Quantum Nano-Photonics

1. Front Matter

   Pages i-xvi

   PDF

2. Lectures

   1. Front Matter

      Pages 1-1

      PDF

   2. Chapter 1 Nanophotonics with and without Photons

      • Sergey V. Gaponenko

      Pages 3-16

   3. Chapter 2 Non-reciprocity in Parametrically Modulated Systems

      • Martin Frimmer, Lukas Novotny

      Pages 17-25

   4. Chapter 3 Nanophosphors: From Rare Earth Activated Multicolor-Tuning to New Efficient White Light Sources

      • Maura Cesaria, Baldassare Di Bartolo

      Pages 27-77

   5. Chapter 4 Non-radiative Processes in Crystals and Nanocrystals

      • John M. Collins

      Pages 79-95

   6. Chapter 5 Quantum Aspects of Biophotonics

      • Jean-Pierre Wolf

      Pages 97-116

   7. Chapter 6 Simulations in Nanophotonics

      • Antonino Calà Lesina, Joshua Baxter, Pierre Berini, Lora Ramunno

      Pages 117-131

   8. Chapter 7 Terahertz Nanoscale Science and Technology

      • John W. Bowen

      Pages 133-148

   9. Chapter 8 Casimir Forces: Fundamental Theory, Computation, and Nanodevice Applications

      • Fabrizio Pinto

      Pages 149-180

   10. Chapter 9 Nanomaterials and Nanotechnologies for Photon Radiation Enhanced Cancer Treatment

       • Diana Adliene

       Pages 181-202

   11. Chapter 10 Fundamental Experiments and Quantum Technology Applications with Defect Centres in Diamond

       • Oliver Benson

       Pages 203-219

   12. Chapter 11 Emerging Fields of Colloidal Nanophotonics for Quality Lighting to Versatile Lasing

       • Hilmi Volkan Demir

       Pages 221-233

   13. Chapter 12 Semiconductor Nanophotonics Using Surface Polaritons

       • Thomas G. Folland, Joshua D. Caldwell

       Pages 235-254

   14. Chapter 13 Waveguide Integrated Superconducting Single Photon Detectors

       • Wolfram H. P. Pernice

       Pages 255-265

   15. Chapter 14 Whispering Gallery Mode Resonators as Opto-Mechanical Probes to Nanoparticle-Microcavity Interaction and Charge

       • Stephen Arnold, J. R. Lopez, E. Treasurer, K. M. Snyder, D. Keng

       Pages 267-276

   16. Chapter 15 Novel Aspects of the Fabry-Pérot Resonator

       • Markus Pollnau, Nur Ismail

       Pages 277-295

   17. Chapter 16 Performance of Nd3+ As Structural Probe of Rare-Earth Distribution in Transparent Nanostructured Glass-Ceramics

       • Rolindes Balda, Giulio Gorni, José J. Velázquez, María J. Pascual, Alicia Durán, Joaquín Fernández

       Pages 297-313

   18. Chapter 17 Research on the Yb3+ Ion Activated Cubic Molybdates and Molybdato-Tungstates for Optical Transparent Ceramics

       • M. Guzik, M. Bieza, E. Tomaszewicz, Y. Guyot, G. Boulon

       Pages 315-354

3. Short Seminars

   1. Front Matter

      Pages 355-355

      PDF

This book brings together more closely researchers working in the two fields of quantum optics and nano-optics and provides a general overview of the main topics of interest in applied and fundamental research. The contributions cover, for example, single-photon emitters and emitters of entangled photon pairs based on epitaxially grown semiconductor quantum dots, nitrogen vacancy centers in diamond as single-photon emitters, coupled quantum bits based on trapped ions, integrated waveguide superconducting nanowire single-photon detectors, quantum nano-plasmonics, nanosensing, quantum aspects of biophotonics and quantum metamaterials. The articles span the bridge from pedagogical introductions on the fundamental principles to the current state-of-the-art, and are authored by pioneers and leaders in the field. Numerical simulations are presented as a powerful tool to gain insight into the physical behavior of nanophotonic systems and provide a critical complement to experimental investigations and design of devices.

• Bio Photonics
• Nano Plasmonics
• Nanophotonic Systems
• Single photon emitters
• Emitters of entangled photon pairs
• Quantum nano-plasmonics
• Quantum aspects of biophotonics
• Quantum metamaterials
• NATO Science Proceedings

“The book will be useful to graduate students entering the field of quantum nanophotonics, as well as to those already working there but wanting to deepen their understanding or broaden their interests.” (Mark Fox, Optics & Photonics News, osa-opn.org, April 18, 2019)

• Department of Physics, Boston College, Chestnut Hill, USA

  Baldassare Di Bartolo, Luciano Silvestri

• IMM-CNR, Lecce, Italy

  Maura Cesaria

• Department of Physics and Astronomy, Wheaton College, Norton, USA

  John Collins

BALDASSARE DI BARTOLO 

Baldassare (friendly called Rino by friends) teaches physics at Boston College. He got his first degree in Industrial Engineering at the University of Palermo and followed his studies in Telecommunications and Radar Technique in Rome at the Superior Institute of Telecommunications and National Research Council, respectively.

After an insdustrial experience in Italy he moved to the United States where he gained a Ph.D. in Physics at the Massachusetts Institute of Technology.

An industrail experience in USA in the of laser physics was a prelude to his joining Boston College where he has been teaching since 1968.

He has written or edited some 36 books and published 170 articles. He has written two books of short stories in Italian.

He has been the director of the International Atomic and Molecular Spectroscopy of the Ettore Majorana center in Erice Sicily, Italy since 1974 

 

LUCIANO SILVESTRI

Luciano Silvestri received his Bachelor degree summa cum laudae from University of Massachusetts Boston in 2011 with a thesis in the thermalization of open quantum systems. In addition, as an undergrad he worked on the manufacturing and characterization of nano-electromechanical systems at Northeastern University.

Since 2011 he has been the Scientific Secretary of the International School of Atomic and Molecular Spectroscopy in Erice. He has been part of the organizing committee of the last four NATO ASI on Nano-Optics and Nano-Photonics, and three Workshops on Luminescence.

He is currently completing his Doctoral degree in theoretical physics at Boston College. His research interests have shifted to strongly coupled plasmas and nuclear fusion.

 

MAURA CESARIA 

Cesaria Maura graduated in Physics cum laude in 2008 at the University of Salento (Lecce, Italy) and received her Ph.D. degree in Physics in 2012 at the University of Salento (Lecce, Italy) with a thesis dealing with the experimental and theoretical characterization of very thin Cr-doped ITO films deposited by pulsed laser ablation for spintronic applications. Since then she has worked as a research fellow in Italy in the fields of material science and nanophotonics.

Her research activity at the Physics Department of the University of Salento have focused on laser-based deposition techniques (i.e., nano- and femto-second PLD, MAPLE) for depositing inorganic bulk materials and nanostructures as well as monolayer and multilayer of emitting polymers. In this framework her studies contributed to the understanding of the origin of itinerant ferromagnetism in Cr-doped ITO films as related to Cr-oxygen vacancy complexes, the development ex-novo of a theoretical algorithm and experimental spectrophotometric procedure for calculating a realistic absorption coefficient of (ultra)thin films covering transparent substrates that first and only one includes the non measurable contribution from the film-substrate interface, and the realization of the first white light emitting diode made by multi-layer polymeric thin films.

More recently, her activity as a fixed-term researcher at the IMM-CNR Institute (unit of Lecce-Italy) has focused on PDMS-based microfluidics and colloidal lithography techniques for sensing applications using plasmonic nanoparticles and short-range ordered nanohole arrays .

Since 2013 she contributes to the organization of the Spectroscopy School held at the Majorana Foundation (Erice, Italy) and collaborates with Prof. Di Bartolo (Boston College (MA, USA)) in spectroscopy studies of white-light emitting nanophosphors. 

JOHN COLLINS 

John Collins is a Professor of Physics at Wheaton College in Norton, MA USA. His research areas of interest involve the interaction of radiation with matter. He is an experimental physicist trained in the field of luminescence spectroscopy of solids doped with transition metal and rare earth ions. Specific areas of interest include energy transfer, nonradiative processes, luminescence in nanosystems, and plasmonic effects on radiative and non-radiative processes of excited ions in solids. Dr. Collins has co-edited several books and journal volumes on topics such as spectroscopy of solids, nano-optics, biophotonics, and visible and infrared phosphors, and has authored or co-authored numerous articles and book chapters. He has served as Chair of the Luminescence and Display Materials Division of the Electrochemical Society and currently serves on its Executive Committee, and also serves on the Organizing Committee of the International School of Atomic and Molecular Spectroscopy.

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