Spin-resolved oscilloscope for charge and spin signals|NTT Basic Research Laboratories | NTT R&D Website
: Basic measuring instrument for future plasmonics and spintronics (Tokyo, March 2017) Researchers at the
https://www.rd.ntt/e/brl/latesttopics/2017/03/latest_topics_201703141752.html
Overview and Prospects for Research on Plasmons in Two-dimensional Semiconductor Systems | NTT R&D Website
Plasmons in Two-dimensional Semiconductor Systems plasmonics graphene semiconductor Plasmons, which are
https://www.rd.ntt/e/research/JN202303_21252.html
Demonstration of ultrafast and energy-efficient all-optical switching with graphene and plasmonic waveguides|NTT Basic Research Laboratories | NTT R&D Website
processing. In addition, this development shows novel promising possibility for applications of plasmonics. A
https://www.rd.ntt/e/brl/latesttopics/2019/11/latest_topics_201911261120.html
Electrical Control of Plasmon Reflectivity in Graphene | NTT R&D Website
for manipulating plasmons in nanoscale regions is referred to as plasmonics. Plasmonics has been used
https://www.rd.ntt/e/research/JN202303_21254.html
plasmon
field to nanoscale structures. However, there is a fundamental limitation to using metals for plasmonics
https://www.rd.ntt/brl/people/kumada/research/further_grapheneEMP.html
Quantum Solid State Physics Research Group|Opportunities
-transform infrared spectroscopy. While our current main target is graphene plasmonics, we plan to apply
https://www.rd.ntt/brl/group_introduction/ryoubutsu-g/opportunities.html
Quantum Solid State Physics Research Group|Members
] Members Norio Kumada Senior Distinguished Scientist/Group Leader Graphene plasmonics, Carrier dynamics
https://www.rd.ntt/brl/group_introduction/ryoubutsu-g/members.html
Plasmon Transport in Graphene Investigated by Time-Resolved Electrical Measurements
, could provide a means of confining electromagnetic field to nanoscale regions. Recently, plasmonics in
https://www.rd.ntt/e/brl/result/activities/file/report12/report18e.html
List of Invited Talks at International Conferences (2010)
Plasmonics (META’10), Cairo, Egypt (Feb. 2010) (Plenary). (4) K. Oguri, T. Okano, T. Nishikawa, and H. Nakano
https://www.rd.ntt/e/brl/result/activities/file/report10/data09.html
国際会議招待講演一覧(2010年)
Plasmonics (META’10), Cairo, Egypt (Feb. 2010) (Plenary). (4) K. Oguri, T. Okano, T. Nishikawa, and H. Nakano
https://www.rd.ntt/brl/result/activities/file/report10/data09.html
Masashi Miyata | NTT R&D Website
of Applied Physics 111 (5), 053102 (2012). Keywords Metasurface, Metamaterial, Plasmonics
https://www.rd.ntt/e/organization/researcher/special/s_100.html
Emission Enhancement in a Nanowire Coupled to a Nanoantenna
plasmonics, which overcomes the diffraction limit of light, and studied a bowtie nanoantenna to enhance the
https://www.rd.ntt/e/brl/result/activities/file/report14/report29E.html
国際会議招待講演一覧(2012年)
Crystals, and Plasmonics (META'12), Paris, France (Apr. 2012). (4) M. Notomi, K. Nozaki, S. Matsuo, A
https://www.rd.ntt/brl/result/activities/file/report12/data09.html
List of Invited Talks at International Conferences (2012)
network on chip", The Fourth International Conference on Metamaterials, Photonic Crystals, and Plasmonics
https://www.rd.ntt/e/brl/result/activities/file/report12/data09e.html
Time-resolved Measurement of Ambipolar Plasmon Transport in Semiconductor Composite Quantum Wells | NTT R&D Website
insulators topological quantum computing plasmonics Two-dimensional topological insulators have attracted
https://www.rd.ntt/e/research/JN202303_21262.html
Norio Kumada
-frequency transport measurement) Graphene plasmonics have attracted interest, particularly because of the
https://www.rd.ntt/brl/people/kumada/researchj.html
Norio Kumada
-frequency transport measurement) Graphene plasmonics have attracted interest, particularly because of the
https://www.rd.ntt/brl/people/kumada/research.html
世界で初めてトポロジーの原理を利用したギガヘルツ超音波回路を実現|NTT物性科学基礎研究所 | NTT R&D Website
・富山市で開催される国際会議「14th International Conference of Metamaterials, Photonic Crystals and Plasmonics」(略称
https://www.rd.ntt/brl/latesttopics/2024/07/latest_topics_202407161738.html
Pioneering the Understanding and Functional Exploration of Carrier Dynamics in Atomic-layer Materials | NTT R&D Website
Electronics on July 17, 2024[2]. We plan to expand this work to applications in plasmonics (a technology for
https://www.rd.ntt/e/research/JN202505_33801.html
Exploring New Fields and the World | NTT R&D Website
substance at room temperature. *4Plasmonics: A plasmon is a quantum of plasma oscillation. By controlling
https://www.rd.ntt/e/research/JN202006_2201.html
NTTBrl_honbun_E_220301-2.indd
nanophotonics such as photonic crystal, silicon photonics, plasmonics technologies. We also conduct research
https://www.rd.ntt/e/brl/result/activities/file/annual_report/Annual_report_2021_E.pdf
NTTBrl__E_h1
photonic crystals and plasmonics ●Integrable nanophotonic devices with extremely small energy consumption
https://www.rd.ntt/e/brl/result/activities/file/annual_report/Annual_report_2017_E.pdf
Annual_report_2023_E.pdf
enhancement of light-matter interactions by using photonic crystals and plasmonics ●Integrable nanophotonic
https://www.rd.ntt/brl/brl/result/activities/file/annual_report/Annual_report_2023_E.pdf
NTTBrl_honbun_E_190306.indd
enhancement of light-matter interactions by using photonic crystals and plasmonics ●Integrable nanophotonic
https://www.rd.ntt/e/brl/result/activities/file/annual_report/Annual_report_2018_E.pdf
Annual_report_2019_E.pdf
enhancement of light-matter interactions by using photonic crystals and plasmonics ●Integrable nanophotonic
https://www.rd.ntt/e/brl/result/activities/file/annual_report/Annual_report_2019_E.pdf
Annual_report_2023_E.pdf
enhancement of light-matter interactions by using photonic crystals and plasmonics ●Integrable nanophotonic
https://www.rd.ntt/e/brl/result/activities/file/annual_report/Annual_report_2023_E.pdf
NTTBrl_honbun_E_230228_final.indd
environment. ●Extreme enhancement of light-matter interactions by using photonic crystals and plasmonics
https://www.rd.ntt/brl/brl/result/activities/file/annual_report/Annual_report_2022_E.pdf
Annual_report_2020_E.pdf
plasmonics ●Integrable nanophotonic devices with extremely small energy consumption ●Nano-imprint, SPM
https://www.rd.ntt/e/brl/result/activities/file/annual_report/Annual_report_2020_E.pdf
NTTBrl_honbun_E_230228_final.indd
environment. ●Extreme enhancement of light-matter interactions by using photonic crystals and plasmonics
https://www.rd.ntt/e/brl/result/activities/file/annual_report/Annual_report_2022_E.pdf
Annual_report_2024_E.pdf
plasmonics ●Integrable nanophotonic devices with extremely small energy consumption ●Novel optical platforms
https://www.rd.ntt/brl/brl/result/activities/file/annual_report/Annual_report_2024_E.pdf
NTTBrl_honbun_E_250225.indd
plasmonics ●Integrable nanophotonic devices with extremely small energy consumption ●Novel optical platforms
https://www.rd.ntt/brl/result/activities/file/annual_report/NTTBrl_E_250321_print.pdf
NTTBrl_honbun_J_220301.indd
, silicon photonics, plasmonics technologies. We also conduct research aiming at the ultimate reduction of
https://www.rd.ntt/brl/result/activities/file/annual_report/Annual_report_2021_J.pdf
NTTBrl_honbun_E_260302.indd
interactions by using photonic crystals and plasmonics ●Integrable nanophotonic devices with extremely small
https://www.rd.ntt/brl/result/activities/file/annual_report/NTTBrl_E_260310_print.pdf
Publications
Crystals and Plasmonics (META'17), July 28, 2017, Incheon, South Korea (invited). P. L. McMahon, A. Marandi
https://www.rd.ntt/brl/people/htakesue/papers.html
Report_12.pdf
https://www.rd.ntt/brl/result/activities/file/report12/Report_12.pdf
Report_12.pdf
https://www.rd.ntt/e/brl/result/activities/file/report12/Report_12.pdf
NTT物性科学基礎研究所の研究活動
https://www.rd.ntt/brl/result/activities/file/report10/Report_2010J.pdf
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