Quantum theory of fractional topological pumping of lattice solitons (2506.00090v1)

Abstract: One of the haLLMarks of topological quantum systems is the robust quantization of particle transport, which is the origin of the integer-valued Quantum Hall conductivity. In the presence of interactions the topological transport can also become fractional. Recent experiments on topological pumps constructed by arrays of photonic waveguides have demonstrated both integer and fractional transport of lattice solitons. Here a background medium mediates interactions between photons via a Kerr nonlinearity and leads to the formation of self-bound composites, called lattice solitons. Upon increasing the interaction strength of these solitons a sequence of transitions was observed from a phase with integer transport in a pump cycle through different phases of fractional transport to a phase with no transport. We here present a full quantum description of topological pumps of solitons. This approach allows us to identify a topological invariant, a many-body Chern number, determined by the band structure of the center-of-mass (COM) momentum of the solitons, which fully governs their transport. Increasing the interaction leads to a successive merging of COM bands which explains the observed sequence of topological phase transitions and also the potential for a breakdown of topological quantization for intermediate interaction strength