Quarter- and half-filled quantum Hall states and their competing interactions in bilayer graphene

Bilayer graphene has emerged as a key platform for studying non-Abelian fractional quantum Hall (FQH) states. Its multiple half-filled plateaus with large energy gaps combined with its tunability offer an opportunity to distill the principles that determine their topological order. Here, we report four additional plateaus at =12 for different spin and valley, revealing a systematic pattern of non-Abelian states according to their Levin--Halperin daughter states. Whenever a pair of N=1 Landau levels cross, anti-Pfaffian and Pfaffian develop at half filling of the lower and higher levels, respectively. In the N=0 levels, where half-filled plateaus are absent, we instead observe four unexpected incompressible quarter-filled states along with daughters. The mutual exclusion of half- and quarter-filled states indicates a robust competition between the interactions favoring either paired states of two-flux or four-flux composite fermions. Finally, we observe several FQH states that require strong interactions between composite fermions. Our combined findings herald a new generation of quantum Hall physics in graphene-based heterostructures.