Electrochemical Doping in Ordered and Disordered Domains of Conjugated Polymers

TL;DR

This study investigates how the coexistence of order and disorder in conjugated polymers influences electrochemical doping, revealing that bipolarons form faster in disordered regions and significantly enhance conductivity, impacting device performance.

Contribution

It demonstrates the structure-property relationships in conjugated polymers, showing how morphology affects doping dynamics and conductivity, using advanced spectroscopic and conductivity measurements.

Findings

Bipolarons form faster in disordered regions.

Polarons prefer ordered domains.

Enhanced conductivity occurs with bipolaron formation in disordered regions.

Abstract

Conjugated polymers are increasingly used as organic mixed ionic-electronic conductors in electrochemical devices for neuromorphic computing, bioelectronics and energy harvesting. The design of efficient applications relies on high electrochemical doping levels, high electronic conductivity, fast doping/dedoping kinetics and high ionic uptake. In this work, we establish structure-property relations and demonstrate how these parameters can be modulated by the co-existence of order and disorder. We use in-situ time-resolved spectroelectrochemistry, resonant Raman and terahertz conductivity measurements to investigate the electrochemical doping in the different morphological domains of poly(3-hexylthiophene). Our main finding is that bipolarons are found preferentially in disordered polymer regions, where they are formed faster and are thermodynamically more favoured. On the other hand, polarons show a preference for ordered domains, leading to drastically different bipolaron/polaron ratios and doping/dedoping dynamics in the distinct regions. We evidence a significant enhancement of the electronic conductivity when bipolarons start being formed in the disordered regions, while the presence of bipolarons in the ordered regions is detrimental for transport. Our study provides significant advances in the understanding of the impact of morphology on the electrochemical doping of conjugated polymers and the induced increase in conductivity.