Abstract
A core component of energy storage systems like vanadium redox flow batteries (VRFB) is the polymer electrolyte membrane (PEM). In this work, the frequently used perfluorosulfonic-acid (PFSA) membrane Nafion™ 117 and a novel poly (vinylidene difluoride) (PVDF)-based membrane are investigated. A well-known problem in VRFBs is the vanadium permeation through the membrane. The consequence of this so-called vanadium crossover is a severe loss of capacity. For a better understanding of vanadium transport in membranes, the uptake of vanadium ions from electrolytes containing Vdimer(IV–V) and for comparison also V(II), V(III), V(IV), and V(V) by both membranes was studied. UV/VIS spectroscopy, X-ray absorption near edge structure spectroscopy (XANES), total reflection X-ray fluorescence spectroscopy (TXRF), inductively coupled plasma optical emission spectrometry (ICP-OES), and micro X-ray fluorescence spectroscopy (microXRF) were used to determine the vanadium concentrations and the species inside the membrane. The results strongly support that Vdimer(IV–V), a dimer formed from V(IV) and V(V), enters the nanoscopic water-body of Nafion™ 117 as such. This is interesting, because as of now, only the individual ions V(IV) and V(V) were considered to be transported through the membrane. Additionally, it was found that the Vdimer(IV–V) dimer partly dissociates to the individual ions in the novel PVDF-based membrane. The Vdimer(IV–V) dimer concentration in Nafion™ was determined and compared to those of the other species. After three days of equilibration time, the concentration of the dimer is the lowest compared to the monomeric vanadium species. The concentration of vanadium in terms of the relative uptake λ = n(V)/n(SO3) are as follows: V(II) [λ = 0.155] > V(III) [λ = 0.137] > V(IV) [λ = 0.124] > V(V) [λ = 0.053] > Vdimer(IV–V) [λ = 0.039]. The results show that the Vdimer(IV–V) dimer needs to be considered in addition to the other monomeric species to properly describe the transport of vanadium through Nafion™ in VRFBs.
Highlights
Renewable energy sources like wind, water, and solar power are sustainable alternatives to fossil fuels and nuclear energy
The results show that the Vdimer(IV–V) dimer needs to be considered in addition to the other monomeric species to properly describe the transport of vanadium through NafionTM in vanadium redox flow batteries (VRFB)
We have shown that single vanadium species inside the membrane can be determined by UV/VIS and the spectra are similar to those of the corresponding vanadium electrolyte
Summary
Renewable energy sources like wind, water, and solar power are sustainable alternatives to fossil fuels and nuclear energy. Oh et al modeled the vanadium transport through NafionTM based on the Nernst-Planck-equation with negligible convection [17] All in all, this indicates that vanadium crossover is not well understood and that the lack of knowledge is of a fundamental nature. For a better understanding of the vanadium crossover, it is necessary to determine vanadium concentrations and species in VRFB cell components, ideally in situ. UV/VIS spectroscopy is often applied to study the vanadium species of the electrolyte in situ. A procedure to determine the vanadium species inside the membranes by UV/VIS and XANES was established as well as a new procedure to extract vanadium from NafionTM and other ionomeric membranes. The extraction efficiency was validated by using micro X-ray fluorescence spectroscopy (microXRF)
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