need for sample rotation, greatly simplifying the manufacturing process. The maximum phase shift measured for our 6 mm long devices was 3.5 rads for a drive power of 580 mW. Unlike devices fabricated using sputtered ZnO films the maximum attainable phase shift is not significantly limited by thermal and mechanical loss effects at higher driving powers which we attribute to the excellent chemical composition of our chemical vapor deposition (CVD) grown films. A maximum efficiency of 0.28 rad/√(mW)/cm of device length was measured which may be attributed to the relatively thin films used in this experiment (0.4-0.9 μm)
Keywords :
acousto-optical modulation; chemical vapour deposition; optical fabrication; optical fibre cladding; optical films; phase modulation; zinc compounds; 580 mW; 6 mm; ZnO; ZnO film; all-fiber acoustooptic phase modulators; chemical composition; chemical vapor deposition; drive power; fiber surface; maximum attainable phase shift; maximum efficiency; maximum phase shift; mechanical loss effects; modified single source chemical vapor deposition; sample rotation; zinc oxide films; Australia; Chemical vapor deposition; Optical fiber devices; Optical fiber polarization; Optical films; Optical surface waves; Phase modulation; Piezoelectric films; Thin film devices; Zinc oxide;
Journal_Title :
Lightwave Technology, Journal of
