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Advisor(s)
Abstract(s)
The growth mechanism of nanostructured cobalt foams prepared by hydrogen bubble template electrodeposition has been studied. To that end, cobalt foams have been synthesized under different electrodeposition times and studied with various characterization techniques, namely scanning electron microscopy (SEM) and confocal microscopy in reflection mode. In addition, the mechanical properties of the resulting foams have been tested by bending and tensile tests. To study the influence of chemical additives in the growth mechanism and final properties of the foams, agar-agar has been added to the electrolytic bath during foam preparation. Results evidence that the addition of agar has successfully modified the microstructure of the final foams, creating a denser porous structure with smaller pore area and reduced growth rate that translates into better mechanical properties. By studying the evolution of the microstructure under different deposition conditions, a growth model of cobalt metallic foams by dynamic hydrogen bubble template is proposed. This easy and scalable route paves the way to produce tailored foams for numerous applications that include, for instance, energy storage and energy conversion.
Description
Keywords
Cobalt metal foams Growth mechanism Hydrogen bubble template electrodeposition Agar-agar Mechanical properties
Citation
AREVALO-CID, P.; [et al] – On the growth and mechanical properties of nanostructured cobalt foams by dynamic hydrogen bubble template electrodeposition. Materials Characterization. ISSN 1044-5803. Vol. 169 (2020), pp. 1-10
Publisher
Elsevier