Spatially Resolved Quantification of the Surface Reactivity of Solid Catalysts

A new property is reported that accurately quantifies and spatially describes the chemical reactivity of solid surfaces. The core idea is to create a reactivity weight function peaking at the Fermi level, thereby determining a weighted summation of the density of states of a solid surface. When such a weight function is defined as the derivative of the Fermi–Dirac distribution function at a certain non‐zero temperature, the resulting property is the finite‐temperature chemical softness, termed Fermi softness ( S F ), which turns out to be an accurate descriptor of the surface reactivity. The spatial image of S F maps the reactive domain of a heterogeneous surface and even portrays morphological details of the reactive sites. S F analyses reveal that the reactive zones on a Pt 3 Y(111) surface are the platinum sites rather than the seemingly active yttrium sites, and the reactivity of the S‐dimer edge of MoS 2 is spatially anisotropic. Our finding is of fundamental and technological significance to heterogeneous catalysis and industrial processes demanding rational design of solid catalysts.