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Nlo Polymer Material Systems for Electro-Optic Devices

Published online by Cambridge University Press:  10 February 2011

J. T. Kenney
Affiliation:
ROI Technology (ROITech), 2990 Scott Blvd., SANTA CLARA, CA 95054
J. C. Nurse
Affiliation:
ROI Technology (ROITech), 2990 Scott Blvd., SANTA CLARA, CA 95054
J. C. Chon
Affiliation:
ROI Technology (ROITech), 2990 Scott Blvd., SANTA CLARA, CA 95054
E. S. Binidey
Affiliation:
ROI Technology (ROITech), 2990 Scott Blvd., SANTA CLARA, CA 95054
M. Stiller
Affiliation:
ROI Technology (ROITech), 2990 Scott Blvd., SANTA CLARA, CA 95054
D. W. Ball
Affiliation:
ROI Technology (ROITech), 2990 Scott Blvd., SANTA CLARA, CA 95054
A. K-Y. Jen
Affiliation:
ROI Technology (ROITech), 2990 Scott Blvd., SANTA CLARA, CA 95054
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Abstract

Non linear optical (NLO) polymers have great potential to be fabricated into integrated electro-optic (E/O) devices for use as high speed electro-optic (E/O) switches, modulators and interconnects in computer and communication systems [1,2]. The fabrication of practical integrated E/O devices requires a material system that meets the final device requirements and can be processed using standard fabrication technologies [3]. Applications of polymer E/O devices in electronic systems have been limited by the relatively low thermal stability and poor processability of non linear optical (NLO) polymers. This paper describes a thermally stable electro-optic material system and the fabrication process to make compact integrated E/O devices for application in electronic systems. This material system consists of high thermal stability polyimide core and cladding materials. The active NLO material is a side chain polyimide that uses a new high activity and high thermal stability chromophore.

Type
Research Article
Copyright
Copyright © Materials Research Society 1996

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References

REFERENCES

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