Hardcover ISBN:  9780821848289 
Product Code:  PSAPM/68 
List Price:  $129.00 
MAA Member Price:  $116.10 
AMS Member Price:  $103.20 
eBook ISBN:  9780821892848 
Product Code:  PSAPM/68.E 
List Price:  $125.00 
MAA Member Price:  $112.50 
AMS Member Price:  $100.00 
Hardcover ISBN:  9780821848289 
eBook: ISBN:  9780821892848 
Product Code:  PSAPM/68.B 
List Price:  $254.00 $191.50 
MAA Member Price:  $228.60 $172.35 
AMS Member Price:  $203.20 $153.20 
Hardcover ISBN:  9780821848289 
Product Code:  PSAPM/68 
List Price:  $129.00 
MAA Member Price:  $116.10 
AMS Member Price:  $103.20 
eBook ISBN:  9780821892848 
Product Code:  PSAPM/68.E 
List Price:  $125.00 
MAA Member Price:  $112.50 
AMS Member Price:  $100.00 
Hardcover ISBN:  9780821848289 
eBook ISBN:  9780821892848 
Product Code:  PSAPM/68.B 
List Price:  $254.00 $191.50 
MAA Member Price:  $228.60 $172.35 
AMS Member Price:  $203.20 $153.20 

Book DetailsProceedings of Symposia in Applied MathematicsVolume: 68; 2010; 348 ppMSC: Primary 81; 68; 57; 20
This volume is based on lectures delivered at the 2009 AMS Short Course on Quantum Computation and Quantum Information, held January 3–4, 2009, in Washington, D.C.
Part I of this volume consists of two papers giving introductory surveys of many of the important topics in the newly emerging field of quantum computation and quantum information, i.e., quantum information science (QIS). The first paper discusses many of the fundamental concepts in QIS and ends with the curious and counterintuitive phenomenon of entanglement concentration. The second gives an introductory survey of quantum error correction and fault tolerance, QIS's first line of defense against quantum decoherence.
Part II consists of four papers illustrating how QIS research is currently contributing to the development of new research directions in mathematics. The first paper illustrates how differential geometry can be a fundamental research tool for the development of compilers for quantum computers. The second paper gives a survey of many of the connections between quantum topology and quantum computation. The last two papers give an overview of the new and emerging field of quantum knot theory, an interdisciplinary research field connecting quantum computation and knot theory. These two papers illustrate surprising connections with a number of other fields of mathematics.
In the appendix, an introductory survey article is also provided for those readers unfamiliar with quantum mechanics.
ReadershipGraduate students and research mathematicians interested in quantum information theory and its relations to new research areas in mathematics.

Table of Contents

Quantum information science

Patrick Hayden — Concentration of measure effects in quantum information [ MR 2762144 ]

Daniel Gottesman — An introduction to quantum error correction and faulttolerant quantum computation [ MR 2762145 ]

Contributions to mathematics

Howard E. Brandt — Riemannian geometry of quantum computation [ MR 2762146 ]

Louis H. Kauffman and Samuel J. Lomonaco, Jr. — Topological quantum information theory [ MR 2762147 ]

Samuel J. Lomonaco and Louis H. Kauffman — Quantum knots and mosaics [ MR 2762148 ]

Samuel J. Lomonaco and Louis H. Kauffman — Quantum knots and lattices, or a blueprint for quantum systems that do rope tricks [ MR 2762149 ]

Appendix

Samuel J. Lomonaco, Jr. — A Rosetta stone for quantum mechanics with an introduction to quantum computation [ MR 2762150 ]


Additional Material

RequestsReview Copy – for publishers of book reviewsPermission – for use of book, eBook, or Journal contentAccessibility – to request an alternate format of an AMS title
 Book Details
 Table of Contents
 Additional Material
 Requests
This volume is based on lectures delivered at the 2009 AMS Short Course on Quantum Computation and Quantum Information, held January 3–4, 2009, in Washington, D.C.
Part I of this volume consists of two papers giving introductory surveys of many of the important topics in the newly emerging field of quantum computation and quantum information, i.e., quantum information science (QIS). The first paper discusses many of the fundamental concepts in QIS and ends with the curious and counterintuitive phenomenon of entanglement concentration. The second gives an introductory survey of quantum error correction and fault tolerance, QIS's first line of defense against quantum decoherence.
Part II consists of four papers illustrating how QIS research is currently contributing to the development of new research directions in mathematics. The first paper illustrates how differential geometry can be a fundamental research tool for the development of compilers for quantum computers. The second paper gives a survey of many of the connections between quantum topology and quantum computation. The last two papers give an overview of the new and emerging field of quantum knot theory, an interdisciplinary research field connecting quantum computation and knot theory. These two papers illustrate surprising connections with a number of other fields of mathematics.
In the appendix, an introductory survey article is also provided for those readers unfamiliar with quantum mechanics.
Graduate students and research mathematicians interested in quantum information theory and its relations to new research areas in mathematics.

Quantum information science

Patrick Hayden — Concentration of measure effects in quantum information [ MR 2762144 ]

Daniel Gottesman — An introduction to quantum error correction and faulttolerant quantum computation [ MR 2762145 ]

Contributions to mathematics

Howard E. Brandt — Riemannian geometry of quantum computation [ MR 2762146 ]

Louis H. Kauffman and Samuel J. Lomonaco, Jr. — Topological quantum information theory [ MR 2762147 ]

Samuel J. Lomonaco and Louis H. Kauffman — Quantum knots and mosaics [ MR 2762148 ]

Samuel J. Lomonaco and Louis H. Kauffman — Quantum knots and lattices, or a blueprint for quantum systems that do rope tricks [ MR 2762149 ]

Appendix

Samuel J. Lomonaco, Jr. — A Rosetta stone for quantum mechanics with an introduction to quantum computation [ MR 2762150 ]