Synthesis of metal alloy catalysts using high-throughput experiments and machine learning optimization
The periodic table comprises over a hundred elements, offering numerous possibilities for the discovery of novel materials that have superior properties and could therefore be used to address current technological and societal challenges. However, exploring the extensive range of combinations are...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
Nanyang Technological University
2023
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| Online Access: | https://hdl.handle.net/10356/172270 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | The periodic table comprises over a hundred elements, offering numerous possibilities
for the discovery of novel materials that have superior properties and could therefore
be used to address current technological and societal challenges. However, exploring
the extensive range of combinations are resource-intensive: slow and costly,
particularly for materials significantly affected by the synthesis procedures. In this
final year project, a workflow for the high throughput synthesis of multimetallic alloys
is presented. The two-step workflow is comprised by a liquid mixing step and an
annealing step. An acceleration factor of 2.4 relative to the traditional auto combustion
sol gel synthesis method is achieved by synthesizing 24 samples in 620 minutes. To
evaluate the effectiveness of this methodology and with the assistance of previous
computational work carried out by collaborators at Meta AI, copper and three other
copper alloys, namely binary Cu-Ag, Cu-Zn, and ternary Cu-Zn-Ag, are synthesized,
due to their predicted promising use in CO2 reduction. The synthesized samples show
homogeneously distributed elemental composition and high phase purity. The catalytic
performance is evaluated by collaborators at the University of Toronto. The initial
findings from measuring pure Cu, which serves as a baseline, demonstrate consistent
performance when compared to commercially available Cu nanoparticles. Crucially,
the Faradaic efficiencies show different results compared to Cu nanoparticles. Firstly,
a substantial amount of H2 gas is produced, accompanied by low CO. This is due to
the large amount of carbon in our powders, stemming from the annealing step, and
large particle size of the pure Cu. To guide future experiments and optimize the
Faradaic efficiencies, the experimental data collected in this project is used to deploy
a Bayesian Optimization (BO) algorithm. Specifically, q-Noisy Expected
Hypervolume Improvement based Bayesian Optimization (qNEHVI-BO) model is
implemented, providing insight to guide the next experimental steps to achieve dry
samples and minimize the absolute difference between the obtained composition and
the target. |
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