"Six-vertex model and Quantum XXZ Hamiltonian"의 두 판 사이의 차이

2013년 2월 4일 (월) 03:29 판

introduction

ice-type model, R model, Rys model
XXZ spin chain and the six-vertex transfer matrix have the same eigenvectors
Boltzmann weights
monodromy matrix
trace of monodromy matrix is the transfer matrix
power of transfer matrix becomes the partition function

types of six vertex models

on a square lattice with periodic boundary conditions
on a square lattice with domain wall boundary conditions
- this is related to the Alternating sign matrix theorem

transfer matrix

borrowed from transfer matrix in statistical mechanics
transfer matrix is builtup from matrices of Boltzmann weights
finding eigenvalues and eigenvectors of transfer matrix is crucial
Bethe ansatz equation is used to find the eigenvectors and eigenvalues of the transfer matrix
partition function = trace of power of transfer matrices
so the partition function is calculated in terms of the eigenvalues of the transfer matrix
then the problem of solving the model is reduced to the computation of this trace

integrability of the model

$T(u)$ transfer matrix
$\log T(u)=\sum_{n=0}^{\infty}Q_{n}u^n$
here $Q_1$ plays the role of the Hamiltonian
necessary and sufficient codntion to have infinitely many conserved quantities

$$[T(u), T(v)]=0$$ which implies $[Q_n,Q_m]=0$

in order to have $[T(u), T(v)]=0$, the YBE must be satisfied

R-matrix and Yang-Baxter equation

$$ R(u,\eta)=\rho\left( \begin{array}{cccc} \sin (u+\eta ) & 0 & 0 & 0 \\ 0 & \sin (u) & \sin (\eta ) & 0 \\ 0 & \sin (\eta ) & \sin (u) & 0 \\ 0 & 0 & 0 & \sin (u+\eta ) \end{array} \right) $$

transfer matrix formalism and coordinate Bethe ansatz

$M=N^{2}$ number of molecules
one can regard the up(or down) arrows in a row as 'particles'
because of the ice rule, their number is conserved and one can try a Bethe ansatz for the eigenvectors of the transfer matrix
$f(x_1,\cdots,x_n)$ be the amplitude in an eigenvector of the state with up arrows at the sites $ x_ 1<x_ 2<\cdots<x_n$
obtain the equation for amplitudes \[f(x_ 1,\cdots,x_n)=\sum_{P}A (P)\exp(i\sum_{j=1}^{n}x_jk _{P_j})\]
Bethe ansatz equation for wave numbers : there are n conditions

\[\exp(ik_jn)=\prod_{j \neq i}B(k_i,k_j)=\prod_{j=1}^{n}B(k_i,k_j)\]
where \[B(k,q)=-\frac{1+e^{ik}e^{iq}-e^{ik}}{1+e^{ik}e^{iq}-e^{iq}}\]

eigenvalue

\[\lambda=\frac{1+e^{i(k_{1}+\cdots+k_{n})}}{\prod_{j=1}^{n}1-e^{ik_{j}}}=\frac{1+e^{i(k_{1}+\cdots+k_{n})}}{(1-e^{ik_{j}})\cdots(1-e^{ik_{j}})}\]

anistropic one-dimensional Heisenberg model (XXZ model)

Heisenberg spin chain model
Hamiltonian of XXZ model or XXZ spin chain with anisotropic parameter $\Delta=1/2$

\[\hat H = -\sum_{j=1}^{N} (\sigma_j^x \sigma_{j+1}^x +\sigma_j^y \sigma_{j+1}^y + \Delta \sigma_j^z \sigma_{j+1}^z)=-\sum_{j=1}^{N} (\sigma_j^x \sigma_{j+1}^x +\sigma_j^y \sigma_{j+1}^y + \frac{1}{2} \sigma_j^z \sigma_{j+1}^z)\]

two body scattering term

\[s_{jl}=1-2\Delta e^{ik_l}+ e^{ik_l+ik_j}=1-e^{ik_l}+ e^{ik_l+ik_j}\]

equation satisfied by wave numbers

\[\exp(ik_jN)=(-1)^{N-1}\prod_{l=1}^{N}\exp(-i\theta(k_j,k_l))\] where $\theta(p,q)$ is defined as \[\exp(-i\theta(p,q))=\frac{1-2\Delta e^{ip}+e^{i(p+q)}}{1-2\Delta e^{iq}+e^{i(p+q)}}=\frac{1-e^{ip}+e^{i(p+q)}}{1- e^{iq}+e^{i(p+q)}}\]

fundamental equation

\[k_jN=2\pi I(k_j)+\sum_{l=1}^{N}\theta(k_j,k_l)\]

eigenvalue
ground state eigenvector for Hamiltonian is a common eigenvector although the eigenvalues are different
the maximum eigenstate of the transfer matrix and the ground state of the above Hamiltonian are identical because both are characterized by the fact that $f(x_ 1,\cdots,x_n)>0$
see [YY1966-2]

Sutherland's observation

the eigenvectors of the transfer matrix depended on a,b,c only via the parameter

\[\Delta=\frac{a^2+b^2-c^2}{2ab}=\cos \eta\]

$\delta$ = anistropic parameter in Heisenberg spin chain model

entropy of two-dimensional ice

entropy is given as
$Mk\ln W$ where M is the number of molecules and $W=(4/3)^{3/2}=1.53960\cdots$

free energy

$F=-kT \ln Z=-\beta \ln Z$

partition function

correlation functions

related items

books

찾아볼 수학책

Exactly Solved Models in Statistical mechanics
- R. J. Baxter, 1982

encyclopedia

blogs

구글 블로그 검색

STATISTICAL MECHANICS-A REVIEW OF SELECTED RIGOROUS RESULTS

By JOEL L. LEBOWITZ

Method for calculating finite size corrections in Bethe ansatz systems: Heisenberg chain and six-vertex model
de Vega, H. J.; Woynarovich, F.

expositions

Integrability of the Quantum XXZ Hamiltonian
- T Miwa, 2009

Introduction to solvable lattice models in statistical and mathematical physics
- Tetsuo Deguchi, 2003
A Theory of the Structure of Ice

articles

Szabo, Richard J, 와/과Miguel Tierz. 2011. “Two-dimensional Yang-Mills theory, Painleve equations and the six-vertex model”. arXiv:1102.3640 (2월 17). http://arxiv.org/abs/1102.3640
Kazuhiko Minami, The free energies of six-vertex models and the n-equivalence relation
Exact Solution of the F Model of An Antiferroelectric
- E.H. Lieb. Phys. Rev. 18 (1967), p. 1046.
Exact Solution of the Two-Dimensional Slater KDP Model of a Ferroelectric
- E.H. Lieb. Phys. Rev. 19 (1967), p. 108.
Exact Solution of a Two-Dimensional Model for Hydrogen-Bonded Crystals
- B. Sutherland. Phys. Rev. 19 (1967), p. 103.
Exact Solution of the Problem of the Entropy of Two-Dimensional Ice
- E. H. Lieb, Phys. Rev. Letters 18, 692 (1967)
[YY1966-2]One-Dimensional Chain of Anisotropic Spin-Spin Interactions. II. Properties of the Ground-State Energy Per Lattice Site for an Infinite System
- C. N. Yang, C. P. Yang, Phys. Rev. 150, 327 (1966)

One-dimensional chain of anisotropic spin-spin interactions
- C. N. Yang, C. P. Yang, Phys. Rev. 150, 321 (1966)
The Structure and Entropy of Ice and of Other Crystals with Some Randomness of Atomic Arrangement
- L. Pauling, Journal of the American Chemical Society, Vol. 57, p. 2680 (1935).
http://dx.doi.org/10.1063/1.2890671

links

@@ 116번째 줄: / 116번째 줄: @@
 ==free energy==
-* <math>F=-kT \ln Z</math>
+* <math>F=-kT \ln Z=-\beta \ln Z</math>
 ==partition function==