Hexagonal lattice diagrams for complex curves in CP2

Abstract

We demonstrate that the geometric, topological, and combinatorial complexities of certain surfaces in CP2 are closely related: We prove that a positive genus surface K in CP2 that minimizes genus in its homology class is isotopic to a complex curve Cd if and only if K admits a hexagonal lattice diagram, a special type of shadow diagram in which arcs meet only at bridge points and tile the central surface of the standard trisection of CP2 by hexagons. There are eight families of these diagrams, two of which represent surfaces in efficient bridge position. Combined with a result of Lambert-Cole relating symplectic surfaces and bridge trisections, this allows us to provide a purely combinatorial reformulation of the symplectic isotopy problem in CP2. Finally, we show that that the varieties Vd = \[z1:z2:z3] ∈ CP2 : z1z2d-1 + z2z3d-1 + z3z1d-1 = 0\ and V'd = \[z1:z2:z3] ∈ CP2 : z1d-1z2 + z2d-1z3 + z3d-1z1 = 0\ are in efficient bridge position with respect to the standard Stein trisection of CP2, and their shadow diagrams agree with the two families of efficient hexagonal lattice diagrams. As a corollary, we prove that two infinite families of complex hypersurfaces in CP3 admit efficient Stein trisections, partially answering a question of Lambert-Cole and Meier.