2016 Fiscal Year Research-status Report
Probing THz Evanescent Waves of Non-equilibrium Dynamics
Project/Area Number |
16K17517
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Research Institution | The University of Tokyo |
Principal Investigator |
林 冠廷 東京大学, 生産技術研究所, 特任助教 (70772309)
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Project Period (FY) |
2016-04-01 – 2018-03-31
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Keywords | Near-field microscopy / THz image / Graphene / Noise image |
Outline of Annual Research Achievements |
To prove the passive THz scattering-type scanning near-field optical microscope (s-SNOM) that can be a unique experimental tool for investigating the non-equilibrium dynamics system via probing electromagnetic evanescent waves, we first observed the current-induced evanescent waves on graphene device. The electrotransport measurement system has been introduced into the sample stage of the AFM system, which enables us to apply the voltage/current bias to the device. To eliminate the thermally excited evanescent waves from the excess current-induced evanescent waves, I ceased modulating the tip-height to extract the near-field signals and established the current-modulation method. After the measurement method was established, we successfully observed 2D near-field images on the biased graphene. The near-field signals generated on the sample surface can be seen as the current-induced excess noise, which is related to the fluctuating charge/current. In the narrow constricted graphene, we found that the noise fields strongly show up in the constricted region due to the higher current density and increase almost linearly with increasing current. The temperature rise in the narrow constriction can be explained by considering the carrier energy dissipation through inelastic carrier-carrier, carrier-phonon, and carrier-impurity interactions. This work was reported in the 64th JSAP Spring Meeting. The THz s-SNOM thus has been proved to be a unique non-invasive experimental tool for investigating the noise field distribution via the near-field mapping not only for the graphene devices.
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Current Status of Research Progress |
Current Status of Research Progress
2: Research has progressed on the whole more than it was originally planned.
Reason
The project is progressing smoothly. The design and fabrication of the graphene devices and metallic nano-wire devices were carried out. We successfully observed 2D near-field images on the biased graphene device. The passive s-SNOM thus has been proved to be a unique non-invasive experimental tool for investigating the noise field distribution. The GaAs 2DEG conducting channels are now undergoing fabricating. Planned experiments were also conducted. The first graphene THz image results have been submitted and will be presented at international conferences in 2017 (EP2DS-22 and IRMMW-THz 2017).
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Strategy for Future Research Activity |
For the second year, I will continuously design and fabricate the new graphene device, GaAs 2DEG narrow conducting channel, and Pt nanowire device. The results, obtained in the first year, shows that the passive THz s-SNOM can be applied to the non-equilibrium system. Therefore, the GaAs 2DEG system and metallic nano-wire, proposed in the project, also have a chance to image the non-equilibrium charge/current induced evanescent waves and study the energy relaxation processes of the charge carriers. To simulate the electron-phonon relaxation process, we planed to use the COMSOL simulator. It may help us to distinguish the energy relaxation process of electron-phonon in the non-equilibrium system.
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Causes of Carryover |
Because the fabrication process of the 2DEG conducting device has not been finished, some experimental items, such as high power DC voltage supply, have not been bought yet. I did not attend the oversea international conference in the first year.
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Expenditure Plan for Carryover Budget |
For feedback-controlled electromigration in the metallic nano-wire device, the highly precision source/measure unit will be purchased. For data simulation, I plan to buy the COMSOL simulator. Some consumable goods are still needed for the following experiments. The EP2DS international conference has already accepted our submission about the graphene results. Therefore, I will attend the conference hold at Penn State University, U.S.A, in July 2017.
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Research Products
(8 results)