Conserved charges of order-parameter textures in Dirac systems

A simple expression for the induced fermion current in the presence of a texture in mass order parameters in two-dimensional condensed-matter Dirac systems is derived using the representation theory of Clifford algebras. In particular, it is shown that every texture in three mutually anticommuting order parameters, in graphene for example, implies an induced density of a properly defined conserved charge. The sufficient condition for the general charge to be the familiar electrical charge is that the remaining two anticommuting order parameters allowed by the particle-hole symmetry are the two phase components of some superconducting order. This allows eight different types of electrically charged texture in graphene or in the π-flux Hamiltonian on the square lattice. The generalized charge of mass textures on the surfaces of thin films of topological insulators or in spinless Dirac fermions hopping on the honeycomb lattice is also discussed.