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A prominent aspect of quantum theory, tunneling arises in a variety of contexts across several fields of study, including nuclear, atomic, molecular, and optical physics and has led to technologically relevant applications in mesoscopic science. Exploring mechanisms and consequences, Dynamical Tunneling: Theory and Experiment presents the work of international experts who discuss the considerable progress that has been achieved in this arena in the past two decades.
Highlights in this volume include:
A historical introduction and overview of dynamical tunneling, with case histories ranging from simple and emblematic to complex and involving experimental counterparts
An emphasis on the semiclassical theory of tunneling put forth by various research groups using different approaches
Developments in tunneling with cold atoms and molecular manifestations
Advances in our ability to perform delicate and precise experiments in atomic systems
The visualization and control of photonic tunneling
The role of dynamical tunneling on energy flow and localization in large molecules
In the near future, complex tunneling processes occurring in few and many-body systems will be able to be predicted, understood, and controlled. Comprising all relevant topics and authors in the context of present-day research on dynamical tunneling, this self-contained volume provides readers with the basis for further discovery into the potential of this powerful phenomenon.
List of contents
Perspectives on Dynamical Tunneling - Past, Present, and Future. Semiclassical Theories of Dynamical Tunneling. Cold Bosonic Atoms in Double Wells. Tunneling of Bose-Einstein Condensates in Optical Lattices. Dynamical Tunneling, Intramolecular Energy Flow, and Quantum Ergodicity. Quantum Discrete Breathers. Dynamical Tunneling in Optical and Microwave Cavities. Dynamical Tunneling and Conductance in Quantum Dots.
About the author
Srihari Keshavamurthy is a theoretical chemist with the department of chemistry at the Indian Institute of Technology Kanpur, India. He received his BSc degree from the University of Madras, MS from Villanova University, and PhD from University of California, Berkeley. After a postdoc at Cornell, he joined IIT Kanpur in December 1996. Srihari’s primary interest is the mechanisms of chemical reaction dynamics and control from the classical-quantum correspondence perspective.
Peter Schlagheck
is a theoretical physicist with the department of physics at the University of Liège. He received his PhD in 1999 at the Technical University of Munich. After a postdoc at the Université Paris Sud from 1999 to 2001, he became assistant at University of Regensburg in 2002. In 2009, he obtained a faculty position at the University of Liège. Schlagheck’s research interests include the transport of ultracold atoms and tunneling in the presence of chaos.
