Frenkel biexcitons in hybrid HJ photophysical aggregates

TL;DR

This paper demonstrates the direct observation of bound Frenkel biexcitons in a polymeric semiconductor using nonlinear spectroscopy, linking their binding energies to molecular parameters and revealing unexpected interchain/intrachain correlations.

Contribution

It provides the first direct evidence of bound biexcitons in a model polymeric semiconductor and establishes a quantum-mechanical framework relating biexciton binding energy to molecular parameters.

Findings

Identification of bound biexcitons via nonlinear spectroscopy

Unexpected interchain and intrachain correlation findings

Relation of biexciton binding energy to molecular parameters

Abstract

Frenkel excitons, the primary photoexcitations in organic semiconductors that are unequivocally responsible for the optical properties of this materials class, are predicted to form \emph{bound} exciton pairs, i.e., biexcitons. These are key intermediates, ubiquitous in many relevant photophysical processes; for example, they determine the exciton bimolecular annihilation dynamics in such systems. Deciphering the details of biexciton correlations is, thus, of utmost importance to understand the optical processes in these semiconductors. To date, however, due to their spectral ambiguity, there has been only scant direct evidence of bound biexcitons, limiting the insights that can be gained. Moreover, a quantum-mechanical basis describing biexciton correlation/stability has so far been lacking. By employing nonlinear coherent spectroscopy, we identify here bound biexcitons in a model polymeric semiconductor. We find, unexpectedly, that excitons with \emph{interchain} vibronic dispersion reveal \emph{intrachain} biexciton correlations and vice versa. Moreover, using a Frenkel exciton model, we can relate the biexciton binding energy to molecular parameters quantified by quantum chemistry, including the magnitude and sign of the exciton-exciton interaction the inter-site hopping energies. Therefore, our work promises a window towards general insights into the many-body electronic structure in polymeric semiconductors and beyond; e.g., other excitonic systems such as organic semiconductor crystals, molecular aggregates, photosynthetic light-harvesting complexes, or DNA.