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Keio University ホーム
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研究成果
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Scopus著者プロファイル
野田 啓
電気情報工学科
ウェブサイト
https://k-ris.keio.ac.jp/html/100011350_ja.html
h-index
803
被引用数
14
h 指数
Pureの文献数とScopusの被引用数に基づいて算出されます
1999
2022
年別の研究成果
概要
フィンガープリント
ネットワーク
研究成果
(66)
類似のプロファイル
(6)
Pureに変更を加えた場合、すぐここに表示されます。
フィンガープリント
Kei Nodaが活動している研究トピックを掘り下げます。このトピックラベルは、この研究者の研究成果に基づきます。これらがまとまってユニークなフィンガープリントを構成します。
並べ替え順
重み付け
アルファベット順
Engineering & Materials Science
Annealing
12%
Buffer layers
30%
Butyric acid
17%
Carrier concentration
12%
Conjugated polymers
12%
Contact resistance
20%
Copolymers
14%
Decomposition
14%
Dimers
16%
Doping (additives)
41%
Electric potential
15%
Electrodes
30%
Electrons
19%
Fabrication
18%
Ferroelectric materials
49%
Field emission
11%
Fullerenes
16%
Gases
16%
Gates (transistor)
15%
Gold
14%
Graphene nanoribbon
17%
Hall effect
14%
Hole mobility
13%
Hydrogen
14%
Hydrogen production
30%
Methanol
37%
Microscopic examination
17%
Molecules
22%
Monolayers
18%
Nanotubes
47%
Oligomers
44%
Organic field effect transistors
27%
Organic semiconductor materials
14%
Oxygen
13%
Palladium
17%
Parameter extraction
13%
Partial pressure
12%
Photocatalysis
15%
Polymers
31%
Polymethyl methacrylates
28%
Self assembled monolayers
13%
Substrates
15%
Thermionic emission
16%
Thin film transistors
100%
Thin films
53%
Thiophene
22%
Titanium dioxide
14%
Transistors
22%
Vacancies
14%
Vacuum
36%
Physics & Astronomy
acids
8%
alkali halides
12%
atomic force microscopy
11%
buffers
13%
butyric acid
8%
composite materials
10%
contact resistance
12%
decomposition
23%
dimers
9%
electric contacts
10%
electric potential
14%
electrodes
24%
electrons
9%
fabrication
14%
field effect transistors
9%
field emission
8%
fluorides
38%
formaldehyde
10%
fullerenes
11%
gas reactors
8%
gold
9%
graphene
8%
high vacuum
36%
hydrogen
14%
hydrogen production
44%
illumination
11%
mass spectrometers
9%
membranes
11%
methyl alcohol
42%
microscopy
15%
molecules
11%
nanotubes
46%
oligomers
45%
oxygen
10%
palladium
15%
partial pressure
9%
polymers
25%
polymethyl methacrylate
16%
probes
14%
purity
9%
thermionic emission
11%
thin films
72%
thiophenes
18%
titanium
11%
titanium oxides
20%
transistors
68%
traps
12%
vapor phases
22%
vinylidene
43%
water
10%
Chemical Compounds
Alternating Copolymer
6%
Behavior as Electrode
8%
Benzimidazole
11%
Bilayer Membrane
12%
Buffer Solution
13%
Composite Material
6%
Compound Mobility
10%
Copper Oxide
5%
Decomposition
10%
Doping Material
14%
Electrical Property
6%
Electron Particle
6%
Electron Trap
8%
Ferroelectric Film
9%
Field Effect
22%
Field Emission
6%
Gas
8%
Hall Effect
7%
Hole Mobility
11%
Hydrogen
6%
Illumination
11%
Kelvin Probe Force Microscopy
15%
Liquid Film
21%
Methanol
19%
Methyl Ester
7%
Molecular Crystal
6%
Molecule
8%
Monolayer
11%
Multilayer
9%
Nanotube
21%
Non-Contact AFM
10%
Nonconductor
14%
Oligomer
12%
Palladium
10%
Partial Pressure
6%
Pentacene
22%
Photocatalytic Oxidation
7%
Photoconductivity
6%
Reflectivity
7%
Resistance
5%
Schottky Barrier
12%
Schottky Contact
19%
Self Assembled Monolayer
8%
Semiconductor
6%
Simulation
8%
Surface
8%
Terephthalic Acid
6%
Vacuum
30%
Vinylidene Fluoride
20%
Voltage
11%