Strained graphene optoelectronic devices with unprecedented pseudo-magnetic fields
Photonic-integrated circuit (PIC) is a research field that has been attracting many researchers’ interests owing to its great potential for enabling various disruptive technologies. In the past few decades, silicon-based PIC has been at the core of PIC development due to the maturity of industry-ado...
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Nanyang Technological University
2022
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sg-ntu-dr.10356-1625422022-10-28T07:30:02Z Strained graphene optoelectronic devices with unprecedented pseudo-magnetic fields Wang, Boyan Nam Donguk Teo Hang Tong Edwin School of Materials Science and Engineering HTTEO@ntu.edu.sg, dnam@ntu.edu.sg Engineering::Materials Photonic-integrated circuit (PIC) is a research field that has been attracting many researchers’ interests owing to its great potential for enabling various disruptive technologies. In the past few decades, silicon-based PIC has been at the core of PIC development due to the maturity of industry-adopted silicon processing technologies. Since the first discovery of graphene in 2004, graphene-based PIC has been considered one of the strongest candidates to further improve the performance of silicon-based PIC for various reasons. For example, graphene has higher carrier mobility than silicon, which can allow making high-speed electronic devices. This property also enables producing very high-speed photodetectors. However, due to the zero-bandgap nature of graphene, it remains challenging to create a graphene-based light source, making the bandgap opening an important milestone for developing efficient graphene-based light sources. Recently, there have been several reports that theoretically predict the possibility of opening the energy gaps in graphene by using strain- induced pseudo-magnetic fields. In this Final Year Project (FYP) report, I investigate the research field of strained graphene particularly for harnessing pseudo-magnetic fields and pseudo-Landau levels. First, I present a review of several key papers discussing the strain- induced pseudo-magnetic fields. I then focus on discussing my research progress for monolayer graphene fabrication and the generation of strained graphene by using patterned substrates. Lastly, I discuss the characterization results of the fabricated devices using Raman spectroscopy. Bachelor of Engineering (Materials Engineering) 2022-10-28T07:30:02Z 2022-10-28T07:30:02Z 2022 Final Year Project (FYP) Wang, B. (2022). Strained graphene optoelectronic devices with unprecedented pseudo-magnetic fields. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/162542 https://hdl.handle.net/10356/162542 en MSE/21/116 application/pdf Nanyang Technological University |
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Engineering::Materials Wang, Boyan Strained graphene optoelectronic devices with unprecedented pseudo-magnetic fields |
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Photonic-integrated circuit (PIC) is a research field that has been attracting many researchers’ interests owing to its great potential for enabling various disruptive technologies. In the past few decades, silicon-based PIC has been at the core of PIC development due to the maturity of industry-adopted silicon processing technologies. Since the first discovery of graphene in 2004, graphene-based PIC has been considered one of the strongest candidates to further improve the performance of silicon-based PIC for various reasons. For example, graphene has higher carrier mobility than silicon, which can allow making high-speed electronic devices. This property also enables producing very high-speed photodetectors. However, due to the zero-bandgap nature of graphene, it remains challenging to create a graphene-based light source, making the bandgap opening an important milestone for developing efficient graphene-based light sources. Recently, there have been several reports that theoretically predict the possibility of opening the energy gaps in graphene by using strain- induced pseudo-magnetic fields. In this Final Year Project (FYP) report, I investigate the research field of strained graphene particularly for harnessing pseudo-magnetic fields and pseudo-Landau levels. First, I present a review of several key papers discussing the strain- induced pseudo-magnetic fields. I then focus on discussing my research progress for monolayer graphene fabrication and the generation of strained graphene by using patterned substrates. Lastly, I discuss the characterization results of the fabricated devices using Raman spectroscopy. |
| author2 |
Nam Donguk |
| author_facet |
Nam Donguk Wang, Boyan |
| format |
Final Year Project |
| author |
Wang, Boyan |
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Wang, Boyan |
| title |
Strained graphene optoelectronic devices with unprecedented pseudo-magnetic fields |
| title_short |
Strained graphene optoelectronic devices with unprecedented pseudo-magnetic fields |
| title_full |
Strained graphene optoelectronic devices with unprecedented pseudo-magnetic fields |
| title_fullStr |
Strained graphene optoelectronic devices with unprecedented pseudo-magnetic fields |
| title_full_unstemmed |
Strained graphene optoelectronic devices with unprecedented pseudo-magnetic fields |
| title_sort |
strained graphene optoelectronic devices with unprecedented pseudo-magnetic fields |
| publisher |
Nanyang Technological University |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/162542 |
| _version_ |
1749179251761872896 |