Research on Iron-Lead Semi-Flow Battery Based on 3D Solid Electrode

Zhang, Zhuhan; Jiang, Fengjing; Wu, Keke; Shen, Ping

doi:10.6023/a21090440

Cited by 5 publications

(2 citation statements)

References 25 publications

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“…It can be seen that the self-discharge times of H3020 and H3520 are 208.7 and 180.8 h, respectively, significantly higher than N115 membranes (141.2 h). This indicates the excellent ability of the porous membrane to prevent iron ion migration [25] . It is noteworthy that the cell with the N115 membrane exhibited bigger fluctuations in VE and EE [Figure 9B and C] than the PVDF-HFP porous membranes during the cycling measurement.…”

Section: Single-cell Performancementioning

confidence: 84%

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Tailoring porous structure in non-ionic polymer membranes using multiple templates for low-cost iron-lead single-flow batteries

Zhang,

Lejarazu-Larrañaga,

Yang

et al. 2024

Energy Mater

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Porous ion-selective membranes are promising alternatives for the expensive perfluorosulfonic acid membranes in redox flow batteries. In this work, novel non-ionic porous polyvinylidene fluoride-hexafluoro propylene membranes are designed for iron-lead single-flow batteries. The membranes are prepared using a multiple template approach, involving simultaneously using polyethylene glycol and dibutyl phthalate (DBP) as pore-forming templates. Their porous structure is finely tuned by adjusting the ratio of the two templates. As a result, dual-porous membranes bearing both macro and micropores are obtained. The H3520 membrane with modified porous structure attains a high proton conductivity of 43.5 mS·cm-1 and a relatively low ferric ion diffusion constant (8.61 × 10-8 cm2·min-1) and demonstrates the best balance between these performance-determining parameters (selectivity 5.04 × 105 S·min·cm-3, higher than that of the N115 membrane). Besides, performance tests of the iron-lead single-flow single cells equipped with the dual-porous membranes show a high energy efficiency, exceeding 87.2% at its rated current density, and outstanding cycling stability over 200 charge-discharge cycles. Altogether, the mixed template method presents a promising strategy to prepare high-performance and low-cost non-ionic membranes for redox flow batteries.

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Section: Single-cell Performancementioning

confidence: 84%

“…The evolution of ferric ion concentration in chamber B was measured by an ultraviolet-visible (UV-vis) spectrometer at 420 nm. The ferric ion diffusion constant (D diffusion const ) was calculated using Fick's law, denoted as [24,25] :…”

Section: Ferric Ion Permeability and Ion Selectivity Measurementsmentioning

confidence: 99%