Surprises on the Way from 1D to 2D Quantum Magnets: the Novel Ladder Materials

TL;DR

This paper explores the transition from 1D to 2D quantum magnets using ladder materials, revealing unexpected behaviors and potential for superconductivity upon doping.

Contribution

It provides experimental verification of the distinct magnetic ground states in ladder materials and discusses the implications for superconductivity.

Findings

Ladders with even legs have short-range order and a finite energy gap.

The crossover from 1D to 2D is not smooth, with unique magnetic properties.

Holes doped into ladders are predicted to pair, suggesting possible superconductivity.

Abstract

One way of making the transition between the quasi-long range order in a chain of S=1/2 spins coupled antiferromagnetically and the true long range order that occurs in a plane, is by assembling chains to make ladders of increasing width. Surprisingly this crossover between one and two dimensions is not at all smooth. Ladders with an even number of legs have purely short range magnetic order and a finite energy gap to all magnetic excitations. Predictions of this novel groundstate have now been verified experimentally. Holes doped into these ladders are predicted to pair, and possibly superconduct.