The One-Dimensional Hubbard Model,9780521802628

The One-Dimensional Hubbard Model

by
ISBN13: 9780521802628
ISBN10: 0521802628
Format: Hardcover
Pub. Date: 2005-02-07
Publisher(s): Cambridge University Press
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Summary

The description of solids at a microscopic level is complex, involving the interaction of a huge number of its constituents, such as ions or electrons. It is impossible to solve the corresponding many-body problems analytically or numerically, although much insight can be gained from the analysis of simplified models. An important example is the Hubbard model, which describes interacting electrons in narrow energy bands, and which has been applied to problems as diverse as high-Tc superconductivity, band magnetism, and the metal-insulator transition. This book presents a coherent, self-contained account of the exact solution of the Hubbard model in one dimension. The early chapters will be accessible to beginning graduate students with a basic knowledge of quantum mechanics and statistical mechanics. The later chapters address more advanced topics, and are intended as a guide for researchers to some of the more recent scientific results in the field of integrable models.

Table of Contents

Preface xi
Introduction
1(19)
On the origin of the Hubbard model
1(4)
The Hubbard model -- a paradigm in condensed matter physics
5(6)
External fields
11(3)
Conclusions
14(1)
Appendices to Chapter 1
15(1)
Response to external fields
15(5)
The Hubbard Hamiltonian and its symmetries
20(30)
The Hamiltonian
20(5)
Symmetries
25(10)
Conclusions
35(1)
Appendices to Chapter 2
36(1)
The strong coupling limit
36(9)
Continuum limits
45(5)
The Bethe ansatz solution
50(70)
The Hamiltonian in first quantization
51(3)
Solution of the two-particle problem
54(10)
Many-particle wave functions and Lieb-Wu equations
64(3)
Symmetry properties of wave functions and states
67(1)
The norm of the eigenfunctions
68(4)
Conclusions
72(1)
Appendices to Chapter 3
73(1)
Scalar products and projection operators
73(3)
Derivation of Bethe ansatz wave functions and Lieb-Wu equations
76(18)
Some technical details
94(2)
Highest weight property of the Bethe ansatz states with respect to total spin
96(5)
Explicit expressions for the amplitudes in the Bethe ansatz wave functions
101(4)
Lowest weight theorem for the η-pairing symmetry
105(7)
Limiting cases of the Bethe ansatz solution
112(8)
String hypothesis
120(29)
String configurations
121(4)
String solutions as bound states
125(3)
Takahashi's equations
128(3)
Completeness of the Bethe ansatz
131(2)
Higher-level Bethe ansatz
133(1)
Appendices to Chapter 4
134(1)
On deviations from the string hypothesis
134(3)
Details about the enumeration of eigenstates
137(12)
Thermodynamics in the Yang-Yang approach
149(26)
A point of reference: noninteracting electrons
149(4)
Thermodynamic Bethe Ansatz (TBA) equations
153(8)
Thermodynamics
161(1)
Infinite temperature limit
162(1)
Zero temperature limit
163(5)
Appendices to Chapter 5
168(1)
Zero temperature limit for ε'1(Λ)
168(1)
Properties of the integral equations at T = 0
168(7)
Ground state properties in the thermodynamic limit
175(34)
A point of reference: noninteracting electrons
175(2)
Defining equations
177(1)
Ground state phase diagram
178(6)
Density and magnetization
184(3)
Spin and charge velocities
187(1)
Susceptibilities
188(5)
Ground state energy
193(2)
Appendices to Chapter 6
195(1)
Numerical solution of integral equations
195(2)
Ground state properties in zero magnetic field
197(5)
Small magnetic fields at half filling: application of the Wiener-Hopf method
202(7)
Excited states at zero temperature
209(59)
A point of reference: noninteracting electrons
210(1)
Zero magnetic field and half-filled band
211(14)
Root density formalism
225(11)
Scattering matrix
236(6)
`Physical' Bethe ansatz equations
242(2)
Finite magnetic field and half-filled band
244(9)
Zero magnetic field and less than half-filled band
253(8)
Finite magnetic field and less than half-filled band
261(1)
Empty band in the infinite volume
262(3)
Appendices to Chapter 7
265(1)
Relating root-density and dressed-energy formalisms
265(2)
Lower bounds for εn(0), n ≥ 2 at half filling in a finite magnetic field
267(1)
Finite size corrections at zero temperature
268(29)
Generic case -- the repulsive Hubbard model in a magnetic field
268(8)
Special cases
276(7)
Finite size spectrum of the open Hubbard chain
283(7)
Relation of the dressed charge matrix to observables
290(4)
Appendices to Chapter 8
294(1)
Wiener Hopf calculation of the dressed charge
294(3)
Asymptotics of correlation functions
297(36)
Low energy effective field theory at weak coupling
297(6)
Conformal field theory and finite size scaling
303(5)
Correlation functions of the one-dimensional Hubbard model
308(12)
Correlation functions in momentum space
320(4)
Correlation functions in the open boundary Hubbard chain
324(7)
Appendices to Chapter 9
331(1)
Singular behaviour of momentum-space correlators
331(2)
Scaling and continuum limits at half-filling
333(43)
Construction of the scaling limit
333(2)
The S-matrix in the scaling limit
335(2)
Continuum limit
337(7)
Correlation functions in the scaling limit
344(17)
Correlation functions in the continuum limit
361(6)
Finite temperatures
367(2)
Appendices to Chapter 10
369(1)
Current algebra
369(2)
Two-particle form factors
371(1)
Correlation functions in the Gaussian model
372(4)
Universal correlations at low density
376(17)
The Hubbard model in the gas phase
377(6)
Correlation functions of the impenetrable electron gas
383(9)
Conclusions
392(1)
The algebraic approach to the Hubbard model
393(95)
Introduction to the quantum inverse scattering method
393(18)
Shastry's R-matrix
411(14)
Graded quantum inverse scattering method
425(15)
The Hubbard model as a fundamental graded model
440(10)
Solution of the quantum inverse problem
450(2)
On the algebraic Bethe ansatz for the Hubbard model
452(18)
Conclusions
470(2)
Appendices to Chapter 12
472(1)
A proof that Shastry's R-matrix satisfies the Yang-Baxter equation
472(7)
A proof of the inversion formula
479(5)
A list of commutation relations
484(1)
Some identities needed in the construction of the two-particle algebraic Bethe ansatz-states
484(2)
An explicit expression for the fermionic R-operator of the Hubbard model
486(2)
The path integral approach to thermodynamics
488(75)
The quantum transfer matrix and integrability
489(7)
The Heisenberg chain
496(13)
Shastry's model as a classical analogue of the Id Hubbard model
509(1)
Diagonalization of the quantum transfer matrix
510(4)
Associated auxiliary problem of difference type
514(5)
Derivation of non-linear integral equations
519(6)
Integral expression for the eigenvalue
525(11)
Numerical results
536(11)
Analytical solutions to the integral equations
547(8)
Conclusions
555(2)
Appendices to Chapter 13
557(1)
Derivation of TBA equations from fusion Hierarchy analysis
557(3)
Derivation of single integral equation
560(3)
The Yangian symmetry of the Hubbard model
563(36)
Introduction
563(1)
The variable-range-hopping Hamiltonian
564(2)
Construction of the Yangian generators
566(4)
Special cases
570(3)
Conclusions
573(2)
Appendices to Chapter 14
575(1)
Yangians
575(24)
S-matrix and Yangian symmetry in the infinite interval limit
599(21)
Preliminaries
599(1)
Passage to the infinite interval
600(5)
Yangian symmetry and commuting operators
605(2)
Constructing N-particle states
607(10)
Eigenvalues of quantum determinant and Hamiltonian
617(1)
Conclusions
617(1)
Appendices to Chapter 15
618(1)
Some useful formulae
618(2)
Hubbard model in the attractive case
620(18)
Half-filled case
622(3)
The ground state and low lying excitations below half filling
625(1)
Interaction with magnetic field
626(1)
Phase diagram
627(1)
Critical behavior
628(2)
Thermodynamics
630(3)
Appendices to Chapter 16
633(1)
Appendix A
633(2)
Appendix B
635(3)
Mathematical appendices
638(5)
Useful integrals
638(2)
The Wiener-Hopf method
640(3)
References 643(26)
Index 669

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