Description
Book SynopsisThis book approaches condensed matter physics from the perspective of quantum information science, focusing on systems with strong interaction and unconventional order for which the usual condensed matter methods like the Landau paradigm or the free fermion framework break down. Concepts and tools in quantum information science such as entanglement, quantum circuits, and the tensor network representation prove to be highly useful in studying such systems. The goal of this book is to introduce these techniques and show how they lead to a new systematic way of characterizing and classifying quantum phases in condensed matter systems.
The first part of the book introduces some basic concepts in quantum information theory which are then used to study the central topic explained in Part II: local Hamiltonians and their ground states. Part III focuses on one of the major new phenomena in strongly interacting systems, the topological order, and shows how it can essential
Trade Review
“Quantum information meets quantum matter is bound to hold an honored place on the bookshelves of many scientists for years to come.’ From myself, I would add that of students and PhD students, I do believe!” (Eugene Kryachko, zbMATH 1423.81010, 2019)
Table of Contents
Part I Basic Concepts in Quantum Information Theory
1 Correlation and Entanglement.
2 Evolution of Quantum Systems.
3 Quantum Error-Correcting Codes.
Part II Local Hamiltonians, Ground States and Many-body Entanglement.
4 Local Hamiltonians and Ground States.
5 Gapped Quantum Systems and Entanglement Area Law.
Part III Topological order and Long-Range Entanglement.
6 Introduction to Topological order.
7 Local Transformations and Long-Range Entanglement.
Part IV Gapped Topological Phases and Tensor Network.
8 Matrix Product State and 1D Gapped Phase.
9 Tensor Product States and 2D Gapped Phases.
10 Symmetry Protected Topological Phases.
Part V Outlook.
11 A Unification of Information and Matter.
