Emily Lichko, Naval Research Laboratory  Frequency-resolved local measurements of phase-space energization  In order to disentangle the competing kinetic-scale energy dissipation processes that are intrinsic to collisionless plasmas, like those found in space and astrophysical systems, it is critical to diagnose the local energy transfer that is occurring between fields and particles in both time and space. A relatively recent technique to resolve the local rate of energy transfer between the fields and particles is the field-particle correlation, which has resolved local energy transfer at a single point in space for a large variety of systems and physical processes. This work details an updated version of the field-particle correlation that includes for the first time a breakdown of the energy transfer in frequency space, as well as time and velocity space. In addition to the increase in available information, this new method more cleanly separates magnitude and phase information of the signal, resulting in an improvement of the temporal resolution. This new method is applied to Gkeyll simulations of electron Landau damping as a proof of concept, as well as Magnetospheric MultiScale (MMS) observations of Landau damping in the solar wind.