MEA and GDE manufacture for electrolytic membrane characterisation / Henry Howell Hoek

Hoek, Henry Howell

January 2013

In recent years an emphasis has been placed on the development of alternative and clean energy sources to reduce the global use of fossil fuels. One of these alternatives entails the use of H2 as an energy carrier, which can be obtained amongst others using thermochemical processes, for example the hybrid sulphur process (HyS). The HyS process is based on the thermal decomposition of sulphuric acid into water, sulphur dioxide and oxygen. The subsequent chemical conversion of the sulphur dioxide saturated water back to sulphuric acid and hydrogen is achieved in an electrolyser using a platinum coated proton exchange membrane. This depolarised electrolysis requires a theoretical voltage of only 0.158 V compared to water electrolysis requiring approximately 1.23 V. One of the steps in the development of this technology at the North-West University, entailed the establishment of the platinum coating technology which entailed two steps; firstly using newly obtained equipment to manufacture the membrane electro catalyst assemblies (MEA’s) and gas diffusion electrodes (GDE’s) and secondly to test these MEA’s and GDE’s using sulphur dioxide depolarized electrolysis by comparing the manufactured MEA’s and GDE’s to commercially available MEA’s and GDE’s. Different MEA’s and GDE’s were manufactured using both a screen printing (for the microporous layer deposition) and a spraying technique. The catalyst loadings were varied as well as the type and thickness of the proton exchange membranes used. The proton exchange membranes that were included in this study were Nafion 117®, sPSU-PBIOO and SfS-PBIOO membranes whereas the gas diffusion layer consisted of carbon paper with varying thicknesses (EC-TP01-030 – 0.11 mm and EC-TP01-060 – 0.19mm). MEA and GDE were prepared by first preparing an ink that was used both for MEA and GDE spraying. The MEA’s were prepared by spraying various catalyst coatings onto the proton exchange membranes containing 0.3, 0.6 and 0.9 mg/cm2 platinum respectively. The GDE’s were first coated by a micro porous carbon layer using the screen printing technique in order to attain a suitable surface for catalyst deposition. Using the spraying technique GDE’s containing 0.3, 0.6, 0.9 mg/cm2 platinum were prepared. After SEM analysis, the MEA’s and GDE’s performance was measured using SO2 depolarized electrolysis. From the electrolysis experiments, the voltage vs. current density generated during operation, the hydrogen production, the sulphuric acid generation and the hydrogen production efficiency was obtained. From the results it became clear that while the catalyst loading had little effect on performance there were a number of factors that did have a significant influence. These included the type of proton exchange membrane, the membrane thickness and whether the catalyst coating was applied to the proton exchange membrane (MEA) or to the gas diffusion layer (GDE). During SO2 depolarized electrolysis VI curves were generated which gave an indication of the performance of the GDE’s and MEA’s. The best preforming GDE was GDE-3 (0.46V @ 320 mA/cm2), which included a GDE EC-TP01-060, while the best preforming MEA’s were NAF-4 (0.69V @ 320mA/cm2) consisting of a Nafion117 based MEA and PBI-1 (0.43V @ 320mA/cm2) made from a sPSU-PBIOO blended membrane. During hydrogen production it became clear that the GDE’s produced the most hydrogen (best was GDE-02 a in house manufactured GDE yielding 67.3 mL/min @ 0.8V), followed by the Nafion® MEA’s (best was NAF-4 a commercial MEA yielding 57.61 mL/min @ 0.74V) and the PBI based MEA’s. , (best was PBI-2 with 67.11 mL/min @ 0.88V). Due to the small amounts of acid produced and the SO2 crossover, a significant error margin was observed when measuring the amount of sulphuric acid produced. Nonetheless, a direct correlation could still be seen between the acid and the hydrogen production as had been expected from literature. The highest sulphuric acid concentrations produced using the tested GDE’s and MEA’s from this study were the in-house manufactured GDE-01 (3.572mol/L @ 0.8V), the commercial NAF-4 (4.456mol/L @ 0.64V) and the in-house manufactured PBI-2 (3.344mol/L @ 0.8V). The overall efficiency of the GDE’s were similar, ranging from less than 10% at low voltages (± 0.6V) increasing to approximately 60% at ± 0.8V. For the MEA’s larger variation was observed with NAF-4 reaching efficiencies of nearly 80% at 0.7V. In terms of consistency of performance it was shown that the Nafion MEA’s preformed most consistently followed by the GDE’s and lastly the PBI based MEA’s which for the PBI based membranes can probably be ascribed to the significant difference in thickness of the thin PBI vs. the Nafion based membranes. In summary the study has shown the results between the commercially obtained and the in-house manufactured GDE’s and MEA’s were comparable confirming the suitability of the coating techniques evaluated in this study. / MSc (Chemistry), North-West University, Potchefstroom Campus, 2014

Gas diffusion electrodes (GDE)

Catalyst loadings

Proton exchange membrane

SO2 depolarized electrolysis

MEA and GDE manufacture for electrolytic membrane characterisation / Henry Howell Hoek

Hoek, Henry Howell

January 2013

In recent years an emphasis has been placed on the development of alternative and clean energy sources to reduce the global use of fossil fuels. One of these alternatives entails the use of H2 as an energy carrier, which can be obtained amongst others using thermochemical processes, for example the hybrid sulphur process (HyS). The HyS process is based on the thermal decomposition of sulphuric acid into water, sulphur dioxide and oxygen. The subsequent chemical conversion of the sulphur dioxide saturated water back to sulphuric acid and hydrogen is achieved in an electrolyser using a platinum coated proton exchange membrane. This depolarised electrolysis requires a theoretical voltage of only 0.158 V compared to water electrolysis requiring approximately 1.23 V. One of the steps in the development of this technology at the North-West University, entailed the establishment of the platinum coating technology which entailed two steps; firstly using newly obtained equipment to manufacture the membrane electro catalyst assemblies (MEA’s) and gas diffusion electrodes (GDE’s) and secondly to test these MEA’s and GDE’s using sulphur dioxide depolarized electrolysis by comparing the manufactured MEA’s and GDE’s to commercially available MEA’s and GDE’s. Different MEA’s and GDE’s were manufactured using both a screen printing (for the microporous layer deposition) and a spraying technique. The catalyst loadings were varied as well as the type and thickness of the proton exchange membranes used. The proton exchange membranes that were included in this study were Nafion 117®, sPSU-PBIOO and SfS-PBIOO membranes whereas the gas diffusion layer consisted of carbon paper with varying thicknesses (EC-TP01-030 – 0.11 mm and EC-TP01-060 – 0.19mm). MEA and GDE were prepared by first preparing an ink that was used both for MEA and GDE spraying. The MEA’s were prepared by spraying various catalyst coatings onto the proton exchange membranes containing 0.3, 0.6 and 0.9 mg/cm2 platinum respectively. The GDE’s were first coated by a micro porous carbon layer using the screen printing technique in order to attain a suitable surface for catalyst deposition. Using the spraying technique GDE’s containing 0.3, 0.6, 0.9 mg/cm2 platinum were prepared. After SEM analysis, the MEA’s and GDE’s performance was measured using SO2 depolarized electrolysis. From the electrolysis experiments, the voltage vs. current density generated during operation, the hydrogen production, the sulphuric acid generation and the hydrogen production efficiency was obtained. From the results it became clear that while the catalyst loading had little effect on performance there were a number of factors that did have a significant influence. These included the type of proton exchange membrane, the membrane thickness and whether the catalyst coating was applied to the proton exchange membrane (MEA) or to the gas diffusion layer (GDE). During SO2 depolarized electrolysis VI curves were generated which gave an indication of the performance of the GDE’s and MEA’s. The best preforming GDE was GDE-3 (0.46V @ 320 mA/cm2), which included a GDE EC-TP01-060, while the best preforming MEA’s were NAF-4 (0.69V @ 320mA/cm2) consisting of a Nafion117 based MEA and PBI-1 (0.43V @ 320mA/cm2) made from a sPSU-PBIOO blended membrane. During hydrogen production it became clear that the GDE’s produced the most hydrogen (best was GDE-02 a in house manufactured GDE yielding 67.3 mL/min @ 0.8V), followed by the Nafion® MEA’s (best was NAF-4 a commercial MEA yielding 57.61 mL/min @ 0.74V) and the PBI based MEA’s. , (best was PBI-2 with 67.11 mL/min @ 0.88V). Due to the small amounts of acid produced and the SO2 crossover, a significant error margin was observed when measuring the amount of sulphuric acid produced. Nonetheless, a direct correlation could still be seen between the acid and the hydrogen production as had been expected from literature. The highest sulphuric acid concentrations produced using the tested GDE’s and MEA’s from this study were the in-house manufactured GDE-01 (3.572mol/L @ 0.8V), the commercial NAF-4 (4.456mol/L @ 0.64V) and the in-house manufactured PBI-2 (3.344mol/L @ 0.8V). The overall efficiency of the GDE’s were similar, ranging from less than 10% at low voltages (± 0.6V) increasing to approximately 60% at ± 0.8V. For the MEA’s larger variation was observed with NAF-4 reaching efficiencies of nearly 80% at 0.7V. In terms of consistency of performance it was shown that the Nafion MEA’s preformed most consistently followed by the GDE’s and lastly the PBI based MEA’s which for the PBI based membranes can probably be ascribed to the significant difference in thickness of the thin PBI vs. the Nafion based membranes. In summary the study has shown the results between the commercially obtained and the in-house manufactured GDE’s and MEA’s were comparable confirming the suitability of the coating techniques evaluated in this study. / MSc (Chemistry), North-West University, Potchefstroom Campus, 2014

Gas diffusion electrodes (GDE)

Catalyst loadings

Proton exchange membrane

SO2 depolarized electrolysis

Influence of Molecular Weight and Architecture on Polymer Dynamics

Ding, Yifu

13 May 2005

No description available.

Polymer Dynamics

Glass Transition

Fast dynamics

Fragility

Molecular Weight Effect

Depolarized Light Scattering

Développement d’un réacteur électro-membranaire utilisant l'électrolyse pour la production d'hydroxyde de lithium

Faral, Manon

04 1900

Au cours des dernières années, le développement des batteries Li-ion a révolutionné nos modes de vie. Compte tenu de la croissance exponentielle en batteries, le besoin se répercute sur les matériaux de base, qui sont entre autres, synthétisés à partir de sels de lithium de haute pureté. Nemaska Lithium, une entreprise partenaire du projet, est reconnue en tant que nouveau producteur d’hydroxyde de lithium, par l’entremise d’un procédé électromembranaire breveté. Comparativement au procédé conventionnel, la solution mise en place est l’une des méthodes la plus économique et écologique à l’échelle mondiale. Dans le but de diminuer encore plus les coûts énergétiques du procédé, l’usage d’une anode dépolarisée à l’hydrogène ((ADH); H2(g) ⇄ 2H+(aq) +2é; E=0,00 V) est considérée. Cette approche demande une certaine compréhension et optimisation de l’électrode à des fins d’adaptation pour l’électrolyse. Ainsi, ce travail tant fondamental qu’appliqué a été réalisé afin d’étudier les phénomènes se produisant à l’ADH. Dans un premier temps, une étude portée sur la cinétique de réaction de l’oxydation de l’hydrogène à l’aide d’une électrode à disque tournant est réalisée. L’influence d’ions lithium et d’une couche catalytique composite sur l’efficacité de la réaction a ainsi pu être démontrée. L’identification des limitations du système a ensuite permis l’optimisation de l’ADH à l’aide d’un plan d’expérience. L’ADH est composée d’un ionomère, d’un catalyseur et d’un support à catalyseur, qui ont des propriétés intrinsèques ayant un impact direct sur l’efficacité et la durabilité de celle-ci. Conséquemment, pour une étude de performance et d’optimisation, plusieurs configurations d’assemblage d’électrode à membrane (MEA) ont été considérées visant à faire varier les proportions des différentes composantes avec un plan d’expérience. Ce projet a ainsi permis l’étude menant à une meilleure compréhension d’une nouvelle technologie d’électrolyse membranaire. / In recent years, the development of Li-ion batteries has revolutionized our lifestyles. Given the exponential demand for batteries, the requirement is for base materials, which are synthesized from high-purity lithium salts. Nemaska Lithium, a partner in the project, is recognized as a new producer of lithium hydroxide, using a patented electromembrane process. Compared to the conventional process, this solution is one of the most economical and environmentally friendly methods worldwide. In order to further reduce the energy costs of the process, the use of a hydrogen depolarized anode ((HDA); H2(g) ⇄ 2H+(aq) +2é; E0=0,00 V) is considered. This approach requires some understanding and optimization of the electrode for electrolysis adaptations. Thus, this fundamental and applied work was conducted to study the phenomena occurring at the HDA. First, a study on the kinetics of the hydrogen oxidation reaction using a rotating disk electrode is performed. The influence of lithium ions and a composite catalytic layer on the efficiency of the reaction was demonstrated. The identification of system limitations allowed the optimization of the DHA using a design of experiment. The components of a HDA have intrinsic properties which have a direct impact on its efficiency and durability. They consist of an ionomer, a catalyst, and a catalyst support. Consequently, for a performance and optimization study, several membrane electrode assembly (MEA) configurations were considered in order to vary the proportions of the different components with a design of experiment. This study provided a better understanding and development of this new membrane electrolysis technology.

Nafion

Batterie Li-ion

Électrolyse membranaire

Anode dépolarisée à l’hydrogène

Platine

Cinétique de réaction électrochimique

Plan d’expérience

Optimisation

Li-ion battery

Membrane electrolysis

Hydrogen depolarized anode

Hydrogen oxidation reaction

Platinum

Electrochemical reaction kinetics

Optimization

Design of experiment