Hot-Electron-Assisted Femtosecond All-Optical Modulation in Plasmonics

Abstract

The optical Kerr nonlinearity of plasmonic metals provides enticing prospects for developing reconfigurable and ultracompact all-optical modulators. In nanostructured metals, the coherent coupling of light energy to plasmon resonances creates a nonequilibrium electron distribution at an elevated electron temperature that gives rise to significant Kerr optical nonlinearities. Although enhanced nonlinear responses of metals facilitate the realization of efficient modulation devices, the intrinsically slow relaxation dynamics of the photoexcited carriers, primarily governed by electron–phonon interactions, impedes ultrafast all-optical modulation. Here, femtosecond (≈190 fs) all-optical modulation in plasmonic systems via the activation of relaxation pathways for hot electrons at the interface of metals and electron acceptor materials, following an on-resonance excitation of subradiant lattice plasmon modes, is demonstrated. Both the relaxation kinetics and the optical nonlinearity can be actively tuned by leveraging the spectral response of the plasmonic design in the linear regime. The findings offer an opportunity to exploit hot-electron-induced nonlinearities for design of self-contained, ultrafast, and low-power all-optical modulators based on plasmonic platforms.

Exchange of hot electrons at the interface of plasmonic metals and electron acceptor materials is employed to enable an electron-dominated relaxation pathway for demonstration of femtosecond (≈190 fs) all-optical modulation in plasmonic systems. Relaxation dynamics and optical nonlinearity are actively tuned by leveraging the linear spectral response of a designed plasmonic lattice suitable for all-optical data processing.

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