Novel Nafion nanocomposite membranes embedded with TiO2-decorated MWCNTs for high-temperature/low relative humidity fuel cell systems

IF 3.6 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

Materials for Renewable and Sustainable Energy Pub Date : 2024-06-06 DOI:10.1007/s40243-024-00266-7

Isabella Nicotera, Luigi Coppola, Cataldo Simari

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Abstract

Extending the operation of proton exchange membrane fuel cells (PEMFCs) at high temperature (i.e., 120 °C) and/or low relative humidity (< 50% RH) remains a significant challenge due to dehydration and subsequent performance failure of the Nafion electrolyte. We approached this problem by integrating the Nafion matrix with a novel hybrid nanofiller, created through direct growth of TiO₂ nanoparticles on the surface of carbon nanotubes. This synthetic approach allowed to preserve an effective nanodispersion of Titania particles in the hosting matrix, thereby boosting dimensional stability, hydrophilicity, and physiochemical properties of the Nafion/MWCNTs-TiO₂ (NMT-x) nanocomposites compared to parental Nafion. At optimal concentration (i.e., 3 wt% with respect to the polymer), the nanocomposite membrane exhibited high transport characteristics with impressive water retention capabilities, resulting in a proton conductivity of 8.3 mS cm^− 1 at 80 °C and 20% RH. The Titania nanoparticles plays a key role in retaining water molecules even under dehydrating conditions, while also directly contributing to proton transport. Additionally, the long carbon nanotubes promote the formation of additional paths for proton conductivity. These combined features enabled the NMT-3 membrane to achieve a maximum power output of 307.7 mW/cm² in a single H₂/air fuel cell (5 cm² active electrode area and 0.5 mg Pt/cm² at both electrodes) under very challenging conditions, specifically at 120 °C and 30% RH. This represents a significant advancement towards overcoming the limitations of traditional Nafion membranes and opens up new possibilities for high-temperature, low-humidity H₂/air fuel cell applications.

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用于高温/低相对湿度燃料电池系统的嵌入了 TiO2 装饰的 MWCNT 的新型 Nafion 纳米复合膜

由于 Nafion 电解质的脱水和随之而来的性能故障，在高温（即 120 °C）和/或低相对湿度（50% RH）条件下延长质子交换膜燃料电池（PEMFC）的运行时间仍然是一项重大挑战。我们通过在碳纳米管表面直接生长 TiO2 纳米粒子，将 Nafion 基体与新型混合纳米填料结合起来，从而解决了这一问题。这种合成方法可以在寄主基质中保持钛粒子的有效纳米分散，从而与母体 Nafion 相比，提高了 Nafion/MWCNTs-TiO2 (NMT-x) 纳米复合材料的尺寸稳定性、亲水性和理化特性。在最佳浓度下（即相对于聚合物为 3 wt%），纳米复合膜表现出高传输特性和令人印象深刻的保水能力，在 80 °C 和 20% 相对湿度条件下，质子电导率为 8.3 mS cm-1。即使在脱水条件下，钛纳米颗粒也能在保留水分子方面发挥关键作用，同时还能直接促进质子传输。此外，长碳纳米管还促进了质子传输路径的形成。这些综合特性使 NMT-3 膜能够在极具挑战性的条件下，特别是在 120 °C 和 30% 相对湿度条件下，在单个 H2/air 燃料电池中实现 307.7 mW/cm2 的最大功率输出（活性电极面积为 5 cm2，两个电极的 Pt/cm2 均为 0.5 mg）。这表明在克服传统 Nafion 膜的局限性方面取得了重大进展，并为高温、低湿度 H2/air 燃料电池的应用开辟了新的可能性。

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来源期刊

Materials for Renewable and Sustainable Energy MATERIALS SCIENCE, MULTIDISCIPLINARY-

CiteScore

7.90

自引率

2.20%

发文量

审稿时长

13 weeks

期刊介绍： Energy is the single most valuable resource for human activity and the basis for all human progress. Materials play a key role in enabling technologies that can offer promising solutions to achieve renewable and sustainable energy pathways for the future. Materials for Renewable and Sustainable Energy has been established to be the world''s foremost interdisciplinary forum for publication of research on all aspects of the study of materials for the deployment of renewable and sustainable energy technologies. The journal covers experimental and theoretical aspects of materials and prototype devices for sustainable energy conversion, storage, and saving, together with materials needed for renewable fuel production. It publishes reviews, original research articles, rapid communications, and perspectives. All manuscripts are peer-reviewed for scientific quality. Topics include: 1. MATERIALS for renewable energy storage and conversion: Batteries, Supercapacitors, Fuel cells, Hydrogen storage, and Photovoltaics and solar cells. 2. MATERIALS for renewable and sustainable fuel production: Hydrogen production and fuel generation from renewables (catalysis), Solar-driven reactions to hydrogen and fuels from renewables (photocatalysis), Biofuels, and Carbon dioxide sequestration and conversion. 3. MATERIALS for energy saving: Thermoelectrics, Novel illumination sources for efficient lighting, and Energy saving in buildings. 4. MATERIALS modeling and theoretical aspects. 5. Advanced characterization techniques of MATERIALS Materials for Renewable and Sustainable Energy is committed to upholding the integrity of the scientific record. As a member of the Committee on Publication Ethics (COPE) the journal will follow the COPE guidelines on how to deal with potential acts of misconduct. Authors should refrain from misrepresenting research results which could damage the trust in the journal and ultimately the entire scientific endeavor. Maintaining integrity of the research and its presentation can be achieved by following the rules of good scientific practice as detailed here: https://www.springer.com/us/editorial-policies