Alloying of ALD metals
As high entropy alloys (HEAs) continue to gain interest in many applications of today’s world, methods to produce this material of superior properties such as arc melting and powder metallurgy involves harsh conditions that will damage and influence properties of the HEAs. In addition to this,...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
Nanyang Technological University
2022
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| Online Access: | https://hdl.handle.net/10356/157238 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | As high entropy alloys (HEAs) continue to gain interest in many applications of today’s world,
methods to produce this material of superior properties such as arc melting and powder
metallurgy involves harsh conditions that will damage and influence properties of the HEAs.
In addition to this, traditional methods used are mostly used to produce HEAs in bulk form.
This study aims to address the shortcomings of conventional methods and develop a two-step
approach to produce HEA thin films which is believed to be less invasive and more sustainable
as compared to conventional methods. This approach consists of deposition of five noble
metals by ALD, followed by joule heating to alloy the metal atoms deposited. The experimental
part of this study begins with single metal deposition of the noble metals on individual
substrates which will lay the foundation for five-layer metal films to be fabricated thereafter.
The deposition of the single noble metals was conducted with higher number of cycles,
achieving thicker metal layers. Characterization techniques were used to determine the
morphology, crystal structure and composition of the samples. The successful deposition of the
individual metal samples led to the deposition of the five-layer films which is essentially the
combination of the individual processes performed separately onto a single substrate. XRD and
EDX data of the five-layer films proved successful deposition of all five noble metals.
Thereafter, the films were joule heated in which new bonds were formed, as the shift in
characterization peaks were observed in the XRD pattern. Surface morphology of the HEAs
and five-layer films before joule heating were noticed to be vastly different as compared to the
samples with single metal deposited.
Successful fabrication of HEAs implies versality of this two-step approach to the fabrication
of HEAs involving other materials as well as HEAs with better properties and surface coverage
during applications. However, more research has to be done to investigate the properties of the
HEAs fabricated. |
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