Heisenberg spin exchange and relaxation dynamics in EPR oximetry: A photoinduced transition from non-adiabatic rapid-sweeps to the rapid-scan regime

Key Points

Rapid-scan EPR reveals changes in oxygen concentration through EPR lineshape distortions, indicating a significant finding for biochemical studies.
The research shows control over oxygen partial pressure using lithium phthalocyanine and CTPO as spin probes in photochemical reactions.
Observational analysis of relaxation dynamics was conducted by examining the effects of Heisenberg spin exchange on EPR signals.
Potential applications of this technique include studying oxidation processes in biochemical systems under varying oxygen levels.

Abstract

Rapid-scan electron paramagnetic resonance spectroscopy (RS EPR) has emerged as a powerful tool to monitor light-induced processes accompanied by changes of the EPR lineshape and is frequently used for measuring local oxygen concentrations. Here we use LiPc (lithium phthalocyanine) and CTPO (3-Carbamoyl-2,2,5,5-tetramethyl-3-pyrrolin-1-oxyl) as spin probes and demonstrate control over the oxygen partial pressure through a photochemical reaction. The resulting changes in pO2 manifest as characteristic distortions of the EPR lineshape and reveal how Heisenberg spin exchange influences relaxation dynamics. As a proof-of-concept, we investigate photopolymerization at reduced oxygen levels. These results highlight the potential of RS for studying oxidation processes in biochemical systems.

Heisenberg spin exchange and relaxation dynamics in EPR oximetry: A photoinduced transition from non-adiabatic rapid-sweeps to the rapid-scan regime

Key Points

Abstract

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