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Collective light emission :many quantum emitters /

"Version: 20200901"--Title page verso.Includes bibliographical references.1. Introduction -- 1.1. How does light meet with matter? -- 1.2. Collectivity that matters -- 1.3. At the boundary from quantum to classical worlds2. Light-induced dipole-dipole interactions -- 2.1. Reservoir interaction volume -- 2.2. Resonant dipole-dipole interactions in free space -- 2.3. Two-dimensional dipole-dipole interactions -- 2.4. One-dimensional dipole-dipole interactions3. Construction of Hilbert space -- 3.1. Dicke-Hilbert space -- 3.2. Singly-excited Hilbert space -- 3.3. Multiply-excited Hilbert space4. Cooperative spontaneous emissions: super- and subradiance -- 4.1. Recent progress -- 4.2. Methodology -- 4.3. One-dimensional atomic array -- 4.4. Three-dimensional atomic array -- 4.5. Multiphoton cooperative spontaneous emissions5. Cooperative light scattering -- 5.1. Far-field light scattering -- 5.2. Light scattering from two atoms -- 5.3. One-dimensional array -- 5.4. Single ring6. Subradiance in a chirally coupled atomic chain -- 6.1. A chiral coupling matrix -- 6.2. Subradiance dynamics -- 6.3. Quantum-coherence-enhanced subradiance -- 6.4. Steady states under weak excitations7. Applications in quantum information processing and quantum simulation -- 7.1. Quantum information processing -- 7.2. Quantum simulation8. Future perspectives -- 8.1. Complexity of a macroscopic system -- 8.2. Strong coupling regime -- 8.3. Exotic collective states and many-body phenomena.Collective Light Emission: Many quantum emitters covers several recent essential topics related to collective light emissions from many quantum emitters. Light-matter interactions in quantum systems form one of the complicated dynamical systems. Owing to its complexity, researchers have developed new means and techniques to investigate such systems with better control of parameters and better precision to observe interesting phenomenon. These advancements provide new insights to this research direction, and this book dives into the recent progress and future of it. The book includes the basic mechanism, well-known super- and sub-radiant phenomena in free space and nanophotonic platform, applications in quantum systems, and perspectives to future directions. Additionally, several updates of this ongoing research and challenges confronted in experiments and theories are included.Researchers, professors, scientists, and graduate students in quantum optics.Also available in print.Mode of access: World Wide Web.System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader.Hsiang-Hua Jen received a bachelor degree in physics from National Taiwan University in 2000 and obtained his PhD degree in 2010 from Georgia Institute of Technology in the United States. He is initially trained in theoretical quantum optics, and now actively investigates the collective effects of light-matter interactions along with other interesting subjects of long-distance quantum communication and spinor Bose gas. Starting in March 2020, he becomes an assistant research fellow in the Institute of Atomic and Molecular Sciences, Academia Sinica, Taiwan (Republic of China). He has contributed 30 peer-reviewed papers and is recently selected as 2019 IOP Outstanding Reviewer for Journal of Physics B: Atomic, Molecular and Optical Physics.Title from PDF title page (viewed on November 6, 2020).

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Series Title
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Call Number
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Publisher
: .,
Collation
1 online resource (various pagings) :illustrations (some color).
Language
English
ISBN/ISSN
9780750326995
Classification
535.15
Content Type
-
Media Type
-
Carrier Type
-
Edition
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Subject(s)
Optical physics.
SCIENCE / Physics / Optics & Light.
Quantum optics.
Light sources.
Specific Detail Info
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