As a platform for generating solar fuels, dye-sensitized photoelectrochemical cells (DS-PECs) offer a promising solution. DS-PECs effectively address the intermittency issues inherent to solar and wind energy by storing solar energy in chemical bonds to generate sustainable fuels. However, the design of efficient DS-PECs remains challenging due to sluggish catalytic turnovers and low charge separation efficiencies. Addressing these limitations requires a deeper understanding of the physical mechanisms that govern these processes. With this goal in mind, this dissertation aims to elucidate at an atomistic level the mechanisms that drive photo-induced charge separation and catalysis in various components of DS-PEC devices. A strong emphasis is placed on the coupled motion of nuclear and electronic degrees of freedom, which I demonstrate to be crucial for many of the investigated systems.

• dye-sensitized photoelectrochemical cell (ds-pec)
• sustainability

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