MESO HIERARCHY

Suppose we possess the capability to manipulate the photophysical properties of materials, specifically exciton dynamics, at the meso-scale. In such a scenario, we can usher in a new era of optoelectronics that bridges the gap between the nano- and micro-scales, exerting a significant impact on the fields of energy and environmental science. However, currently, there is no promising method available for analyzing and controlling exciton dynamics at the meso-scale. The goal of this project is to develop a measurement technique that unravels the intricacies of exciton dynamics in meso-structures. To achieve this, we will employ a 10 nm remote excitation method, originally devised by the Principal Investigators. Additionally, we will utilize optical cavity strong coupling to manipulate ultra-long-range energy transfer and exciton dynamics in meso-structures. This will enable us to develop a methodology for expressing unique photophysical properties. With these advanced technologies, we..