Measuring and Manipulating Density of States in Two-Dimensional Materials with Electrochemical Capacitance

Abstract Measuring and controlling the density of states (DOS) and defect states of two-dimensional van der Waals materials is of profound importance for understanding their unique physical properties, and for advancing their future practical applications. However, probing their defect states typically requires experiments performed at cryogenic temperatures and/or in ultra-high vacuum conditions, severely constraining efforts to monitor the electronic structure evolution of these materials under useful device operating conditions. Here, we develop a new electrochemical quantum capacitance spectroscopy (EQCS) technique for detecting the absolute energies of defect states and band edges in an ambient environment. We demonstrate the viability of this method with a variety of two-dimensional material systems, with the ability to easily extend to many more. The highest energy resolution achieved at room temperature, 116 meV, approaches the theoretical limit of 91 meV (3.5kBT). The in-situ EQCS platform can be further used to monitor and manipulate the DOS in real-time, enabling a controlled enhancement of electrochemical reactions. Notably, band shifts driven by as little as ≈ 1% mechanical strain can increase of the catalytic activity for hydrogen generation by half an order of magnitude. The EQCS platform provides a powerful new method for probing and manipulating the intrinsic DOS and defect states of 2D materials in ambient environments.