Nanoparticle size-dependent singlet fission and exciton dynamics in amorphous TIPS-pentacene
Date
2021
Authors
Hudson, R.J.
Stuart, A.N.
De La Perrelle, J.M.
Huang, D.M.
Kee, T.W.
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Journal article
Citation
Journal of Physical Chemistry C, 2021; 125(39):21559-21570
Statement of Responsibility
Rohan J. Hudson, Alexandra N. Stuart, Jessica M. de la Perrelle, David M. Huang, and Tak W. Kee
Conference Name
Abstract
Aqueous nanoparticle (NP) dispersions are commonly used as model systems for the spectroscopic study of singlet exciton fission (SF) in acenes such as 6,13-(triisopropylsilylethynyl)pentacene (TIPS-Pn). However, the potential for particle size effects to complicate interpretation of results in such model systems is generally ignored. In this work, we study amorphous TIPS-Pn NP dispersions prepared by the re-precipitation method over a range of particle sizes. Time-resolved fluorescence and femtosecond transient absorption spectroscopies show that exciton dynamics in these systems depend significantly upon particle size. Kinetic analysis reveals that SF becomes slower at smaller NP sizes, while triplet exciton decay (through both correlated triplet pair relaxation and geminate triplet–triplet annihilation) accelerates. These significant size-dependent effects are ascribed to increased morphological disorder within smaller NPs, weakening the intermolecular couplings which control SF and triplet migration. A non-radiative singlet quenching channel separate from SF is also identified, which has not been previously reported for NPs of SF-capable chromophores. This non-radiative singlet decay becomes a significant relaxation pathway at small particle sizes, substantially reducing SF yields. Interestingly, exciton kinetics in the largest NPs considered here (81 nm diameter) approach those of bulk amorphous TIPS-Pn. This work demonstrates that particle size effects are significant for small NPs of SF chromophores and must be accounted for in order to accurately model bulk materials with such NP dispersions.
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Data source: Supporting information, https://pubs.acs.org/doi/10.1021/acs.jpcc.1c07048?goto=supporting-info
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© 2021 American Chemical Society