Projects per year
Abstract
Electronic energy transfer (EET) in organic materials is a key mechanism that controls the efficiency of many processes, including light harvesting antennas in natural and artificial photosynthesis, organic solar cells, and biological systems. In this paper we have examined EET in solid-state thin-films of polyfluorene, a prototypical conjugated polymer, with ultrafast photoluminescence experiments and theoretical modeling. We observe EET occurring on a 680 ± 300 fs time scale by looking at the depolarisation of photoluminescence. An independent, predictive microscopic theoretical model is built by defining 125 000 chromophores containing both spatial and energetic disorder appropriate for a spin-coated thin film. The model predicts time-dependent exciton dynamics, without any fitting parameters, using the incoherent Förster-type hopping model. Electronic coupling between the chromophores is calculated by an improved version of the usual line-dipole model for resonant energy transfer. Without the need for higher level interactions, we find that the model is in general agreement with the experimentally observed 680 ± 300 fs depolarisation caused by EET. This leads us to conclude that femtosecond EET in polyfluorene can be described well by conventional resonant energy transfer, as long as the relevant microscopic parameters are well captured. The implications of this finding are that dipole-dipole resonant energy transfer can in some circumstances be fully adequate to describe ultrafast EET without needing to invoke strong or intermediate coupling mechanisms.
Original language | English |
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Pages (from-to) | 9734-9744 |
Number of pages | 11 |
Journal | Journal of Physical Chemistry C |
Volume | 119 |
Issue number | 18 |
Early online date | 15 Apr 2015 |
DOIs | |
Publication status | Published - 7 May 2015 |
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Dive into the research topics of 'Subpicosecond exciton dynamics in polyfluorene films from experiment and microscopic theory'. Together they form a unique fingerprint.Projects
- 3 Finished
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ERC Advanced Grant EXCITON: EU FP7 ERC Advanced Grant 2012 EXCITON
Samuel, I. D. W. (PI)
1/04/13 → 30/03/19
Project: Standard
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The Influence of Excited State Physics: The influence of Excited State Physics in Conjugated Polymer Devices
Samuel, I. D. W. (PI)
1/10/12 → 30/09/15
Project: Standard
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EP/E062636/1 Polymer Photonic Devices: The Physics of Polymer Photonic Devices: Experiment and Theory
Samuel, I. D. W. (PI) & Turnbull, G. (CoI)
1/07/08 → 30/06/11
Project: Standard