Description
Book SynopsisThe first of its kind, this comprehensive resource explains the fundamental physics of semiconductor nanolasers along with details of their design, fabrication, and applications. This is essential reading for graduate students, researchers, and professionals in optoelectronics, applied photonics, physics, and materials science.
Trade Review'For many years, photonics has sought to emulate the enormous success of electronics in miniaturizing devices - specifically with the aim of creating photonic integrated circuits. Nanolasers are strong potential candidates for the role of optical source in photonic integrated circuits. This excellent book provides the first in-depth description of the challenges faced in creating such lasers … It is anticipated that this book will help accelerate the creation of photonic integrated circuits and sensors based on nanolasers.' K. Alan Shore, Optics and Photonics News
'This introduction to the growing literature on nanolaser is self-contained, and sufficiently user-friendly. … Although not conceived as a textbook, parts of the monograph would be suitable for courses in photonics or quantum electronics. … 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.' Richard F. Haglund, Jr, MRS Bulletin
Table of Contents1. Introduction; 2. Photonic mode metal-dielectric-metal based nanolasers; 3. Purcell effect and the evaluation of Purcell and spontaneous emission factors; 4. Plasmonic mode metal-dielectric-metal based nanolasers; 5. Antenna-inspired nano-patch lasers; 6. Active medium for semiconductor nanolasers: MQW vs. bulk gain; 7. Electrically pumped nanolasers; 8. Multi-physics design for nanolasers; 9. Cavity-free nanolaser; 10. Beyond nanolasers: inversionless exciton-polariton microlaser; 11. Application of nanolasers: photonic integrated circuits and other applications.
