Planar Site Percolation, End Structure, and the Benjamini-Schramm Conjecture

Abstract

Let G be an infinite, connected, locally finite planar graph and consider i.i.d.\ Bernoulli(p) site percolation. Write pcsite(G) and pusite(G) for the critical and uniqueness thresholds. Using a well--separated Freudenthal embedding G S2, we introduce a cycle--separation equivalence on ends and associated ``directional'' thresholds psitec,F(G). When the set of end--equivalence classes is countable, we show that pcsite(G)=∈fF psitec,F(G) and that for every p∈(12,\,1-pcsite(G)) there are almost surely infinitely many infinite open clusters. Combined with the 0/∞ theorem of Glazman--Harel--Zelesko for p 12, this yields non--uniqueness throughout the full coexistence interval (pcsite(G),\,1-pcsite(G)), and hence pusite(G) 1-pcsite(G) in this setting. This resolves the extension problem posed by Glazman--Harel--Zelesko for the upper half of the coexistence regime under a natural countability hypothesis. In contrast, for graphs with uncountably many end--equivalence classes we give criteria guaranteeing infinitely many infinite clusters above criticality, and we construct an explicit locally finite planar graph of minimum degree at least 7 for which pusite(G)<1-pcsite(G). Consequently, the Benjamini--Schramm conjecture (Conjecture 7 in bs96) that planarity together with minimal vertex degree at least 7 forces infinitely many infinite clusters for all p∈(pc,1-pc) does not hold in full generality. Our proofs combine a cutset characterization of pcsite with a planar alternating--arm exploration organized by an end--adapted boundary decomposition.