Publications by authors named "Maksim Lednev"
Optical control is achieved on the excited state energy transfer between spatially separated donor and acceptor molecules, both coupled to the same optical mode of a cavity. The energy transfer occurs through the formed hybrid polaritons and can be switched on and off by means of ultraviolet and visible light. The control mechanism relies on a photochromic component used as donor, whose absorption and emission properties can be varied reversibly through light irradiation, whereas in-cavity hybridization with acceptors through polariton states enables a 6-fold enhancement of acceptor/donor contribution to the emission intensity with respect to a reference multilayer.
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- The study addresses challenges in understanding ultrastrong coupling between quantized light and matter, which complicates common theoretical approaches.
- A new method is proposed that successfully describes the dynamics of hybrid quantum systems across various interaction strengths, utilizing a modified Lindblad master equation.
- The effectiveness of this approach is validated through comparisons with existing models, particularly in applications that current theories struggle to handle, such as realistic nanoplasmonic systems.
Resonant interaction between excitonic transitions of molecules and localized electromagnetic field allows the formation of hybrid light-matter polaritonic states. This hybridization of the light and the matter states has been shown to significantly alter the intrinsic properties of molecular ensembles placed inside the optical cavity. Here, we have observed strong coupling of excitonic transition in a pair of closely located organic dye molecules demonstrating an efficient donor-to-acceptor resonance energy transfer with the mode of a tuneable open-access cavity.
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