Distributed Bragg Reflectors for Vertical-Cavity Surface-Emitting Lasers

W.G. Breiland; A.A. Allerman; J.F. Klem; K.E. Waldrip

doi:10.1557/mrs2002.170

Abstract

Distributed Bragg reflectors (DBRs) not only serve as high-reflectance mirrors to define the laser cavity of a vertical-cavity surface-emitting laser (VCSEL), but they also must conduct electricity, confine currents, and provide a single-crystal template for the gain region of the laser. Basic optical and electrical properties of DBRs are presented in this article. Three examples of DBR structures used in VCSEL applications from the ultraviolet to the infrared are given to illustrate the complexity and range of materials science issues that are encountered in DBR growth. Fabrication issues are also discussed.

References

1.MacLeod, H.A., Thin-Film Optical Filters, 2nd ed. (McGraw-Hill, New York, 1989) p. 164.Google Scholar

2.Weber, J., Malloy, K., and Wang, S., IEEE Photon. Technol. Lett. 2 (1990) p. 162.CrossRef Google Scholar

3.Lear, K.L. and Schneider, R.P. Jr, Appl. Phys. Lett. 68 (1996) p. 605.CrossRef Google Scholar

4.Choquette, K.D., Schneider, R.P. Jr., Lear, K.L., and Geib, K.M., Electron. Lett. 30 (1994) p. 2043.CrossRef Google Scholar

5.Breiland, W.G. and Killeen, K.P., J. Appl. Phys. 78 (1995) p. 6726.CrossRef Google Scholar

6.Hou, H.Q., Choquette, K.D., Hammons, B.E., Breiland, W.G., Crawford, M.H., and Lear, K.L., in Proc. SPIE, Vol. 3003 (SPIE—The International Society for Optical Engineering, Belling-ham, WA, 1997) p. 34.Google Scholar

7.Choquette, K.D., Klem, J.F., Fischer, A.J., Blum, O., Allerman, A.A., Fritz, I.J., Kurtz, S.R., Breiland, W.G., Sieg, R., Geib, K.M., Scott, J.W., and Naone, R.L., Electron. Lett. 36 (2000) p. 1388.CrossRef Google Scholar

8.Hearne, S., Chason, E., Han, J., Floro, J.A., Figiel, J., Hunter, J., Amano, H., and Tsong, I.S.T., Appl. Phys. Lett. 74 (1999) p. 356.CrossRef Google Scholar

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Agarwal, V. and del Rı́o, J. A. 2003. Tailoring the photonic band gap of a porous silicon dielectric mirror. Applied Physics Letters, Vol. 82, Issue. 10, p. 1512.

Qian, M. Bao, X.Q. Wang, L.W. Lu, X. Shao, J. and Chen, X.S. 2006. Structural tailoring of multilayer porous silicon for photonic crystal application. Journal of Crystal Growth, Vol. 292, Issue. 2, p. 347.

Wang, Zhejin Zhang, Jie Xu, Shaohui Wang, Lianwei Cao, Zhishen Zhan, Peng and Wang, Zhenlin 2007. 1D partially oxidized porous silicon photonic crystal reflector for mid-infrared application. Journal of Physics D: Applied Physics, Vol. 40, Issue. 15, p. 4482.

Estevez, J. O. Arriaga, J. Blas, A. Méndez and Agarwal, V. 2008. Omnidirectional photonic bandgaps in porous silicon based mirrors with a Gaussian profile refractive index. Applied Physics Letters, Vol. 93, Issue. 19,

Fengjuan Miao Jie Zhang Shaohui Xu Lianwei Wang Junhao Chu Zhishen Cao Peng Zhan and ZhenlinWang 2008. Fabrication of a reflective mirror within wide incidence angles for mid-infrared wavelength. p. 173.

Estevez, J. O. Arriaga, J. Méndez Blas, A. and Agarwal, V. 2009. Enlargement of omnidirectional photonic bandgap in porous silicon dielectric mirrors with a Gaussian profile refractive index. Applied Physics Letters, Vol. 94, Issue. 6, p. 061914.

Medvedev, A. V. Dukin, A. A. Feoktistov, N. A. and Golubev, V. G. 2017. A spherical distributed Bragg reflector based on a-Si1–xCx: H and a-SiO2 layers. Technical Physics Letters, Vol. 43, Issue. 10, p. 885.

Manfredi, G. Lova, P. Di Stasio, F. Rastogi, P. Krahne, R. and Comoretto, D. 2018. Lasing from dot-in-rod nanocrystals in planar polymer microcavities. RSC Advances, Vol. 8, Issue. 23, p. 13026.

Wang, QiuPin Xia, GuangQiong Tan, ShuLu Liu, Yang Liu, YanTing Zhao, MaoRong and Wu, ZhengMao 2022. Misestimation of the Performance in Vcsel-Based Reservoir Computing Experimental Systems with Optical Information Injection Resulted by High Surface Reflectivity. SSRN Electronic Journal ,

Wang, Qiupin Xia, Guangqiong Tan, Shulu Liu, Yang Liu, Yanting Zhao, Maorong and Wu, Zhengmao 2022. Misestimate of the performance in VCSEL-based reservoir computing systems with optical information injection by high surface reflectivity. Applied Optics, Vol. 61, Issue. 34, p. 10086.

Michałowski, Paweł Piotr Gębski, Marcin Śpiewak, Patrycja Kołkowski, Walery Pasternak, Iwona Głowadzka, Weronika Wasiak, Michał Czyszanowski, Tomasz and Strupiński, Włodzimierz 2024. Artifact-free secondary ion mass spectrometry profiling of a full vertical cavity surface emitting laser structure. Measurement, Vol. 225, Issue. , p. 114003.

Chen, Tzu-Ling Salij, Andrew Parrish, Katherine A. Rasch, Julia K. Zinna, Francesco Brown, Paige J. Pescitelli, Gennaro Urraci, Francesco Aronica, Laura A. Dhavamani, Abitha Arnold, Michael S. Wasielewski, Michael R. di Bari, Lorenzo Tempelaar, Roel and Goldsmith, Randall H. 2024. A 2D chiral microcavity based on apparent circular dichroism. Nature Communications, Vol. 15, Issue. 1,

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Distributed Bragg Reflectors for Vertical-Cavity Surface-Emitting Lasers

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This article has been cited by the following publications. This list is generated based on data provided by Crossref.

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Distributed Bragg Reflectors for Vertical-Cavity Surface-Emitting Lasers

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