Manipulating Chemistry with Vacuum Light Fields (Manipulight)
Main funder
Funder's project number: 323996
Funds granted by main funder (€)
- 385 197,00
Funding program
Project timetable
Project start date: 01/09/2019
Project end date: 31/08/2023
Summary
Our aim is to develop nanophotonic catalysts for chemical transformations. In contrast to traditional catalysts that employ chemical interactions, these photonic catalysts will exploit strong light-matter coupling between molecules and confined light modes to reshape the potential energy surface and steer the molecular dynamics.
Principal Investigator
Other persons related to this project (JYU)
Primary responsible unit
Follow-up groups
Related publications and other outputs
- Non-Hermitian molecular dynamics simulations of exciton–polaritons in lossy cavities (2024) Sokolovskii, Ilia; et al.; A1; OA
- Photochemical initiation of polariton-mediated exciton propagation (2024) Sokolovskii, Ilia; et al.; A1; OA
- Multi-scale molecular dynamics simulations of enhanced energy transfer in organic molecules under strong coupling (2023) Sokolovskii, Ilia; et al.; A1; OA
- Tuning the Coherent Propagation of Organic Exciton‐Polaritons through the Cavity Q‐factor (2023) Tichauer, Ruth H.; et al.; A1; OA
- Controlling Exciton Propagation in Organic Crystals through Strong Coupling to Plasmonic Nanoparticle Arrays (2022) Berghuis, Anton Matthijs; et al.; A1; OA
- Identifying Vibrations that Control Non-adiabatic Relaxation of Polaritons in Strongly Coupled Molecule-Cavity Systems (2022) Tichauer, Ruth H.; et al.; A1; OA
- Effect of molecular Stokes shift on polariton dynamics (2021) Hulkko, Eero; et al.; A1; OA
- Multi-scale dynamics simulations of molecular polaritons : the effect of multiple cavity modes on polariton relaxation (2021) Tichauer, Ruth H.; et al.; A1; OA
