Strong-coupling expansion and effective hamiltonians

TL;DR

This paper reviews methods for deriving effective Hamiltonians in frustrated quantum magnets, emphasizing perturbative techniques and illustrating with recent examples like frustrated ladders and quantum dimer models.

Contribution

It introduces modern approaches for high-order effective Hamiltonian derivation, expanding on traditional degenerate perturbation theory with practical examples.

Findings

Effective Hamiltonians simplify complex frustrated systems.

Modern techniques like continuous unitary transformations improve accuracy.

Applications include frustrated ladders and quantum dimer models.

Abstract

When looking for analytical approaches to treat frustrated quantum magnets, it is often very useful to start from a limit where the ground state is highly degenerate. This chapter discusses several ways of deriving {effective Hamiltonians} around such limits, starting from standard {degenerate perturbation theory} and proceeding to modern approaches more appropriate for the derivation of high-order effective Hamiltonians, such as the perturbative continuous unitary transformations or contractor renormalization. In the course of this exposition, a number of examples taken from the recent literature are discussed, including frustrated ladders and other dimer-based Heisenberg models in a field, as well as the mapping between frustrated Ising models in a transverse field and quantum dimer models.