A nanophotonic-enhanced SHG platform with a new overlap-integral formalism enables quantitative probing of light-driven interfacial dynamics, showing electrolyte-dependent spectral shifts and intensity-dependent susceptibility changes at silicon-oxide-electrolyte interfaces.
Chemical Reviews122(12), 10821–10859 (2022) https://doi
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Derives time-dependent voltage protocols that eliminate an arbitrary number of relaxation modes to accelerate charging and discharging of planar EDLCs in finite time shorter than intrinsic relaxation timescales.
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Revealing Light-Driven Dynamics at Nanostructured Solid-Liquid Interfaces with In-Situ SHG
A nanophotonic-enhanced SHG platform with a new overlap-integral formalism enables quantitative probing of light-driven interfacial dynamics, showing electrolyte-dependent spectral shifts and intensity-dependent susceptibility changes at silicon-oxide-electrolyte interfaces.
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Accelerating charging dynamics of electric double-layer capacitors
Derives time-dependent voltage protocols that eliminate an arbitrary number of relaxation modes to accelerate charging and discharging of planar EDLCs in finite time shorter than intrinsic relaxation timescales.