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Abstract
It is demonstrated that both SMG (shadow masked growth) and SG (selective growth) together with the use of QWs (quantum wells) can change the bandgap of InP-based materials laterally over the substrate. The thickness change that can be obtained with both techniques and the corresponding deviation from stoichiometry are competitive. The authors present the basic principle of both techniques and the basic characteristics (thickness and composition change). They have fabricated a multiwavelength laser array using SMG with a wavelength span of 130 nm around 1550 nm.

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MLA
Coudenys, Geert, et al. “Lateral Bandgap Engineering for InP-Based Photonic Integrated Circuits.” LEOS 1992 Summer Topical Meeting Digest on Broadband Analog and Digital Optoelectronics, Optical Multiple Access Networks, Integrated Optoelectronics, and Smart Pixels, Proceedings, IEEE, 1992, pp. 202–05, doi:10.1109/ICIPRM.1992.235604.
APA
Coudenys, G., Moerman, I., Zhu, Y., Van Daele, P., & Demeester, P. (1992). Lateral bandgap engineering for InP-based photonic integrated circuits. LEOS 1992 Summer Topical Meeting Digest on Broadband Analog and Digital Optoelectronics, Optical Multiple Access Networks, Integrated Optoelectronics, and Smart Pixels, Proceedings, 202–205. https://doi.org/10.1109/ICIPRM.1992.235604
Chicago author-date
Coudenys, Geert, Ingrid Moerman, Y. Zhu, Peter Van Daele, and Piet Demeester. 1992. “Lateral Bandgap Engineering for InP-Based Photonic Integrated Circuits.” In LEOS 1992 Summer Topical Meeting Digest on Broadband Analog and Digital Optoelectronics, Optical Multiple Access Networks, Integrated Optoelectronics, and Smart Pixels, Proceedings, 202–5. IEEE. https://doi.org/10.1109/ICIPRM.1992.235604.
Chicago author-date (all authors)
Coudenys, Geert, Ingrid Moerman, Y. Zhu, Peter Van Daele, and Piet Demeester. 1992. “Lateral Bandgap Engineering for InP-Based Photonic Integrated Circuits.” In LEOS 1992 Summer Topical Meeting Digest on Broadband Analog and Digital Optoelectronics, Optical Multiple Access Networks, Integrated Optoelectronics, and Smart Pixels, Proceedings, 202–205. IEEE. doi:10.1109/ICIPRM.1992.235604.
Vancouver
1.
Coudenys G, Moerman I, Zhu Y, Van Daele P, Demeester P. Lateral bandgap engineering for InP-based photonic integrated circuits. In: LEOS 1992 Summer Topical Meeting Digest on Broadband Analog and Digital Optoelectronics, Optical Multiple Access Networks, Integrated Optoelectronics, and Smart Pixels, Proceedings. IEEE; 1992. p. 202–5.
IEEE
[1]
G. Coudenys, I. Moerman, Y. Zhu, P. Van Daele, and P. Demeester, “Lateral bandgap engineering for InP-based photonic integrated circuits,” in LEOS 1992 Summer Topical Meeting Digest on Broadband Analog and Digital Optoelectronics, Optical Multiple Access Networks, Integrated Optoelectronics, and Smart Pixels, Proceedings, NEWPORT, RI, 1992, pp. 202–205.
@inproceedings{225873,
  abstract     = {{It is demonstrated that both SMG (shadow masked growth) and SG (selective growth) together with the use of QWs (quantum wells) can change the bandgap of InP-based materials laterally over the substrate. The thickness change that can be obtained with both techniques and the corresponding deviation from stoichiometry are competitive. The authors present the basic principle of both techniques and the basic characteristics (thickness and composition change). They have fabricated a multiwavelength laser array using SMG with a wavelength span of 130 nm around 1550 nm.}},
  author       = {{Coudenys, Geert and Moerman, Ingrid and Zhu, Y. and Van Daele, Peter and Demeester, Piet}},
  booktitle    = {{LEOS 1992 Summer Topical Meeting Digest on Broadband Analog and Digital Optoelectronics, Optical Multiple Access Networks, Integrated Optoelectronics, and Smart Pixels, Proceedings}},
  isbn         = {{0780305221}},
  language     = {{eng}},
  location     = {{NEWPORT, RI}},
  pages        = {{202--205}},
  publisher    = {{IEEE}},
  title        = {{Lateral bandgap engineering for InP-based photonic integrated circuits}},
  url          = {{http://doi.org/10.1109/ICIPRM.1992.235604}},
  year         = {{1992}},
}

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