Machining of 2D materials by ultrasonic embossing
The discovery of two-dimensional (2D) materials (E.g., Graphene, Phosphorene and Xenes) in 2004 highlighted the in-plane interatomic interactions displayed in the crystalline materials to be much stronger compared to those along the stacking direction. 2D materials like Graphene exhibit except...
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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/10356/164135 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | The discovery of two-dimensional (2D) materials (E.g., Graphene, Phosphorene and Xenes) in
2004 highlighted the in-plane interatomic interactions displayed in the crystalline materials to
be much stronger compared to those along the stacking direction. 2D materials like Graphene
exhibit exceptional and extraordinary properties which have attracted worldwide attention. It
is internally composed of hexagonally arranged sp2 hybridized atoms that exhibit extraordinary
strength, extremely high thermal conductivity and excellent optical properties making it the
most prosperous development among many researchers.
Herein, the author explores a series of ultrasonic embossing methods capable of imprinting
graphene nanostructure on copper and silver substrates. Exfoliating process with two different
tapes is used to extract graphene layers from graphite crystals and transfer it onto substrates
together with Anodized Aluminum Oxide (AAO). Variations of that process were being
experimented to obtain an optimal result. Different embossing parameters were simulated to
obtain a high yield of graphene nanoparticles.
The results show that exfoliating graphene layers with suitable tapes produce the highest
coverage of graphene on the substate and the various factors for ultrasonic embossing
(Pressure, Welding Time, Amplitude & Holding Times) contributes significantly to replication
depth. The optimized ultrasonic parameters to imprint an array of graphene nanowires is
determined, after numerous experiments, to be welding force of 1400N, welding time of 30 s,
amplitude of 25% and holding force of 1500N time of 10 s.
Hence, the results proved that ultrasonic embossing is effective in shrinking 2D materials to
nanoscale for future applications. |
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