Muutke küpsiste eelistusi

Introduction to Topological Quantum Matter & Quantum Computation [Pehme köide]

4.00/5 (5 hinnangut Goodreads-ist)
(West Virginia University, Morgantown, USA)
  • Formaat: Paperback / softback, 380 pages, kõrgus x laius: 234x156 mm, kaal: 453 g
  • Ilmumisaeg: 30-Jun-2020
  • Kirjastus: CRC Press
  • ISBN-10: 036757411X
  • ISBN-13: 9780367574116
Teised raamatud teemal:
  • Pehme köide
  • Hind: 72,09 €*
  • * saadame teile pakkumise kasutatud raamatule, mille hind võib erineda kodulehel olevast hinnast
  • See raamat on trükist otsas, kuid me saadame teile pakkumise kasutatud raamatule.
  • Kogus:
  • Lisa ostukorvi
  • Tasuta tarne
  • Lisa soovinimekirja
Introduction to Topological Quantum Matter & Quantum ComputationSuurem pilt
  • Formaat: Paperback / softback, 380 pages, kõrgus x laius: 234x156 mm, kaal: 453 g
  • Ilmumisaeg: 30-Jun-2020
  • Kirjastus: CRC Press
  • ISBN-10: 036757411X
  • ISBN-13: 9780367574116
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9780367574116.html
Märksõnad:
What is "topological" about topological quantum states? How many types of topological quantum phases are there? What is a zero-energy Majorana mode, how can it be realized in a solid state system, and how can it be used as a platform for topological quantum computation? What is quantum computation and what makes it different from classical computation?





Addressing these and other related questions, Introduction to Topological Quantum Matter & Quantum Computation provides an introduction to and a synthesis of a fascinating and rapidly expanding research field emerging at the crossroads of condensed matter physics, mathematics, and computer science. Providing the big picture, this book is ideal for graduate students and researchers entering this field as it allows for the fruitful transfer of paradigms and ideas amongst different areas, and includes many specific examples to help the reader understand abstract and sometimes challenging concepts. It explores the topological quantum world beyond the well-known topological insulators and superconductors and emphasizes the deep connections with quantum computation. It addresses key principles behind the classification of topological quantum phases and relevant mathematical concepts and discusses models of interacting and noninteracting topological systems, such as the torric code and the p-wave superconductor. The book also covers the basic properties of anyons, and aspects concerning the realization of topological states in solid state structures and cold atom systems.





Quantum computation is also presented using a broad perspective, which includes fundamental aspects of quantum mechanics, such as Bell's theorem, basic concepts in the theory of computation, such as computational models and computational complexity, examples of quantum algorithms, and elements of classical and quantum information theory.

Arvustused

"In the last twenty years, several themes have come to the forefront of quantum condensed matter physics research through cross-fertilization with other disciplines, such as: topological matter and its emergent quasiparticles, quantum information theory, and quantum computation. This new book from Tudor Stanescu provides a much needed comprehensive introduction to this area of research. Clearly written, it takes the reader from the relevant concepts in quantum mechanics, to physical realizations in cold atom systems and heterostructures, going through the necessary concepts and multiple examples. Written from a condensed matter physics perspective, it will be a valuable reference and will serve as an advanced textbook at the graduate level in this important disciplinary area." Gabriel Kotliar, Rutgers University

"This book is a sort of travel guide through topological quantum computation[ it] is composed of four parts, preliminaries that introduce quantum mechanics, part two that deals with topological phases of matter and part three that deals with theories of topological quantum matter. The last part, part four, introduces topological quantum computationThis book is essential for anyone interested in the exciting new field of topological quantum computation or any one interested in how a possible quantum computer can be realised based on the principles of topological quantum matter." Andreas Wichert, Lisboa, in Zentralblatt Math, Springer

Preface xiii
PART I Preliminaries: From Quantum Mechanics to Quantum Computation
Chapter 1 Quantum Theory: Some Fundamentals
3(34)
1.1 The Quantum Measurement Problem
4(3)
1.2 Operational Quantum Mechanics
7(10)
1.2.1 Noiseless quantum theory
9(1)
1.2.2 Noisy quantum theory
10(7)
1.3 Interpretations Of Quantum Mechanics, Reformulations, And Other Developments
17(8)
1.3.1 Interpretations and reformulations of quantum theory
17(3)
1.3.2 Generic framework for hidden variable theories
20(2)
1.3.3 Weak measurements and weak values
22(3)
1.4 Bell's Theorem
25(6)
1.4.1 Quantum entanglement and the EPR argument
25(1)
1.4.2 Local, quantum, and no-signaling correlations
26(3)
1.4.3 Bell inequalities
29(2)
1.5 Quantum Cats and quantum coins
31(6)
1.5.1 Bell experiments and loopholes
31(1)
1.5.2 The CHSH game
32(2)
1.5.3 The quantum Cheshire cat
34(3)
Chapter 2 The Geometric Phase
37(30)
2.1 Geometric Phases: Examples And Overview
38(7)
2.1.1 Classical and quantum holonomies
38(5)
2.1.2 Historical overview and conceptual distinctions
43(2)
2.2 Phase Changes During Cyclic Quantum Evolutions
45(10)
2.2.1 The Berry phase
45(6)
2.2.2 The non-Abelian adiabatic phase
51(2)
2.2.3 The Aharonov Anandan phase
53(2)
2.3 The Mathematical Structure Of Geometric Phases
55(12)
2.3.1 Basic definitions and examples
55(4)
2.3.2 Elementary introduction to fiber bundles
59(5)
2.3.3 Holonomy interpretations of geometric phases
64(3)
Chapter 3 Quantum Mechanics and Information Science
67(28)
3.1 Introduction
68(5)
3.2 Classical Information Theory
73(6)
3.3 Classical Theory Of Computation
79(9)
3.3.1 Computational models: The Turing machine
79(4)
3.3.2 Computational complexity
83(3)
3.3.3 Energy and computation
86(2)
3.4 Quantum Information, Quantum Computation, And Topological Quantum Matter
88(7)
PART II Topological Phases of Matter
Chapter 4 Symmetry and Topology in Condensed Matter Physics
95(24)
4.1 Themes In Many-Body Physics
96(3)
4.2 Landau Theory Of Symmetry Breaking
99(9)
4.2.1 Construction of the Landau functional
101(3)
4.2.2 Phases and phase transitions
104(4)
4.3 Topology: Mathematical Highlights
108(4)
4.4 Topological Order, Symmetry, And Quantum Entanglement
112(5)
4.5 Topology And Emergent Physics
117(2)
Chapter 5 Topological Insulators and Superconductors
119(36)
5.1 Introduction
120(2)
5.2 Symmetry Classification Of Generic Non-Interacting Hamiltonians
122(7)
5.2.1 Time-reversal symmetry
122(3)
5.2.2 Particle-hole and chiral symmetries
125(2)
5.2.3 Classification of random Hamiltonians
127(2)
5.3 Topological Classification Of Band Insulators And Superconductors
129(11)
5.3.1 The origin of topology in gapped non-interacting systems
131(3)
5.3.2 Classification of topological insulators and superconductors
134(6)
5.4 Topological Invariants: Chern Numbers, Winding Numbers, And Z2 Invariants
140(15)
5.4.1 Hall conductance and the Chern number
140(2)
5.4.2 Chern numbers and winding numbers
142(5)
5.4.3 The Z2 topological invariant
147(8)
Chapter 6 Interacting Topological Phases
155(32)
6.1 TOPOLOGICAL PHASES: ORGANIZING PRINCIPLES
156(7)
6.1.1 Systems with no symmetry constraints
157(4)
6.1.2 Systems with symmetry constraints
161(2)
6.2 QUANTUM PHASES WITH TOPOLOGICAL ORDER
163(12)
6.2.1 Effective theory of Abelian fractional quantum Hall liquids
164(7)
6.2.2 The toric code
171(4)
6.3 Symmetry Protected Topological Quantum Sates
175(12)
6.3.1 SPT phases in one dimension
176(4)
6.3.2 SPT phases in two and three dimensions
180(7)
PART III Topological Quantum States: Design and Engineering
Chapter 7 Theories of Topological Quantum Matter
187(30)
7.1 Topological Band Theory: Continuum Dirac Models
188(10)
7.1.1 Graphene and Dirac fermions
189(2)
7.1.2 Quantum spin Hall state: The Kane-Mele model
191(5)
7.1.3 Three-dimensional four-component Dirac Hamil-tonian
196(2)
7.2 Topological Band Theory: Tight-Binding Models
198(14)
7.2.1 Haldane model
199(2)
7.2.2 Mercury telluride quantum wells: The BHZ model
201(2)
7.2.3 p-Wave superconductors in one and two dimensions
203(9)
7.3 Topological Field Theory
212(5)
Chapter 8 MajoranaZero Modes in Solid State Heterostructures
217(30)
8.1 THEORETICAL BACKGROUND
218(7)
8.1.1 Majorana zero modes
218(4)
8.1.2 "Synthetic" topological superconductors
222(3)
8.2 REALIZATION OF MAJORANAZERO MODES: PRACTICAL SCHEMES
225(12)
8.2.1 Semiconductor-superconductor hybrid structures
225(9)
8.2.2 Shiba chains
234(3)
8.3 EXPERIMENTAL DETECTION OF MAJORANA ZERO MODES
237(10)
8.3.1 Tunneling spectroscopy
237(4)
8.3.2 Fractional Josephson effect
241(2)
8.3.3 Non-local transport
243(4)
Chapter 9 Topological Phases in Cold Atom Systems
247(24)
9.1 Brief Historical Perspective
248(1)
9.2 Many-Body Physics With Ultracold Gases: Basic Tools
249(10)
9.2.1 Cooling and trapping of neutral atoms
249(4)
9.2.2 Optical lattices
253(3)
9.2.3 Feshbach resonances
256(3)
9.3 Light-Induced Artificial Gauge Fields
259(6)
9.3.1 Geometric gauge potentials
260(2)
9.3.2 Abelian gauge potentials: The A scheme
262(1)
9.3.3 Non-Abelian gauge potentials: The tripod scheme and spin-orbit coupling
263(2)
9.4 Topological States In Cold Atom Systems
265(6)
9.4.1 Realization of the Haldane model with ultracold atoms
265(3)
9.4.2 Majorana fermions in optical lattices
268(3)
PART IV Topological Quantum Computation
Chapter 10 Elements of Quantum Information Theory
271(22)
10.1 Basic Concepts
272(6)
10.1.1 Quantum bits
272(2)
10.1.2 Quantum operations
274(3)
10.1.3 No cloning
277(1)
10.2 Entropy And Information
278(3)
10.3 Data Compression
281(2)
10.3.1 Schumacher's noiseless quantum coding theorem
282(1)
10.4 Accessible Information
283(2)
10.4.1 The Holevo bound
284(1)
10.5 Entanglement-Assisted Communication
285(4)
10.5.1 Superdense coding
286(1)
10.5.2 Quantum teleportation
287(2)
10.6 Quantum Cryptography
289(4)
10.6.1 Quantum key distribution
290(3)
Chapter 11 Introduction to Quantum Computation
293(26)
11.1 Introduction: The Universal Quantum Computer
294(3)
11.2 Quantum Circuits
297(3)
11.3 Quantum Algorithms
300(13)
11.3.1 Deutsch's algorithm
300(2)
11.3.2 Quantum search: Grover's algorithm
302(4)
11.3.3 Quantum Fourier transform: Shor's algorithm
306(4)
11.3.4 Simulation of quantum systems
310(3)
11.4 Quantum Error Correction
313(6)
Chapter 12 Anyons and Topological Quantum Computation
319(28)
12.1 Quantum Computation With Anyons
320(13)
12.1.1 Abelian and non-Abelian anyons
320(2)
12.1.2 Braiding
322(2)
12.1.3 Particle types, fusion rules, and exchange properties
324(3)
12.1.4 Fault-tolerance from non-Abelian anyons
327(2)
12.1.5 Ising anyons
329(2)
12.1.6 Fibonacci anyons
331(2)
12.2 Anyons And Topological Quantum Phases
333(6)
12.2.1 Abelian Chern-Simons field theories
335(2)
12.2.2 Non-Abelian Chern Simons field theories
337(2)
12.3 Topological Quantum Computation With Majorana Zero Modes
339(5)
12.3.1 Non-Abelian statistics
339(2)
12.3.2 Fusion of Majorana zero modes
341(2)
12.3.3 Quantum information processing
343(1)
12.4 Outlook: Quantum Computation And Topological Quantum Matter
344(3)
References 347(28)
Index 375
Tudor D. Stanescu