Infrared generation in semiconductor lasers

Details Infrared generation in semiconductor lasers Infrared generation in semiconductor lasers

2001-09-10

2004-08-24

Wong, Don (Department: 2828)

Coherent light generators

Particular active media

Semiconductor

C372S004000, C372S021000, C372S039000, C372S043010

Reexamination Certificate

active

06782020

ABSTRACT:

TECHNICAL FIELD OF THE INVENTION
This invention relates generally to the field of lasers and more specifically to infrared generation in semiconductor lasers.
BACKGROUND OF THE INVENTION
Some infrared semiconductor lasers use bipolar injection pumping and are based on narrow band-gap materials such as lead salts. These lasers, however, are usually less robust and less reliable than their shorter-wavelength counterparts based on GaAs or InP. Other infrared semiconductor lasers operate on intersubband, rather than interband transitions and have a unipolar (n-type) design. Intersubband lasers are based on InP or GaAs technology. These lasers, however, suffer from problems stemming from the need to maintain a large population of carriers on a very short-lived excited level. One problem is that a large pumping current may be needed to support laser operation, which may lead to overheating. As a result, these lasers typically operate in a pulsed manner or continuously only if significantly cooled. The second problem is that strong non-resonant losses of the infrared radiation are caused by free-carrier absorption and diffraction, which increase sharply at longer wavelengths. Consequently, it is difficult for semiconductor lasers to overcome losses for wavelengths above approximately 30 microns.
SUMMARY OF THE INVENTION
In accordance with the present invention, a method and device for infrared generation are provided that substantially eliminate or reduce the disadvantages and problems associated with previously developed devices and methods.
According to one embodiment of the present invention, infrared generation is disclosed. A first laser field having a first frequency associated with a first interband transition is generated. A second laser field having a second frequency associated with a second interband transition is generated. The generation of the first laser field occurs substantially simultaneously with the generation of the second laser field. A third laser field is generated from the first laser field and the second laser field. The third laser field has a third frequency associated with an intersubband transition. The third frequency is substantially equivalent to a difference between the second frequency and the first frequency.
A technical advantage of one embodiment of the present invention may be that infrared generation is achieved without population inversion on the operating intraband transition. This is achieved with the aid of laser fields simultaneously generated on the interband transitions, which serve as the coherent drive for the frequency down-conversion to the infrared region.
A technical advantage of another embodiment may be that the embodiment employs drive fields that are self-generated in the same laser cavity, instead of using external drive fields. This eliminates problems associated with an external drive such as beam overlap, drive absorption, and spatial inhomogeneity problems.
A technical advantage of another embodiment may be the enhancement of nonlinear wave mixing near a resonance with an intersubband transition. The efficiency of wave mixing increases with approaching resonance inversely proportional to the detuning from resonance and reaches the limiting quantum efficiency corresponding to one infrared photon per one drive field photon.
A technical advantage of another embodiment may be the cancellation of resonance one-photon absorption for the generated infrared radiation due to coherence effects provided by self-generated drive fields. This happens when two-photon stimulated processes prevail over one-photon absorption.
Other technical advantages are readily apparent to one skilled in the art from the following figures, descriptions, and claims. Embodiments of the invention may include none, some, or all of the technical advantages.


REFERENCES:
patent: 5300789 (1994-04-01), Gorfinkel et al.
patent: 5799026 (1998-08-01), Meyer et al.
patent: 5898720 (1999-04-01), Yamamoto et al.
patent: 6404791 (2002-06-01), Yang
patent: 6501783 (2002-12-01), Capasso et al.
Chui, H.C. et al., “Tunable Mid-Infrared Generation by Mixing of Near-Infrared Wavelengths in Intersubband Quantum Wells” Oct. 3-Nov. 3, 1994, LEOS '94 Conference Proceedings. IEEE, vol. 1, 175-176.*
Possibility of the Amplification of Electromagnetic Waves in a Semiconductor With a Superlattice, R. F. Kazarinov and R. A. Suris, Soviet Physics—Semiconductors, vol. 5, No. 4, Oct. 1971, pp. 707-709.
Quantum Cascade Laser, Jerome Faist, Federico Capasso, Deborah L. Sivco, Carlo Sirtori, Albert L. Hutchinson, Alfred Y. Cho, SCIENCE, vol. 264, Apr. 22, 1994, pp. 553-556.
Possibility of Room Temperature Intra-Band Lasing in Quantum Dot Structures Placed in High-Photon Density Cavities, Jasprit Singh, IEEE Photonics Technology Letters, vol. 8, No. 4, Apr. 1996, pp. 488-490.
Optics & Photonics News, Oct. 1999, Society of America, pp. 32-37.
Lasers without Inversion: Interference of Lifetime-Broadened Resonances, S. E. Harris, Physical Review Letters, vol. 62, No. 9, Feb. 27, 1989, pp. 1033-1036.
Coherent amplification of an ultrashort pulse in a three-level medium without a population inversion, O.A. Kocharovskaya and Ya. I. Khanin, Institute of Applied Physics, Academy of Sciences of the USSR, JETP Lett., vol. 48, No. 11, Dec. 10, 1988, pp. 631-635.
Degenerate Quantum-Beat Laser: Lasing without Inversion and Inversion without Lasing, Marlan O. Scully and Shi-Yao Zhu, Physical Review Letters, vol. 62, No. 24, Jun. 12, 1989, pp. 2813-2816.
Amplification and lasing without inversion, Olga Kocharovskaya, Physics Reports, Elsevier Science Publishers B.V., 1992, pp. 175-190.
Semiconductor lasers without population inversion, A. Imamoglu and R. J. Ram, Optics Letters, vol. 19, No. 21, Nov. 1, 1994, pp. 1744-1746.
Quantum Interference in Semiconductor Quantum Wells, H. Schmidt, D.E. Nikonov, K. L. Campman, K. D. Maranowski, A. C. Gossard, and A. Imamoglu, Lasing Without Inversion and Interference Phenomena in Atomic Systems, Laser Physics, vol. 9, No. 4, 1999, pp. 797-812.
Coherent population trapping in cesium: Dark lines and coherent microwave emission, Jacques Vanier, Aldo Godone, and Filippo Levi; Physical Review A, vol. 58, No. 3, Sep. 1998; pp. 2345-2358.
Widely separate wavelength switching of single quantum well laser diode by injection-current control, Yasunori Tokuda, Noriaki Tsukada, Kenzo Fujiwara, Koichi Hamanaka, and Takashi Nakayama, Appl. Phys. Lett. 49 (24), Dec. 15, 1986, 1986 American Institute of Physics, pp. 1629-1631.
Second quantized state oscillation and wavelength switching in strained-layer multiquantum-well lasers, T. R. Chen, Yuhua Zhuang, Y.J. Xu, B. Zhao, and A. Yariv, J. Ungar, Se Oh, Appl. Phys. Lett 60 (24), Jun. 15, 1992, 1992 American Insitute of Physics, pp. 2954-2956.
Intraband Relaxation Time in Quantum-Well Lasers, Masahiro Asada, IEEE Journal of Quantum Electronics, vol. 25, No. 9, Sep. 1989, pp. 2019-2026.
Density dependence of carrier-carrier-induced intersubband scattering in GaAs/AlxGa1-xAs quantum wells, M. Hartig, J.D. Ganiere, P.E. Selbmann, and B. Deveaud; Physical Review B, vol. 60, No. 3, Jul. 15, 1999-1, The American Phyisical Society, pp. 1500-1503.
Low-loss Al-free waveguides for unipolar semiconductor lasers; C. Sirtoli, P. Kruck, S. Barbieri, H. Page, J. Nagle, M. Beck, J. Faist, U. Oesterie, Applied Physics Letters, vol. 75, No. 25, Dec. 20, 1999, 1999 American Institute of Physics, pp. 3911-3913.
PTC Notification of Transmittal of the International Search Report or the Declaration, mailed Aug. 16, 2002, including International Search Report re PCT/US 01/28289 (6 pgs).*
Kastalsky, A, “Infrared Intraband Laser Induced in a Multiple-Quantum-Well Interband Laser,”IEEE Journal of Quantum Electronics, IEEE Inc. NY, vol. 29 #4, pp. 1112-1115, Apr. 1993.*
Spencer, et al., “Quantum Well Structures for Intersubband Semiconductor Lasers,”International Journal of Optoelectronics(Incl. Optical Computing & Processing), London G.B., vol. 10, No. 5, pp. 393-400, Sep. 1995.*
Petrov, et al., “Widely Tunable Continuous-Wave Mid-Infrared Laser Sourc

Affiliated with

Also associated with

Rating

Infrared generation in semiconductor lasers does not yet have a rating. At this time, there are no reviews or comments for this patent.

If you have personal experience with Infrared generation in semiconductor lasers, we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Infrared generation in semiconductor lasers will most certainly appreciate the feedback.

Rate now

Comments { 0 }

Profile ID: LFUS-PAI-O-3346068