From The Quantum Hall Effect To Topological Insulators

TL;DR

This paper discusses how the quantum Hall effect's topological properties can be generalized to other quantum systems, leading to the concept of topological insulators without magnetic fields.

Contribution

It reaffirms that the quantum Hall effect's topological features are universal and can be applied to various quantum systems with discrete spectra and multiple periodic parameters.

Findings

Quantum Hall conductance relates to topological invariants.

Topological properties can exist without magnetic fields.

Generalization applies to fermion and boson systems.

Abstract

The integral and fractional quantum Hall effects are among the most important discoveries in condensed matter physics in 1980s. The main results can be summarized in the conductance matrix. When the filling factor is an integer or some fractional value, the conductance is quantized. This quantization is related to the first Chern number. The novel properties of the quantum Hall system raised an important question: Can we have such important quantum properties in other systems? Especially, can we find a quantum system without magnetic field but maintaining the same properties in its conductance matrix? This is really the starting point for the topological insulators, too. This issue was first discussed in our paper, published in Physical Review B, 1987. Here, we re-post this paper and want to emphasize that the physics discussed in our paper is general and profound. The essence of quantum Hall effect can be generalized to many quantum systems, either fermion system or boson system. If the quantum system has discrete energy spectrum and depends on two or more periodic parameters, the response coefficient will be the same as the conductance of quantum Hall effect, dissipation free for the longitudinal ones and quantized for off-diagonal ones.