Maciej Lewenstein, Anna Sanpera and Dr. Verònica Ahufinger
Quantum computers, though not yet available on the market, will revolutionize the future of information processing. Quantum computers for special purposes like quantum simulators are already within reach. The physics of ultracold atoms, ions and molecules offer unprecedented possibilities of
control of quantum many body systems and novel possibilities of applications to quantum information processing and quantum metrology. Particularly fascinating is the possibility of using ultracold atoms in lattices to simulate condensed matter or even high energy physics.
This book
provides a complete and comprehensive overview of ultracold lattice gases as quantum simulators. It opens up an interdisciplinary field involving atomic, molecular and optical physics, quantum optics, quantum information, condensed matter and high energy physics. The book includes some introductory
chapters on basic concepts and methods, and then focuses on the physics of spinor, dipolar, disordered, and frustrated lattice gases. It reviews in detail the physics of artificial lattice gauge fields with ultracold gases. The last part of the book covers simulators of quantum computers. After a
brief course in quantum information theory, the implementations of quantum computation with ultracold gases are discussed, as well as our current understanding of condensed matter from a quantum information perspective.
1. Introduction
2. Statistical physics of condensed matter: basic concepts
3. Ultracold gases in optical lattices: Basic concepts
4. Quantum simulators of condensed matter
5. Bose Hubbard models: Methods of treatment
6. Fermi and Fermi-Bose Hubbard models: Methods of
treatment
7. Ultracold spinor atomic gases
8. Ultracold dipolar gases
9. Disordered ultracold atomic gases
10. Frustrated models in cold atom systems
11. Ultracold atomic gases in <"artificial>" gauge fields
12. Many body physics from a quantum information perspective
13.
Quantum information with lattice gases
14. Detection of quantum systems realised with ultracold atoms
15. Summary and future perspectives
Bibliography
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Maciej Lewenstein has been an ICREA professor at the Institut de Ciències Fotòniques in Castelldefels since 2005 where he leads the quantum optics theory group. In 2007 he won the Humbolt research award, Germany. In 2008 he obtained the Advance Research Grant from the European Community and in
2010 he won the first Harmburger Prize for his contributions in theoretical physics. His interests range from traditional quantum optics through to physics of cold gases and quantum information to physics of ultra intense laser fields. Anna Sanpera has been an ICREA professor in the newly formed
group of Quantum Information and Quantum Phenomena at the Universitat Autònoma of Barcelona, Spain, since 2005. She is currently working on quantum information theory, physics ultra-cold gases and the interface between quantum theory and condensed matter. She is also interested in the connection
between quantum mechanics and biology. Verònica Ahufinger obtained an ICREA researcher position in 2005 and moved to the Universitat Autònoma of Barcelona. Since 2010 she has been a professor at the Universitat Autònoma of Barcelona. She is interested in the interplay between the physics of
ultracold atoms, quantum optics and condensed matter.
