Optical: systems and elements – Optical modulator – Light wave temporal modulation
Patent
1991-02-27
1993-06-15
Arnold, Bruce Y.
Optical: systems and elements
Optical modulator
Light wave temporal modulation
359257, 359278, 359328, 252582, 252583, 252585, 385 5, 385 8, G02F 135, G02F 103, F21V 914
Patent
active
052204510
DESCRIPTION:
BRIEF SUMMARY
TECHNICAL FIELD
This invention relates to a second-order nonlinear optical device by which the frequency conversion effects or linear electro-optic effect (Pockels effect) is utilized. The devices are useful in the field of optical information processing and optical communications.
BACKGROUND ART
When a strong electric field (E) such as laser beam is applied to a substance, the substance shows polarization (P) which is expressed by the following general equation: an integer of not less than 2) means nonlinear optical susceptibility). The nonlinear optical effects are those expressed by the high order terms of E, i.e., terms of E of not less than square.
The effects expressed by the square term are called second-order nonlinear optical effects. Examples of the second-order nonlinear optical effects include frequency conversion effects such as second harmonic generation (SHG) or parametric oscillation, and linear electro-optic effect (Pockels effect). By utilizing these effects, second-order nonlinear optical devices which are industrially important, such as frequency converters including second harmonic generators (SHG devices) and parametric oscillators, or electro-optic devices such as optical switches and optical modulators can be obtained.
The second-order nonlinear optical devices include at least one optical element of an optical medium which should have a substantially optically smooth surface to be impinged, transmitted and/or propagated by laser beam or the like. In case of electro-optic devices, the devices further comprise electrodes for applying electric field.
Employment of an optical medium which shows higher performance or higher nonlinear optical effects for constituting the second-order nonlinear optical device is advantageous because (i}the power of the light source may be reduced, (ii) the size of the device may be made small, (iii) the voltage of the applied electric field may be reduced and (iv) the price of the device may be made less expensive.
The second-order nonlinear optical media have strong anisotropy with respect to the expression of the effects (i.e., the anisotropic dependency on the optical field and external electric field). Therefore, a device structure, namely, an element structure for allowing the optical medium to efficiently exhibit the effects is required.
Conventional nonlinear optical media include potassium dihydrogen phosphate (KDP) crystals; manifest second-order nonlinear optical effects (e.g., poled polymers hereinbelow described).
The nonlinear optical media (i) were firstly developed in the art and their processing technologies for an optical element or device are best known. However, their second-order nonlinear optical effects are not large. Thus, the performance of the second-order nonlinear optical devices utilizing the nonlinear optical media (i) is unsatisfactory. They are large in size and expensive. In addition, the LN crystals which show the best performance of the media (i) can be damaged by light, which is a serious problem in practical industrial applications.
The nonlinear optical media (ii) are receiving much attention recently as optical media superior to the media (i) because of the large optical nonlinearity of organic molecules due to the intramolecular x electronic fluctuation, fast response and high resistance against laser beam.
For example, 2-methyl-4-nitroaniline (MNA) crystal was reported to have the highest nonlinear optical effects among the optical media (ii), which are larger than those exhibited by the LN crystal which is an inorganic ferroelectric nonlinear optical crystal (e.g., J. Appl. Phys., 50(4), 2523 (1979); J. Chem. Phys., 75(3), 1509 (1981)).
However, the nonlinear optical effects of MNA crystal are not so strikingly larger than those exhibited by LN crystal. Further, MNA crystal has practical problems in that it is water-soluble and sublimated at room temperature.
The nonlinear optical media (iii) have been developed because of the good processability of the polymers. However, their second-order nonlinear optical ef
REFERENCES:
patent: 4909964 (1990-03-01), Clement et al.
patent: 4961631 (1990-10-01), Clement et al.
patent: 4966730 (1990-10-01), Clement et al.
patent: 5045239 (1991-09-01), Miyata et al.
WPIL, Derwent File Supplier, Accession No. 87-238172 [34], Derwent Publications Ltd., London, GB & JP-A-62 160 427 (Toray).
WPIL, Derwent File Supplier, Accession No. 86-260425 [40], Derwent Publications Ltd. London, GB; & JP-A-61 186 942 (Nite).
Egawa Keiichi
Fukuda Seiji
Gotoh Tetsuya
Mataki Hiroshi
Tsunekawa Tetsuya
Arnold Bruce Y.
Shafer R. D.
Toray Industries Inc.
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