First, different active materials have been screened. For that purpose, the technology for the screening has been improved. Firstly, new sensors to determine the state-of-charge (SOC) and state-of-health (SOH) of redox flow battery electrolytes have been developed. A novel analytical approach was utilized, which is based on chronoamperometry. In contrast to previous studies, the transient chronoamperometric signal was utilized for the analysis. For this purpose, micro- as well as macroelectrodes could be utilized for ex situ, and more importantly also for in operando SOC measurements. Furthermore, the thermal stability of ferrocene-based copolymers has been studied in detail. Ferrocenes represent very promising active materials. The copolymer revealed still a good thermal stability at elevated temperatures (60 °C). The stability of the ferrocenes is higher compared to the established TEMPO materials.
The study of the active materials has been based on the two “working horses” TEMPO as well as viologen. Both electrolytes are well-known, and these redox moieties are the first active materials, which have been utilized for the assembly of more complex polymer structures. Ferrocenes have been studied intensively as new catholytes. These materials have been proven to be more stable compared to the standard catholyte – TEMPO. Consequently, the stability of different ferrocenes is studied currently in copolymers in order to elucidate the influence of the polymer structure on the stability.
Furthermore, the first advanced polymer structures have been prepared successfully. Hyperbranched TEMPO polymers have been synthesized in a step-growth polymerization. These materials revealed promising electrochemical properties. Furthermore, the hyperbranched structure led to a decreased viscosity compared to linear TEMPO copolymers as well as a faster diffusion and charge transfer rate. Consequently, the major drawbacks of polymeric electrolytes could be decreased.