Hostname: page-component-586b7cd67f-gb8f7 Total loading time: 0 Render date: 2024-11-24T04:55:24.121Z Has data issue: false hasContentIssue false

Semiconductor Nanolasers by Qing Gu and Yeshaiahu Fainman

Published online by Cambridge University Press:  10 August 2018

Abstract

Type
Book Reviews
Copyright
Copyright © Materials Research Society 2018 

This introduction to the growing literature on nanolasers is self-contained, and sufficiently user-friendly to appeal to an intended audience that includes “graduate students, researchers and professionals in optoelectronics, photonics, applied physics, nanotechnology and materials science.” That broad reach is evident in the Introduction, which begins with a history of laser miniaturization and the fundamentals of laser action, and then uses the evolution of the microscale vertical-cavity surface-emitting laser (VCSEL) to highlight the challenges in photonic materials and optoelectronics found in photonic crystal defect-cavity lasers, nanowire, cavity-free and metal-dielectric-metal (MDM) lasers, and coherent sources based on surface plasmon amplification.

Succeeding chapters explicate critical technical issues in these nanolaser types, and cover optical cavity design, optimization of the principal mode structures, and operation of coaxial and MDM nanolasers in optical and plasmonic modes. Chapters 2, 4, and 5 cover nanolasers that incorporate metallic elements in photonic and plasmonic modes or as antennas to shape output radiation patterns. Chapter 7 covers electrically pumped nanolasers and analyzes indium phosphide devices. The focus on optical design and performance is complemented in chapter 8 by a detailed multiphysics design study of the thermal, electrical, and materials design issues for nanolasers. Chapters 9 and 10 deliver stimulating excursions into the realms of cavity-free lasers and inversionless exciton-polariton lasers.

The concluding chapter acknowledges that the engineering maturity or technological readiness of nanolasers requires a discussion of the emerging potential of nanolasers, rather than specific applications, in the context of integrated photonics platforms and waveguides. This recognizes that the technological utility of nanolasers ultimately rests on their chip-scale integration into photonic devices employing electrical pumping. From that perspective, the final section on silicon-compatible miniature lasers is appropriate and instructive.

Although not conceived as a textbook (e.g., the book lacks homework problems), parts of the monograph would be suitable for courses in photonics or quantum electronics. For example, chapter 3 on the Purcell effect treats a complicated topic with admirable clarity, augmented by Appendix A with a compact review of nonrelativistic quantum electrodynamics. Chapter 6 compares multiple-quantum well versus bulk semiconductor materials as optical-gain media, rendering itself as a course module on laser physics. Also, one could couple chapter 8 with Appendix C, which treats the thermal issues surrounding VCSELs using COMSOL Multiphysics software, as the basis for a project on thermal design of nanolaser components.

The authors are experts in this topical area and also have produced a substantial body of collaborative work. That history may well be at the heart of the impressive thematic, conceptual, and editorial coherence of the text.

Reviewer: Richard F. Haglund Jr., Department of Physics and Astronomy, Vanderbilt University, USA.

Footnotes

Cambridge University Press, 2017 332 pages, $155.00 (e-book $124.00) ISBN 9781107110489

References

Cambridge University Press, 2017 332 pages, $155.00 (e-book $124.00) ISBN 9781107110489