Level statistics for quantum k-core percolation

Abstract

Quantum k-core percolation is the study of quantum transport on k-core percolation clusters where each occupied bond must have at least k occupied neighboring bonds. As the bond occupation probability, p, is increased from zero to unity, the system undergoes a transition from an insulating phase to a metallic phase. When the lengthscale for the disorder, ld, is much greater than the coherence length, lc, earlier analytical calculations of quantum conduction on the Bethe lattice demonstrate that for k=3 the metal-insulator transition (MIT) is discontinuous, suggesting a new universality class of disorder-driven quantum MITs. Here, we numerically compute the level spacing distribution as a function of bond occupation probability p and system size on a Bethe-like lattice. The level spacing analysis suggests that for k=0, pq, the quantum percolation critical probability, is greater than pc, the geometrical percolation critical probability, and the transition is continuous. In contrast, for k=3, pq=pc and the transition is discontinuous such that these numerical findings are consistent with our previous work to reiterate a new universality class of disorder-driven quantum MITs.