Excitation wavelength dependence of the charge separation pathways in tetraporphyrin-naphthalene diimide pentads

The excited-state dynamics of two multichromophoric arrays composed of a naphthalene diimide centre and four zinc or free-base porphyrins substituted on the naphthalene core via aniline bridges has been investigated using a combination of stationary and ultrafast spectroscopy. These pentads act as e...

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Bibliographic Details
Published in:Physical chemistry chemical physics : PCCP 2014-03, Vol.16 (11), p.5188-5200
Main Authors: Villamaina, Diego, Kelson, Melissa M A, Bhosale, Sheshanath V, Vauthey, Eric
Format: Article
Language:English
Subjects:
Arrays
Charge
Diimide
Energy gap
Imides - chemistry
Naphthalene
Naphthalenes - chemistry
Porphyrins
Porphyrins - chemistry
Separation
Solvents
Spectrometry, Fluorescence
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Summary:The excited-state dynamics of two multichromophoric arrays composed of a naphthalene diimide centre and four zinc or free-base porphyrins substituted on the naphthalene core via aniline bridges has been investigated using a combination of stationary and ultrafast spectroscopy. These pentads act as efficient antennae as they absorb over the whole visible region, with a band around 700 nm, associated with a transition to the S1 state delocalised over the whole arrays, and bands at higher energy due to transitions centred on the porphyrins. In non-polar solvents, population of these porphyrin states is followed by sub-picosecond internal conversion to the S1 state. The existence of a charge-separated state located above the S1 state could enhance this process. The decay of the S1 state is dominated by non-radiative deactivation on the 100 ps timescale, most probably favoured by the small S1-S0 energy gap and the very high density of vibrational states of these very large chromophores. In polar solvents, the charge-separated state lies just below the S1 state. It can be populated within a few picoseconds by a thermally activated hole transfer from the S1 state as well as via sub-picosecond non-equilibrium electron transfer from vibrationally hot porphyrin excited states. Because of the small energy gap between the charge-separated state and the ground state, charge recombination is almost barrierless and occurs within a few picoseconds. Despite their very different driving forces, charge separation and recombination occur on similar timescales. This is explained by the electronic coupling that differs considerably for both processes.
ISSN:1463-9076
1463-9084
DOI:10.1039/c3cp54871f