Webinar given by Prof. Todd Krauss (University of Rochester)
Abstract:
Semiconductor nanoplatelets (NPLs) are colloidal nanoparticles with dimensions on the order of tens of nanometers in the transverse directions, but with an extremely well-defined thickness. As such, compared to their spherical cousins colloidal quantum dots, NPLs have significantly narrower absorption and fluorescence line widths and exceptionally large oscillator strengths. These particular photophysical properties of NPLs make them attractive candidates for achieving strong light-matter coupling. We will discuss the photophysical properties of CdSe NPL exciton polaritons in a distributed Bragg reflector (DBR) cavity. The molecule-cavity hybrid system is in the strong coupling regime with an 83 meV Rabi splitting, characterized from angle resolved reflectance and photoluminescence measurements. Mixed quantum-classical dynamics simulations are used to understand the polariton photophysics of the hybrid system whereby the electronic and photonic degrees of freedom (DOF) were treated quantum mechanically and the nuclear phononic DOF classically. Numerical simulations agree extremely well with the experimental data, providing a fundamental explanation of the asymmetric intensity distribution of photoluminescence from the upper and lower polariton branches. We will also discuss theoretical investigations of polariton-mediated electron transfer reactions in a model nanoparticle-cavity coupled system. For such a system, photoinduced charge transfer reactions between a bright donor state and dark acceptor state can be significantly enhanced, or suppressed, depending on the particulars of the coupling between the molecular system and the quantized radiation field inside the optical cavity. Altogether, these discoveries prove the feasibility of using polaritons derived from NPLs as a new platform for investigating cavity-mediated physical and chemical processes.
