posted on 2024-03-11, 14:09authored byYujin Roh, Yeonghoon Jin, Beomjoon Jeon, Yujin Park, Kyoungsik Yu, Jeong Young Park
Hot
electrons are crucial for unraveling the intrinsic relationship
between chemical reactions and charge transfer in heterogeneous catalysis.
Significant research focused on real-time detection of reaction-driven
hot electron flow (chemicurrent) to elucidate the energy conversion
mechanisms, but it remains elusive because carrier generation contributes
to only part of the entire process. Here, a theoretical model for
quantifying the chemicurrent yield is presented by clarifying the
contributions of hot carrier losses from the internal emission and
multiple reflections. The experimental chemicurrent yield verifies
our model with a reliable mean free path of hot electrons, emphasizing
the importance of comprehensive consideration of the transport process
besides hot electron generation. Moreover, Pt nanoparticles (NPs)-decorated
Au/TiO2 is examined, showing the role of NPs-induced carrier
losses in the performance of catalytic nanodiodes. These findings
are expected to contribute to understanding the hot electron detection
efficiency and designing nanodiodes with enhanced hot carrier flow
and catalytic activity.