Non-classical States of Light

• Verfasst von: Rivera-Dean, Javier [VerfasserIn]
• Titel: Non-classical States of Light
• Titelzusatz: Generation via Strong-Field Processes and Applications in Quantum Key Distribution
• Verf.angabe: by Javier Rivera-Dean
• Ausgabe: 1st ed. 2024.
• Verlagsort: Cham
• Verlagsort: Cham
• Verlag: Springer Nature Switzerland
• Verlag: Imprint: Springer
• E-Jahr: 2024
• Jahr: 2024.
• Jahr: 2024.
• Umfang: 1 Online-Ressource(XX, 300 p. 93 illus., 84 illus. in color.)
• Gesamttitel/Reihe: Springer Theses, Recognizing Outstanding Ph.D. Research
• ISBN: 978-3-031-73769-5
• DOI: doi:10.1007/978-3-031-73769-5
• Datenträger: Online-Ressource
• Sprache: eng
• Bibliogr. Hinweis: Erscheint auch als : Druck-Ausgabe
• Bibliogr. Hinweis: Erscheint auch als : Druck-Ausgabe
• Bibliogr. Hinweis: Erscheint auch als : Druck-Ausgabe
• K10plus-PPN: 191575450X
• K10plus-PPN:
  Universitätsbibliothek
• Lokale URL UB: Zum Volltext

Abstract

Chapter 1.Introduction -- Chapter 2.Background -- Chapter 3.Non-classical states of light after strong-laser field processes in atoms -- Chapter 4.Non-classical states of light after high-harmonic generation in molecular and solid systems -- Chapter 5.Non-classical states of light for Device-Independent Quantum Key Distribution -- Chapter 6.Conclusions -- Chapter 7.Additional material of Chapter 2 -- Chapter 8.Additional material of Chapter 3 -- Chapter 9.Additional material of Chapter 4 -- Chapter 10.Additional material of Chapter 5.

Abstract

This doctoral thesis has a dual focus. Firstly, it studies the generation of non-classical states of light through strong-field processes, where light-matter interactions involve light intensities contending with the forces binding electrons to their nuclei. This exploration demonstrates the utility of strong-field phenomena in generating non-classical states of light, with properties dependent on specific dynamics and materials involved in the excitation. Secondly, it investigates the constraints and prerequisites of non-classical light sources—beyond those studied in the first part—for advancing quantum communication applications,specifically in quantum key distribution. The aim here is to create a secret key exclusively known by the communicating parties for encrypting and decrypting messages. As a whole, this work serves as a foundational step towards leveraging strong-field physics as a prospective tool for quantum information science applications, as well as displaying the advantages and limitations of photonic-based setups for quantum key distribution. With its very clear style of presentation, the book is an essential reference for future researchers working in this field.