Photokinetics of Photothermal Reactions

TL;DR

This paper introduces a novel, comprehensive rate-law model for photothermal reactions, enabling better understanding and quantification of their kinetics under various light conditions, filling a significant gap in photochemistry knowledge.

Contribution

The paper presents the first general model equation for integrated rate-laws of photothermal reactions, applicable to different light sources and reaction conditions, validated through simulations and practical examples.

Findings

Validated the model against simulated data.

Demonstrated the model's ability to quantify reaction parameters.

Explored effects of concentration, spectators, and light intensity.

Abstract

Photothermal reactions, involving both photochemical and thermal reaction-steps, are the most abundant sequences in photochemistry. The derivation of their rate-laws is standardized, but the integration of these rate-laws has not yet been achieved. Indeed, the field still lacks integrated rate-laws for the description of these reactions behavior, and/or identification of their reaction-order. This made a comprehensive account of the photo-kinetics of photothermal reactions to be a gap in the knowledge. This gap is addressed in the present paper by introducing an unprecedented general model equation capable to mapping out the kinetic traces of such reactions when exposed to light or in the dark. The integrated rate-law model equation also applies when the reactive medium is exposed to either monochromatic or polychromatic light irradiation. The validity of the model equation was established against simulated data obtained by a fourth-order Runge-Kutta method. It was then used to describe and quantify several situations of photothermal reactions, such as the effects of initial concentration, spectator molecules, and incident radiation intensity, and the impact of the latter on the photonic yield. The model equation facilitated a general elucidation method to determine the intrinsic reaction parameters (quantum yields and absorptivities of the reactive species) for any photothermal mechanism whose number of species are known. This paper contributes to rationalizing photo-kinetics along the same general guidelines adopted in chemical kinetics.