Design and Application of Triplet-Triplet Annihilation Upconversion Materials

Churchill, Emily Marie

January 2022

Triplet-triplet annihilation upconversion (TTA-UC) is a process which converts two low energy photons into one higher-energy excited state. TTA-UC has recently received attention for its potential application to many light driven processes, such as improving efficiency in photovoltaic devices and allowing use of low-energy light sources for in vivo applications, including bioimaging, optogenetics, and photochemotherapy. Each of these applications has a different set of energetic requirements, which has created a need for a diverse library of upconverting materials. Additionally, these applications benefit from improved upconversion efficiency in solid-state, a task that has proven challenging for the traditionally solution-phase process. Macromolecular scaffolds are a promising avenue to tune the electronic communication between chromophores and control intermolecular packing in solid-state. Herein, we report the investigation of dendrimers with annihilator-functionalized termini and linear annihilator polymers as frameworks to control local annihilator concentration and communication. We find that multi-annihilator dendrimers exhibit higher upconversion yields at low concentrations compared to similar concentrations of monomer; however, higher generation dendrimers allow strong interchromophore coupling, which promotes parasitic excimer formation, decreasing relative upconversion yields. Linear annihilator copolymers with alternating anthracene and phenyl or naphthyl bridges had ground state optical properties predictive of interchromophore communication based on bridge connectivity, interchromophore length, and polymer planarity. Non-conjugated, naphthyl polymers were observed to be the most efficient at intramolecular TTA-UC in dilute solutions. In this dissertation, we will discuss current efforts in the field towards control and analysis of intramolecular TTA-UC through design of multi-annihilator macromolecules and novel annihilator scaffolds targeting underutilized regions of the electromagnetic spectrum. In Chapter 1, we list important factors to consider about improving TTA-UC and follow with discussion of reported macromolecular systems and their efforts towards intramolecular TTA-UC. Chapter 2 introduces a series of non-conjugated dendrimers functionalized with anthracene annihilators on the periphery and analyzes their upconversion capabilities as a set of macromolecules with controlled molecular structure. In Chapter 3, we investigate the effect of connectivity between annihilators in alternating co-polymer systems, discussing the impact on ground state photophysical properties and upconversion efficiency. Finally in Chapter 4, we introduce an approach for using computational analysis as a high-throughput tool for identifying potential novel annihilator molecules.

Chemistry

Annihilation reactions

Anthracene

Dendrimers

Photovoltaic power generation

Photochemotherapy

Optogenetics

The effect of intermolecular interactions and disorder on exciton diffusion in organic semiconductors

Haji Masri, Mohammad K. Z.

January 2015

This thesis presents studies of exciton diffusion in organic semiconductors measured using exciton-exciton annihilation and the measurements were performed on materials important for organic solar cells. In the conjugated polymer poly(3-hexylthiophene) (P3HT), the effect of molecular weight (4-76 kgmol⁻¹) was explored. Using exciton-exciton annihilation measurements, the highest diffusion coefficient was observed in the intermediate molecular weight region and was correlated with long conjugation lengths, higher fraction of aggregated states and more delocalised excitons within the aggregate. The results demonstrated that the molecular weight dependence is due to a complex relationship between intermolecular interactions, aggregate size and Boltzmann statistics. This thesis also includes an investigation of exciton diffusion in diketopyrrolopyrrole(DPP)-based small molecules as a function of molecular structure. Significant changes in photophysical and exciton diffusion properties were observed due to minor changes in molecular structure. Long conjugation lengths, bulky side chains or reduced steric hindrance due to absence of end alkyl chains correlated with reduced film crystallinity and reduced diffusion coefficients. The increase in disorder observed due to large conformational torsions resulted in inhomogeneous broadening of density of states and as a result exciton diffusion becomes dispersive. In this case, a slowdown of exciton diffusion is observed. This study demonstrates that enhanced exciton diffusion can be achieved by designing more rigid and planar conjugated backbones with smaller conjugation lengths. Finally, exciton diffusion measurements were used to rationalise the performance of T3 truxene oligomers as explosive sensors. Side chain lengths were found to have a subtle influence on exciton diffusion. Time-resolved PL quenching measurements were used to estimate the quencher concentration. Differences in quencher concentration were observed suggesting different interaction strengths of the quencher with the truxene oligomer which help explain the explosive sensing performance.

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