Super-gain nanostructure with self-assembled well-wire complex energy-band engineering for high performance of tunable laser diodes

• Published in: Nanophotonics (Berlin, Germany) Vol. 12; no. 9; pp. 1763 - 1776
• Main Authors: Wang, Yuhong, Tai, Hanxu, Duan, Ruonan, Zheng, Ming, Lu, Wei, Shi, Yue, Zhang, Jianwei, Zhang, Xing, Ning, Yongqiang, Wu, Jian
• Format: Journal Article
• Language: English
• Published: Berlin De Gruyter 28.04.2023; Walter de Gruyter GmbH
• Subjects: indium-segregation effect; multi-atomic step effect; Nanostructure; optical gain; Quantum dots; Quantum wells; Self-assembly; Semiconductor lasers; semiconductor nanostructure; Spectra; tunable laser diodes; Tunable lasers; Wire
• ISSN: 2192-8614; 2192-8606; 2192-8614
• DOI: 10.1515/nanoph-2023-0013

Although traditional quantum-confined nanostructures e.g. regular quantum wells or quantum dots have achieved huge success in the field of semiconductor lasers for past decades, these traditional nanostructures are encountering the difficulty of enhancing device performance to a higher level due to their inherent gain bottleneck. In this paper, we are proposing a new super-gain nanostructure based on self-assembled well-wire complex energy-band engineering with InGaAs-based materials to break through the existing bottleneck. The nanostructure is constructed by utilizing the special strain-driven indium (In)-segregation and the growth orientation-dependent on-GaAs multi-atomic step effects to achieve the distinguished ultra-wide and uniform super-gain spectra. The structural details and its luminescence mechanism are investigated by multiple measurement means and theoretical modeling. The polarized gain spectra with the max fluctuation of <3 cm in 904 nm–998 nm for transverse electric (TE) mode and 904 nm–977 nm for transverse magnetic (TM) mode are simultaneously obtained with this nanostructure. It enables an ultra-low output power fluctuation of <0.7 dB and a nearly-constant threshold power throughout an ultra-wide wavelength range under a fixed injection level. It was difficult to realize these in the past. Therefore, the described super-gain nanostructure brings a brand-new chance of developing high performance of tunable laser diodes.