Abstract
Surface-area normalization is essential for quantitative comparison in electrochemistry, yet ambiguity in what area represents hampers interpretation and reproducibility. We distinguish the real surface area, a geometric measure of surface roughness and structure, from the electrochemically active surface area, defined as the condition-dependent subset of surface sites participating in a specific faradaic reaction. We clarify how double-layer capacitance and adsorption-limited charge-transfer reactions probe different regions of the electrode surface and how their interpretation and reference values determine whether the result corresponds to an apparent area, the real surface area, or the electrochemically active surface area. We further show that commonly used reference values vary strongly with electrode structure, electrolyte composition, and measurement protocol. To address this, we introduce a formalism based on domain-specific linear combinations of surface contributions that enables structurally consistent area estimates. Finally, we propose normalizing current by active-site count as a direct and reproducible measure of intrinsic activity.