TY - THES
AU - McAteer, Stephen Gerard
Y2 - 2016/02/26
Y1 - 2015
UR - http://hdl.handle.net/11343/58978
AB - The aim of this thesis is a better understanding of certain mathematical structures which arise in integrable spin chains. Specifically, we are concerned with XXZ and XXX Heisenberg spin-1/2 chains and their generalizations.
The mathematical structures in question are the F-matrix (a symmetrising, change-of-basis operator) and the Bethe eigenvectors (the eigenvectors of the transfer matrix of integrable spin chains). A diagrammatic tensor notation represents these operators in a way which is intuitive and allows easy manipulation of the relations involving them. The sun F-matrix is a representation of a Drinfelâ€™d twist of the R-matrix of the quantum algebra U_q(su_n) and its associated Yangian Y(su_n). The F-matrices of these algebras have proven useful in the calculation of scalar products and domain wall partition functions in the spin-1/2 XXZ model. In this thesis we present a factorized diagrammatic expression for the su_2 F-matrix equivalent to the algebraic expression of Maillet and Sanchez de Santos. Next we present a fully factorized expression for the su_n F-matrix which is of a similar form to that of Maillet and Sanchez de Santos [18] for the su_2 F-matrix and equivalent to the unfactorized expression of Albert, Boos, Flume and Ruhlig [2] for the su_n F-matrix.
Using a diagrammatic description of the nested algebraic Bethe Ansatz, we present an expression for the eigenvectors of the sun transfer matrix as components of appropriately selected sun F-matrices. Finally, we present expressions for the sun elementary matrices (and therefore the local spin operators in the case of su_2) in terms of components of the sun monodromy matrix.
KW - mathematical physics
KW - F-matrix
KW - Drinfel'd twist
KW - quantum spin chains
KW - Bethe Ansatz
T1 - A diagrammatic approach to factorizing F-matrices in XXZ and XXX spin chains
L1 - /bitstream/handle/11343/58978/mcateer_thesis_final.pdf?sequence=1&isAllowed=y
ER -