Infrared Nonlinear Photomixing Spectroscopy of Graphene Thermal Relaxation

Hot electron effects in graphene are significant because of graphene's small electronic heat capacity and weak electron-phonon coupling, yet the dynamics and cooling mechanisms of hot electrons in graphene are not completely understood. We describe a photocurrent spectroscopy method that uses the mixing of continuous-wave lasers in a graphene photothermal detector to measure the frequency dependence and nonlinearity of hot-electron cooling in graphene as a function of the carrier concentration and temperature. Our measurements reveal that near the charge-neutral-point the electron cooling is well described by disorder-assisted collisions, while at higher carrier concentrations conventional momentum-conserving cooling mechanisms prevail. Furthermore, the method provides a unique frequency-domain measurement of the cooling rate that is not constrained by the width (temporal resolution) and the high intensity of the optical pulse. The photomixing spectroscopy method is well suited to measure the nonlinearity and response time of other photosensitive nanoscale materials and devices.

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