Plasmon-Driven C–N Bond Cleavage Across a Series of Viologen Derivatives

Brooks, James L.; Chulhai, Dhabih V.; Yu, Ziwei; Goodpaster, Jason D.; Frontiera, Renee R.

Plasmon-Driven C–N Bond Cleavage Across a Series of Viologen Derivatives

2019

Brooks, James L. | Chulhai, Dhabih V. | Yu, Ziwei | Goodpaster, Jason D. | Frontiera, Renee R.

The optical excitation of surface plasmons leads to the generation of highly enhanced nanoscale local fields and an abundance of harvestable hot carriers. When certain analytes are positioned within these unique environments, surface plasmons may be able to induce chemical reactions that are energetically unfavorable under standard conditions. Sometimes, the plasmonic environments can initiate entirely new reaction pathways for the chemical adsorbates. Here, we investigate the nature of plasmon-driven reactions on three viologen derivatives: methyl viologen, ethyl viologen, and benzyl viologen. Viologens have traditionally been employed as excellent redox agents due to their ability to reversibly stabilize additional electrons in their molecular structures. However, by using surface-enhanced Raman spectroscopy, we were able to directly observe a C–N bond cleavage on benzyl and ethyl viologen to form 4,4′-bipyridine on the surface of gold film-over-nanosphere substrates. Surprisingly, methyl viologen does not undergo a similar process. We posit that this differing reactivity may be due to changes in adsorption geometry or in reduction potential. Using both spectroscopic and theoretical methods, we were able to confirm 4,4′-bipyridine as the plasmon-mediated photoproduct. This work highlights the novelty of using plasmonic environments to access new chemical reactions and adds to the expanding library of plasmon-mediated chemical reactions.

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