The hydrogen economy relies on effective and environmentally friendly processes for energy conversion and storage. To this end, hydrogen is progressively holding the role of preferred energy vector. Within this frame, electrochemical science and technology is actively contributing in developing advanced fuel cells and water electrolyzers to be integrated in (i) energy parks to decouple production and consumption; (ii) exploit renewable sources; (iii) favour the progressive reduction of fossil fuels and reduce the greenhouse effect via decarbonization. The exploitation of the relevant processes and devices call for the sound control over the environmental impact from production to end-of-life steps. Here, life-cycle analyses were performed and discussed focusing on both acid and alkaline fuel cells, i.e., proton exchange membrane fuel cells (PEMFC) and anionexchange membrane fuel cells (AEMFC), and assessing their contribution to key environmental impact categories such as, for example, global warming and ozone layer depletion. Within these premises, the study points to the benefits of replacing platinum by low load Pd/CeO2 bifunctional electrocatalyst on electrochemical hydrogen production and usage.

AEMFC exploiting a Pd/CeO2-based anode compared to Classic PEMFC via LCA analysis / S. Minelli, M. Civelli, S. Rondinini, A. Minguzzi, A. Vertova. - In: HYDROGEN. - ISSN 2673-4141. - 2:3(2021 Jun 23), pp. 246-261. [10.3390/hydrogen2030013]

AEMFC exploiting a Pd/CeO2-based anode compared to Classic PEMFC via LCA analysis

S. Minelli
Primo
;
S. Rondinini
;
A. Minguzzi
Penultimo
;
A. Vertova
Ultimo
2021

Abstract

The hydrogen economy relies on effective and environmentally friendly processes for energy conversion and storage. To this end, hydrogen is progressively holding the role of preferred energy vector. Within this frame, electrochemical science and technology is actively contributing in developing advanced fuel cells and water electrolyzers to be integrated in (i) energy parks to decouple production and consumption; (ii) exploit renewable sources; (iii) favour the progressive reduction of fossil fuels and reduce the greenhouse effect via decarbonization. The exploitation of the relevant processes and devices call for the sound control over the environmental impact from production to end-of-life steps. Here, life-cycle analyses were performed and discussed focusing on both acid and alkaline fuel cells, i.e., proton exchange membrane fuel cells (PEMFC) and anionexchange membrane fuel cells (AEMFC), and assessing their contribution to key environmental impact categories such as, for example, global warming and ozone layer depletion. Within these premises, the study points to the benefits of replacing platinum by low load Pd/CeO2 bifunctional electrocatalyst on electrochemical hydrogen production and usage.
anion-exchange membrane; cation-exchange membrane; Pd@CeO2/C; bifunctional electrocatalyst; environmental impact; life cycle assessment
Settore CHIM/02 - Chimica Fisica
   Novel Multilayered and Micro.Machined Electrode nano-Architectures for Electrocatalytic Applica-tions (Fuel cells and Electrolyzers)
   Fuel cells and Electrolyzers
   MINISTERO DELL'ISTRUZIONE E DEL MERITO
   2017YH9MRK_004
23-giu-2021
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2434/857428
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