Thermodynamics and Kinetics of Protonated Merocyanine Photoacids in Water

Overview

Journal Chem Sci

Publisher Royal Society of Chemistry

Specialty Chemistry

Date 2021 Jun 14

PMID 34123105

Citations 18

Authors

Cesare Berton

Daniel Maria Busiello

Stefano Zamuner

Euro Solari

Rosario Scopelliti

Farzaneh Fadaei-Tirani

Kay Severin

Cristian Pezzato

Affiliations

Soon will be listed here.

Abstract

Metastable-state photoacids (mPAHs) are chemical species whose photo-activated state is long-lived enough to allow for proton diffusion. Liao's photoacid () represents the archetype of mPAHs, and is being widely used on account of its unique capability to change the acidity of aqueous solutions reversibly. The behavior of in water, however, still remains poorly understood. Herein, we provide in-depth insights on the thermodynamics and kinetics of in water through a series of comparative H NMR and UV-Vis studies and relative modelling. Under dark conditions, we quantified a three-component equilibrium system where the dissociation ( ) of the open protonated form (MCH) is followed by isomerization ( ) of the open deprotonated form (MC) to the closed spiropyran form (SP) - , in the absence of light, the ground state acidity can be expressed as = (1 + ). On the other hand, under powerful and continuous light irradiation we were able to assess, for the first time experimentally, the dissociation constant ( ) of the protonated metastable state (-MCH). In addition, we found that thermal ring-opening of SP is always rate-determining regardless of pH, whereas hydrolysis is reminiscent of what is found for Schiff bases. The proposed methodology is general, and it was applied to two other compounds bearing a shorter (ethyl, ) and a longer (butyl, ) alkyl-1-sulfonate bridge. We found that the p remains constant, whereas both p and p linearly increase with the length of the alkyl bridge. Importantly, all results are consistent with a four-component model cycle, which describes perfectly the full dynamics of proton release/uptake of in water. The superior hydrolytic stability and water solubility of compound , together with its relatively high p (low ), allowed us to achieve fully reversible jumps of 2.5 pH units over 18 consecutive cycles (6 hours).

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