Spatial correlations of charge density wave order across the transition in 2H-NbSe2

Charge density waves (CDWs) involve coupled amplitude and phase degrees of freedom, but direct access to local amplitude correlations remains experimentally challenging. Here, we report cryogenic four-dimensional scanning transmission electron microscopy (4D-STEM) measurements of CDW ordering in 2H-NbSe2, enabled by liquid helium-based cooling down to 20 K. By mapping the spatial distribution of CDW superlattice intensities at nanometer-scale resolution and analyzing their autocorrelations, we extract the temperature-dependent correlation length associated with the local amplitude of the CDW order parameter, independent of global phase coherence. Our results reveal that weak short-range amplitude correlations persist above the transition temperature, and grow significantly upon cooling, reaching approximately 150 nm at 20 K. These findings demonstrate clear deviations from mean-field expectations and establish 4D-STEM as a powerful tool for probing spatially inhomogeneous electronic order in quantum materials.