Direct methanol fuel cells are feasible devices for efficient electrochemical power generation if some issues can be solved regarding both electrodes and membranes. The research carried out in this Ph.D. thesis has particularly focused on the concerns associated with the membranes. Nafion ® is the most standard fuel cell membrane material due to its high proton conductivity and exceptional chemical and mechanical stability. However, it suffers from a considerably high methanol permeability and a limited operating temperature (< 80 ºC). The first aspect was addressed with the use of PVA nanofibres and the second one replacing Nafion ® with SPEEK-based polymers. Composite membranes of Nafion ® with PVA nanofibres, surface functionalised with sulfonic acid groups, exhibited lower methanol permeabilities due to the intrinsic barrier property of PVA, although proton conductivity was also affected as a result of the non-conducting behaviour of the bulk PVA phase. Remarkably, the nanofibres provided strong mechanical reinforcement which enabled the preparation of low thickness membranes (< 20 μm) with reduced ohmic losses, thus counteracting their lower proton conductivities. SPEEK-based membranes were examined for DMFC operation within the intermediate temperature range of 80-140 ºC, in which sluggish electrochemical reactions at the electrodes are accelerated and proton conductivity activated. SPEEK was blended and crosslinked with PVA and PVB polymers for avoiding its dissolution in hot water conditions. SPEEK-PVA compositions showed practical proton conductivities and SPEEK-PVB blends presented very low methanol permeabilities. Nanocomposite membranes composed of SPEEK-30%PVB nanofibres embedded in a SPEEK-35%PVA matrix were prepared and characterised. A nanocomposite membrane crosslinked at 120 ºC revealed promising results for DMFCs operating at intermediate temperatures. Electrospinning is concluded to be a suitable technique for obtaining polymer nanofibre mats intended for advanced composite membranes with improved characteristics and fuel cell performances. Prof. Dr. Vicente Compañ for affording me the opportunity to work with him and complete this Ph.D. thesis. His guidance and support have been invaluable as well as our exciting scientific discussions. My deepest sincere gratitude also goes to Prof.
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