Tuning Spontaneous Emission versus Forster Energy Transfer in Biological Systems by Manipulating the Density of Photonic States

TL;DR

This paper presents a theoretical method to control the balance between Forster energy transfer and spontaneous emission in biological systems by manipulating the photonic environment, enabling non-invasive analysis of energy transfer processes.

Contribution

It introduces a novel approach to tune energy transfer and emission efficiencies in biological systems through photonic density of states manipulation without physical separation.

Findings

Manipulating photonic density of states alters emission intensities.

The method allows non-destructive analysis of energy transfer.

Potential applications in biological systems like fluorescent proteins.

Abstract

We theoretically discuss how to tune the competition between Forster transfer and spontaneous emission in a continuous and nondestructive fashion. The proposed approach is especially suitable for delicate biological systems like light harvesting complexes and fluorescent protein oligomers. We demonstrate that the manipulation of the density of photonic states at the emission frequency of the energy donor results in a change of the quantum efficiencies of the competing energy transfer and spontaneous emission processes. This change will be manifested in a modification of the donor and acceptor emission intensities. Thus, by controlling the local density of photonic states Forster coupled systems can be manipulated and analyzed without the need to physically separate donor and acceptor chromophores for individual analysis, which is of interest, for example, for oligomeric reef coral fluorescent proteins.