Abstract
Owing to the lack of systematic kinetic theory about the redox reaction of V(III)/V(II), the poor electrochemical performance of the negative process in vanadium flow batteries limits the overall battery performance to a great extent. As the key factors that influence electrode/electrolyte interfacial reactivity, the physicochemical properties of the V(III) acidic electrolyte play an important role in the redox reaction of V(III)/V(II), hence a systematic investigation of the physical and electrochemical characteristics of V(III) acidic electrolytes with different concentrations and related diffusion kinetics was conducted in this work. It was found that the surface tension and viscosity of the electrolyte increase with increasing V(III) concentration, while the corresponding conductivity shows an opposite trend. Both the surface tension and viscosity change slightly with increasing concentration of H2SO4, but the conductivity increases significantly, indicating that a lower V(III) concentration and a higher H2SO4 concentration are conducive to the ion transfer process. The electrochemical measurements further show that a higher V(III) concentration will facilitate the redox reaction of V(III)/V(II), while the increase in H2SO4 concentration only improves the ion transmission and has little effect on the electron transfer process. Furthermore, the diffusion kinetics of V(III) have been further studied with cyclic voltammetry and chronopotentiometry. The results show that an elevated temperature facilitates the V(III)/V(II) redox reaction and gives rise to an increased electrode reaction rate constant (ks) and diffusion coefficient [DV(III)]. On this basis, the diffusion activation energy (13.7 kJ·mol−1) and the diffusion equation of V(III) are provided to integrate kinetic theory in the redox reaction of V(III)/V(II).
Highlights
Higher surface tension will hinder the contact between the electrolyte and the electrode, leading to a decrease in the effective reaction area, while higher conductivity often means faster transmission of ions and higher viscosity usually leads to a lower diffusion rate
Vanadium ions often exist in a very complex form in the electrolyte, which may result in a significant difference in the physicochemical properties of the electrolyte at different concentrations (Sepehr and Paddison, 2016)
The surface tension of the electrolytes gradually increases with an increasing concentration of V(III)
Summary
Vanadium flow batteries (VFBs) have been widely developed as a green energy storage technology because of their high energy efficiency, flexible design, long life cycle, high safety, and low cost (Rychcik and Skyllas-Kazacos, 1988; Sun and Skyllas-Kazacos, 1992; Joerissen et al, 2004; Sukkar and Skyllas-Kazacos, 2004; Zhao et al, 2006; Rahman and Skyllas-Kazacos, 2009; Ding et al, 2013; Chakrabarti et al, 2014; Zheng et al, 2016). VFBs are mainly composed of the electrolyte, electrode, ion exchange membrane, and a bipolar plate. The concentrations of vanadium and H+ ions play an important role in the determination of the electrochemical reaction processes and the battery performance. Sun and Skyllas-Kazacos (Sum and Skyllas-Kazacos, 1982) investigated the electrochemical behavior of the V(III)/V(II) redox couple at glassy carbon electrodes using cyclic voltammetry (CV). They found that the oxidation/reduction reaction is electrochemically irreversible and the surface preparation is very critical in determining the electrochemical behavior. Most studies (Sum and SkyllasKazacos, 1982; Oriji et al, 2005; Lee et al, 2012; Aaron et al, 2013; Sun et al, 2016) found that the electrode reaction rate of V(III)/V(II) is much less than that of V(IV)/V(V); systematic investigations into the detailed mechanism remain scarce
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