Spin-dependent charge recombination along para-phenylene molecular wires

TL;DR

This study uses a new quantum mechanical method to analyze spin-dependent charge recombination in molecular wires, revealing different length dependencies for singlet and triplet pathways and suggesting mechanisms for their behaviors.

Contribution

Introduces a novel quantum method to extract spin-dependent recombination rates from experimental data, providing insights into charge transfer mechanisms in molecular wires.

Findings

Triplet recombination rate decreases exponentially with wire length.

Singlet recombination rate is nearly independent of wire length.

Evidence of a magnetic field-independent background contribution to triplet yield.

Abstract

We have used an efficient new quantum mechanical method for radical pair recombination reactions to study the spin-dependent charge recombination along PTZ$^{\bullet+}$--Ph$_n$--PDI$^{\bullet-}$ molecular wires. By comparing our results to the experimental data of E. Weiss {\em et al.} [J. Am. Chem. Soc. {\bf 126}, 5577 (2004)], we are able to extract the spin-dependent (singlet and triplet) charge recombination rate constants for wires with $n=2-5$. These spin-dependent rate constants have not been extracted previously from the experimental data because they require fitting its magnetic field-dependence to the results of quantum spin dynamics simulations. We find that the triplet recombination rate constant decreases exponentially with the length of the wire, consistent with the superexchange mechanism of charge recombination. However, the singlet recombination rate constant is nearly independent of the length of the wire, suggesting that the singlet pathway is dominated by an incoherent hopping mechanism. A simple qualitative explanation for the different behaviours of the two spin-selective charge recombination pathways is provided in terms of Marcus theory. We also find evidence for a magnetic field-independent background contribution to the triplet yield of the charge recombination reaction, and suggest several possible explanations for it. Since none of these explanations is especially compelling given the available experimental evidence, and since the result appears to apply more generally to other molecular wires, we hope that this aspect of our study will stimulate further experimental work.