Singlet Fission in Lycopene H-Aggregates

TL;DR

This paper presents a theoretical model explaining singlet fission in lycopene H-aggregates, detailing the excited state relaxation pathways and predicting the timescales for triplet-pair state evolution and free triplet formation.

Contribution

It introduces a new theoretical framework for understanding singlet fission in carotenoid dimers, specifically lycopene, including detailed state relaxation mechanisms and timescale predictions.

Findings

Complete population transfer to intermonomer triplet-pair state within 100 ps

Partial population of intermonomer quintet triplet-pair state up to 2 ns

Formation of free triplets within approximately 0.1 microseconds

Abstract

A theory of singlet fission (SF) in carotenoid dimers is applied to explain the SF in lycopene H-aggregates observed after high energy photoexcitation. The explanation proposed here is that a high energy, delocalized bright $^1B_u^+$ state first relaxes and localizes onto a single lycopene monomer. The high-energy intramonomer state then undergoes internal conversion to the $1^1B_u^-$ state. Once populated, the $1^1B_u^-$ state allows exothermic bimolecular singlet fission, while its internal conversion to the $2^1A_g^-$ state is symmetry forbidden. The simulation of SF predicts that the intramonomer triplet-pair state undergoes complete population transfer to the intermonomer singlet triplet-pair state within 100 ps. ZFS interactions then begin to partially populate the intermonomer quintet triplet-pair state up to ca. 2 ns, after which hyperfine interactions thermally equilibrate the triplet-pair states, thus forming free, single triplets within ca. 0.1 $\mu$s.