Abstract
Anthropogenic climate change urgently calls for the greening and intensification of the chemical industry. Most chemical reactors make use of catalysts to increase their conversion yields, but their operation at steady-state temperatures limits their rate, selectivity, and energy efficiency. Here, we show how to break such a steady-state paradigm using ultrashort light pulses and photothermal nanoparticle arrays to modulate the temperature of catalytic sites at timescales typical of chemical processes. Using heat dissipation and time-dependent microkinetic modeling for a number of catalytic landscapes, we numerically demonstrate that pulsed photothermal catalysis can result in a favorable, dynamic mode of operation with higher energy efficiency, higher catalyst activity than for any steady-state temperature, reactor operation at room temperature, resilience against catalyst poisons, and access to adsorbed reagent distributions that are normally out of reach. Our work identifies the key experimental parameters controlling reaction rates in pulsed heterogeneous catalysis and provides specific recommendations to explore its potential in real experiments, paving the way to a more energy-efficient and process-intensive operation of catalytic reactors.
Original language | English |
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Pages (from-to) | 3419-3432 |
Number of pages | 14 |
Journal | ACS Catalysis |
Volume | 13 |
Issue number | 5 |
Early online date | 22 Feb 2023 |
DOIs | |
Publication status | Published - 3 Mar 2023 |
Bibliographical note
Funding Information:S.H.C.A. gratefully acknowledges the Dutch Research Council (NWO) for Veni (VI.Veni.192.062) and NWO-XS grants (OCENW.XS21.4.167). A.B. gratefully acknowledges the Dutch Research Council (NWO) for the Vidi 680-47-550 grant.
Publisher Copyright:
© 2023 The Authors. Published by American Chemical Society.
Keywords
- microkinetic simulations
- nonsteady state
- out-of-equilibrium
- photothermal catalysis
- plasmonics
- pulsed light