Understanding the Role of Triplet-triplet Annihilation in Non-fullerene Acceptor Organic Solar Cells

TL;DR

This paper investigates how triplet-triplet annihilation (TTA) influences the efficiency of non-fullerene acceptor organic solar cells, highlighting the role of molecular properties and crystallinity in managing triplet excitons to reduce voltage losses.

Contribution

It provides a kinetic framework for understanding TTA effects in OSCs and identifies conditions where TTA can enhance device performance by reducing non-radiative losses.

Findings

Higher crystallinity in Y11 leads to increased TTA.

Y11's larger ground state dipole moment improves out-of-plane ordering.

TTA can potentially reduce voltage losses by tens of millivolts.

Abstract

Non-fullerene acceptors (NFAs) have enabled power conversion efficiencies exceeding 19% in organic solar cells (OSCs). However, the open-circuit voltage of OSCs remains low relative to their optical gap due to excessive non-radiative recombination, and this now limits performance. Here, we consider an important aspect of OSC design, namely management of the triplet exciton population formed after non-geminate charge recombination. By comparing the blends PM6:Y11 and PM6:Y6, we show that the greater crystallinity of the NFA domains in PM6:Y11 leads to a higher rate of triplet-triplet annihilation (TTA). We attribute this to the four times larger ground state dipole moment of Y11 versus Y6, which improves the long range NFA out-of-plane ordering. Since TTA converts a fraction of the non-emissive triplet states into bright singlet states, it has the potential to reduce non-radiative voltage losses. Through a kinetic analysis of the recombination processes under 1-Sun illumination, we provide a framework for determining the conditions under which TTA may improve OSC performance. If these could be satisfied, TTA has the potential to reduce non-radiative voltage losses by up to several tens of mV and could thus improve OSC performance.