Historically, time-resolved optical spectroscopy is used to study photoinitiated chemical reactions or physical processes that underlie energy conversion technologies, such as solar cells. However, many electronic and electrochemical/charge storage devices do not use light to operate, discouraging studies with optical spectroscopy. We are developing time-resolved spectroscopy methods for probing dynamics that are not initiated by light, and envision optical spectroscopy as a powerful tool for monitoring structure and charge transport in light-inactive materials. We further envision using ultrafast spectroscopy measurements to probe slow timescale dynamics, such as charge diffusion and storage. We propose that ultrafast snapshots of the system, taken on-the-fly, provide more detailed information about such slower processes integral to applications including electrochemical energy storage.