Enhanced Performance of Bimetallic Co-Pd Catalysts Prepared by Mechanical Alloying

Bimetallic catalysts can provide enhanced performance, and Co-based catalysts in particular have been studied in various respects for their activity in the deposition of carbon nanofibers (CNFs). The majority of studies on CNF catalysis use co-precipitation to create alloys, but recent work has demo...

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Bibliographic Details
Published in:Metals (Basel ) 2019-03, Vol.9 (3), p.335
Main Authors: Knauss, Steven, Guevara, Laura, Atwater, Mark
Format: Article
Language:English
Subjects:
Alloys
Annealing
Ball milling
bimetallic composite
Bimetals
Carbon fibers
carbon nanofiber
Catalysis
Catalysts
Catalytic activity
Cobalt
Deposition
ethylene
Mechanical alloying
Microstructure
Nanofibers
Palladium
Performance enhancement
Stainless steel
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Summary:Bimetallic catalysts can provide enhanced performance, and Co-based catalysts in particular have been studied in various respects for their activity in the deposition of carbon nanofibers (CNFs). The majority of studies on CNF catalysis use co-precipitation to create alloys, but recent work has demonstrated the suitability of mechanical alloying (MA) by ball milling to reduce cost and increase catalytic activity. This work establishes the unique ability of MA to control the microstructure to produce bimetallic composites, which retain distinct metallic phases that improve catalytic activity. It is demonstrated that Co-Pd alloys reach a maximum in catalytic activity at an intermediate time of mechanical activation, where 30 min of milling outperformed samples milled for 5, 15, 60, and 240 min at a reaction temperature of 550 °C and a 1:4 C2H4:H2 reactant ratio. This indicates there is benefit to retaining the metals in distinct phases in close proximity. Ball milling provides a relatively simple and scalable method to achieve these unique microstructures, and in the optimal condition tested here, the activity toward carbon deposition is increased fourfold over prior work. Furthermore, the minimum temperature for deposition is also reduced. The characteristics of these materials, the effects of milling and annealing, and the underlying mechanisms of deposition are discussed.
ISSN:2075-4701
2075-4701
DOI:10.3390/met9030335