Zn superconductivity of composite bosons and the 7/3 fractional quantum Hall effect

Abstract

The topological p-wave pairing of composite fermions, believed to be responsible for the 5/2 fractional quantum Hall effect (FQHE), has generated much exciting physics. Motivated by the parton theory of the FQHE, we consider the possibility of a new kind of emergent "superconductivity" in the 1/3 FQHE, which involves condensation of clusters of n composite bosons. From a microscopic perspective, the state is described by the nn111 parton wave function P LLL nn*13, where n is the wave function of the integer quantum Hall state with n filled Landau levels and P LLL is the lowest-Landau-level projection operator. It represents a Zn superconductor of composite bosons, because the factor 13 Πj<k(zj-zk)3, where zj=xj-iyj is the coordinate of the jth electron, binds three vortices to electrons to convert them into composite bosons, which then condense into the Zn superconducting state |n|2. From a field theoretical perspective, this state can be understood by starting with the usual Laughlin theory and gauging a Zn subgroup of the U(1) charge conservation symmetry. We find from detailed quantitative calculations that the 22111 and 33111 states are at least as plausible as the Laughlin wave function for the exact Coulomb ground state at filling =7/3, suggesting that this physics is possibly relevant for the 7/3 FQHE. The Zn order leads to several observable consequences, including quasiparticles with fractionally quantized charges of magnitude e/(3n) and the existence of multiple neutral collective modes. It is interesting that the FQHE may be a promising venue for the realization of exotic Zn superconductivity.