Evolution of chiral magnetic textures and their topological Hall signature in Ir/Fe/Co/Pt multilayer films

The unique topological properties of magnetic skyrmions, and their interplay with electric currents give rise to exotic electrodynamic phenomena such as the topological Hall effect (THE). While THE has been proposed as a mechanism for skyrmion detection in devices, its manifestation in multilayer thin films remains to be understood. Here we study the evolution of magnetic textures and their Hall signature in Ir/Fe/Co/Pt stacks that host N\'{e}el skyrmions using magnetic force microscopy (MFM) and Hall transport. We demonstrate the relationship between isolated skyrmions and the THE magnitude over a wide ($\approx200~$K) temperature range, and show that magnetic worm-like features corresponding to trains of skyrmions carry considerable topological charge. Our analysis of magnetic textures shows a qualitative agreement between the temperature and field evolution of THE and corresponding topological charge determined from MFM ($n_{\mathrm{T}}$). However, the magnitude of THE is two orders higher than $n_{\mathrm{T}}$ would indicate. We discuss possible sources of this discrepancy.