Extracting entropy of exotic quasiparticles from conductance measurements.

Fractional entropy is a signature of nonlocal degrees of freedom, such as Majorana zero modes or more exotic non-Abelian anyons. However, in the mesoscopic quantum systems hosting these states direct entropy measurements remain highly challenging. Here we introduce a self-consistent framework to extract entropy from existing experimental conductance measurements. Applying this approach to conductance measurement through a metallic quantum dot displaying `charge' Kondo effects, we extract the fractional entropy in the two- and three-channel Kondo effects, corresponding to Majorana and Fibonacci zero modes, respectively. In these cases, the entropy extracted from the experimental data falls on a theoretical curve displaying scaling towards $k_{\rm{B}}\log \sqrt{2}$ or $k_{\rm{B}}\log \frac{1+\sqrt{5}}{2}$ entropy, respectively. Our protocol provides a general route towards a direct extraction of entropy from charge measurements in mesoscopic quantum systems.