Electron Transfer across o‑Phenylene Wires - ACS Publications

Dec 28, 2018 - The key finding is that the flexible o-phenylene bridges permit rapid formation of photoproducts storing ca. 1.7 eV of energy with life...
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Article Cite This: J. Phys. Chem. A XXXX, XXX, XXX−XXX

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Electron Transfer across o‑Phenylene Wires Sabine Malzkuhn, Xingwei Guo, Daniel Häussinger, and Oliver S. Wenger* Department of Chemistry, University of Basel, St. Johanns-Ring 19, 4056 Basel, Switzerland

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S Supporting Information *

ABSTRACT: Photoinduced electron transfer across rigid rod-like oligo-p-phenylenes has been thoroughly investigated in the past, but their o-connected counterparts are yet entirely unexplored in this regard. We report on three molecular dyads comprised of a triarylamine donor and a Ru(bpy)32+ (bpy =2,2′-bipyridine) acceptor connected covalently by 2 to 6 o-phenylene units. Pulsed excitation of the Ru(II) sensitizer at 532 nm leads to the rapid formation of oxidized triarylamine and reduced ruthenium complex via intramolecular electron transfer. The subsequent thermal reverse charge-shift reaction to reinstate the electronic ground-state occurs on a time scale of 120−220 ns in deaerated CH3CN at 25 °C. The conformational flexibility of the o-phenylene bridges causes multiexponential transient absorption kinetics for the photoinduced forward process, but the thermal reverse reaction produces single-exponential transient absorption decays. The key finding is that the flexible o-phenylene bridges permit rapid formation of photoproducts storing ca. 1.7 eV of energy with lifetimes on the order of hundreds of nanoseconds, similar to what is possible with rigid rod-like donor−acceptor compounds. Thus, the conformational flexibility of the o-phenylenes represents no disadvantage with regard to the photoproduct lifetimes, and this is relevant in the greater context of light-to-chemical energy conversion.





INTRODUCTION

Long-range electron transfers play key roles in many biological and artificial systems, and neither photosynthesis nor respiration would function without them.1 With artificial photosynthesis as a long-term perspective, many prior investigations concentrated on obtaining long-lived electron− hole pairs in donor-bridge-acceptor compounds,2−10 whereas other studies explored the distance or driving-force dependence of electron transfer rates (kET).11−19 Rigid rod-like molecular bridges are usually preferred, because they yield systems with well-defined donor−acceptor distances and restricted conformational degrees of freedom, simplifying the analysis of kinetic data. Oligo-p-phenylenes are a prototype class of relatively rigid spacers and as such have received considerable attention,20−36 but to our knowledge there have been no prior studies of photoinduced long-range electron transfer across oligo-o-phenylenes. Recently, much progress has been made in the controlled synthesis of monodisperse o-phenylene oligomers,37−45 and under favorable conditions helical folding was observed as a consequence of arene−arene interactions.40,46−50 Furthermore, oligo-o-phenylenes were found to exhibit remarkably long effective conjugation lengths.37,51 Against this background and given the role of the respective p-isomers as prototype molecular wires it seemed attractive to explore long-range electron transfer in oligo-o-phenylenes. © XXXX American Chemical Society

RESULTS AND DISCUSSION

We synthesized a series of compounds comprised of a triarylamine (TAA) donor, variable-length o-phenylene bridges, and a Ru(bpy)32+ (bpy =2,2′-bipyridine) acceptor (Figure 1), relying on recently reported methodologies for modular bridge elongation (see Supporting Information, pp S4−S24).37 The TAA oxidation and Ru(bpy)32+ reduction potentials are essentially invariant with increasing bridge length (Supporting Information, pp S25−S27), and on the basis of the cyclic voltammograms of our dyads we estimate a reaction free energy of ca. −0.4 eV for electron transfer from TAA to 3 MLCT-excited Ru(bpy)32+ in CH3CN for all three compounds (Supporting Information, pp S28−S29). As expected, the common 3MLCT luminescence detectable in the Ru(bpy)32+ parent complex is quenched when this photosensitizer unit is integrated into our donor−bridge−acceptor compounds (Supporting Information, p S30). The photoproducts forming as a result of nonradiative 3MLCT deactivation can readily be identified as TAA+ and Ru(bpy)3+ based on transient absorption spectroscopy (Figure 2a) combined with spectroelectrochemistry (Figure 2b). Following excitation of 20 μM solutions of the dyads from Figure 1c in deaerated CH3CN at 532 nm using laser pulses of ca. 10 ns duration, transient absorption bands with maxima at 370, 510, and 750 nm appear Received: November 20, 2018 Revised: December 15, 2018

A

DOI: 10.1021/acs.jpca.8b11236 J. Phys. Chem. A XXXX, XXX, XXX−XXX

Article

The Journal of Physical Chemistry A

black trace in Figure 2b is a 1:1 superposition of the TAA+ and Ru(bpy)3+ difference spectra, and this linear combination is in excellent agreement with the transient absorption data in Figure 2a. On this short time scale (