Coherent light generators – Particular active media – Semiconductor
Reissue Patent
1999-10-15
2001-02-13
Sanghavi, Hemang (Department: 2874)
Coherent light generators
Particular active media
Semiconductor
C372S020000, C372S046012, C372S102000
Reissue Patent
active
RE037051
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Technical Field
The present invention relates to semiconductor gain media, especially to those devices that include an integrated multimode region and single mode region and more particularly to laser devices with single spatial mode, diffraction-limited emission with flared gain regions.
2. Background Art
External-cavity semiconductor lasers, including lasers with frequency selective tuning elements in the cavity, are well known and have been extensively studied. For example, T. Fujita, et al., in Applied Physics Letters 51(6), pages 392-394 (1987), describe a laser having a buried heterostructure laser that has been antireflection (AR) coated on the intracavity facet, a collimating lens, a polarization beamsplitter, external cavity mirrors in each of the TE and TM polarization light paths, and an electro-optic modulator in the TE polarization path between the beamsplitter and cavity mirror. The configuration allows selection of either the TE or TM mode of oscillation by adjusting the modulator's bias voltage. W. Sorin, et al., in Optics Letters 13(9), pages 731-733 (1988), describe a laser having a laser diode with one of its facets AR coated to reduce its reflectivity, a lens, a single mode optical fiber and a tunable evanescent grating reflector for providing feedback. The laser is wavelength tunable by sliding the feedback grating laterally over the fiber. P. Zorabedian et al., in Optics Letters 13(10), pages 826-828 (1988), describe another wavelength tunable laser using either a rotatable interference filter in an external Fabry-Perot cavity or an external grating reflector providing frequency-selective feedback.
A problem with previously available external-cavity semiconductor lasers is their generally low output power (on the order of 10 mW cw and 200-300 mW pulsed). Further, higher output powers are associated with unstable output intensity and frequency and less than good modal quality.
In U.S. Pat. No. 4,251,780, Scifres et al. describe semiconductor injection lasers that are provided with a stripe offset geometry in order to enhance and stabilize operation in the lowest order or fundamental transverse mode. In one configuration, the stripe geometry has a horn shaped or trapezoidal section connected to a straight section, in which the width of the horn shaped or trapezoidal section expands from 8 &mgr;m at the straight section to 25 &mgr;m at the cleaved end facet. In contrast to configurations in which the edges of the stripe waveguides are linear and orthogonal to the cleaved end facets of the lasers, the nonorthogonal angled or curved edges of the offset stripe geometries cause higher order modes to reflect or radiate out of the waveguide, thereby increasing the threshold of the higher order modes relative to the fundamental mode.
In U.S. Pat. No. 4,815,084, Scifres et al. describe semiconductor lasers and laser arrays in which lenses and other optical elements have been integrated into the semiconductor bodies of the lasers by means of refractive index changes at boundaries in the light guiding region, where the boundaries are characterized by a lateral geometric contour corresponding to surfaces of selected optical elements so as to cause changes in shape of phase fronts of lightwaves propagating across the boundaries in a manner analogous to the change produced by the optical elements. In one embodiment, a biconcave or plano-concave diverging lens element is integrated within the laser in order to counteract the self-focusing that usually occurs in broad area lasers and that can lead to optical filamentation and lateral incoherence across the laser. The diverging lens in the laser allows the laser to operate as an unstable resonator, leading to high output power and good coherence across the lateral wavefront.
An object of the invention is to provide a high power, semiconductor gain medium which emits a single spatial mode, diffraction-limited output beam.
Another object of the invention is to provide a semiconductor gain medium chip that includes a multimode region and a single spatial mode region with an optical cavity that includes a cleaved facet reflector and a grating reflector.
SUMMARY OF THE INVENTION
The above objects are met with a semiconductor active medium comprising an, at most, marginally stable resonant cavity with a single-spatial-mode filter therein. The semiconductor active medium is preferably an electrically pumped light amplifying diode heterostructure or “amplifier chip” that has a flared gain region with a narrow, single mode, optical aperture end and a broad light output end. The flared gain region permits the light to freely diverge as it propagates in the gain region, so the light has a diverging phase front. Only the central-most light rays of backward propagating light can pass through the narrow aperture end of the flared gain region to reach an external rear reflector of the resonant cavity. Rear reflectors integral with the diode heterostructure could also be used. The rear reflector can be a mirror surface or a frequency selective grating reflector. Orientation of the grating reflector determines which wavelength of light will couple back through the narrow aperture in the amplifier chip into the flared gain region. The flared gain region ensures high power amplification of forward propagating light while maintaining a single spatial mode of oscillation.
In particular, this invention comprises a semiconductor gain medium having a multimode region having a gain portion and providing for light propagation with a diverging phase front to a first reflector comprising a cleaved facet and at least one single mode region coupled at a first end to a first end of the multimode region opposite the first reflecting surface and having at a second end a second reflector comprising a grating reflector formed in the single mode region. An optical cavity, which may be a resonant cavity, formed between the first and second reflectors. The multimode region comprises a flared region extending from the multimode region first end. A tuning current may be applied to the grating reflector to adjust the wavelength response of the grating reflector. At least a portion of the single mode region pumped and, also, a phasing current may be applied to a portion of the single mode region to adjust the optical path length of the cavity to match the phase of the light propagating in the cavity to a selected wavelength. The multimode diverging region may be differentially pumped.
REFERENCES:
patent: 4251780 (1981-02-01), Scifres et al.
patent: 4744089 (1988-05-01), Montroll et al.
patent: 4942585 (1990-07-01), Ungar
patent: 5175643 (1992-12-01), Andrews
patent: 5260822 (1993-11-01), Missaggia et al.
patent: 5517517 (1996-05-01), Liou
patent: 5657339 (1997-08-01), Fukunaga
Mehuys David G.
Scifres Donald R.
Welch David F.
Gallagher & Lathrop
Lathrop David N.
Sanghavi Hemang
SDL Inc.
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