Nanophotonics with Diamond and Silicon Carbide for Quantum Technologies

Herausgeber: Agio, Mario; Castelletto, Stefania

• Broschiertes Buch

Produktbeschreibung

Nanophotonics with Diamond and Silicon Carbide for Quantum Technologies provides an in-depth overview of key developments in diamond and silicon carbide photonics to enable spin-photon interfaces, quantum computing, quantum imaging, and quantum sensing. Written by world experts, chapters discuss nanophotonics effects (atomic size point center properties in the materials), fabrication of photonic components and integrated photonics circuits, photonics and nanophotonics enabling quantum sensing, and quantum information and networks via spin-photon interface. This book is a valuable resource to researchers and professionals interested on the fundamentals, trends, and diamond and silicon carbide applications in the quantum technology industry.

Produktdetails

• Verlag: Elsevier Science
• Seitenzahl: 438
• Erscheinungstermin: 30. Mai 2025
• Englisch
• Abmessung: 279mm x 216mm x 23mm
• Gewicht: 1179g
• ISBN-13: 9780443137174
• ISBN-10: 044313717X
• Artikelnr.: 70889899

Inhaltsangabe

1. Introduction
2. Diamond growth and properties for quantum technologies
3. Micro- and nano-fabrication techniques for single crystal diamond
photonics
4. Quantum micro-nano devices fabricated in diamond by femtosecond laser
and ion irradiation
5. Ab-initio simulations of color centers in diamond
6. Color centers in diamond for quantum photonics
7. Diamond spin-photon interface
8. Diamond integrated quantum photonics
9. Diamond color centers for enhanced quantum sensing
10. Fluorescent Nanodiamonds
11. Diamond single photon source for metrology: focus on radiometry and
imaging
12. Diamond laser threshold magnetometer
13. Silicon carbide growth and properties for quantum technologies
14. Color centers in silicon carbide
15. Defect engineering and charge-state control of color centers in silicon
carbide
16. Silicon carbide spin-photon interface
17. Silicon carbide photonics technologies and fabrication methods
18. Quantum nonlinear photonics in silicon carbide
19. Electrically driven quantum emitters in diamond and silicon carbide
20. Spin defects in silicon carbide for maser applications
21. Conclusions and Outlook