Publication list
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(1) Synthesis of sp2-type carbonaceous thin films by
glow discharge plasma, T. Abe, T. Fukutsuka, M. Inaba, and
Z. Ogumi, Carbon, 37, 1165-1168 (1999).
(2) Preparation and Electrochemical Properties of Carbonaceous
Thin Films Prepared by C2H4/NF3
Glow Discharge Plasma, T. Fukutsuka, T. Abe, M. Inaba, Z.
Ogumi, N. Tsuji, and A. Tasaka, Tanso , 190, 252-256
(1999).
(3) Electrochemical Intercalation of Li into Carbon Thin Films
Prepared by Plasma CVD, T. Fukutsuka, T. Abe, M. Inaba, and
Z. Ogumi, Molecular Crystals and Liquid Crystals, 340,
517-522 (2000).
(4) Electrochemical Properties of Carbonaceous Thin Films
Prepared by Plasma Chemical Vapor Deposition, T. Fukutsuka,
T. Abe, M. Inaba, and Z. Ogumi, Journal of the Electrochemical
Society, 148, A1260-A1265 (2001).
(5) Electrochemical Lithium Insertion/Extraction for
Carbonaceous Thin Film Electrodes in Propylene Carbonate Solution, T.
Fukutsuka, T. Abe, M. Inaba, Z. Ogumi, Y. Matsuo, and Y.
Sugie, Carbon Science, 1, 129-132 (2001).
(6) LITHIUM ION TRANSFER AT CARBON THIN FILM
ELECTRODE/ELECTROLYTE INTERFACE, T. Abe, T. Fukutsuka, S.
Yamate, Y. Iriyama, M. Inaba, and Z. Ogumi, Molecular Crystals
and Liquid Crystals, 388, 141-146 (2002).
(7) SURFACE MODIFICATION OF CARBONACEOUS THIN FILMS BY NF3
PLASMA AND THIER EFFECTS ON ELECTROCHMICAL PROPERTIES, T.
Fukutsuka, Y. Matsuo, Y. Sugie, T. Abe, M. Inaba, and Z.
Ogumi, Molecular Crystals and Liquid Crystals, 388,
117-122 (2002).
(8) Synthesis of highly graphitized carbonaceous thin films by
plasma assisted chemical vapor deposition and their electrochemical
properties in propylene carbonate solution, T. Abe, K. Takeda, T.
Fukutsuka, Y. Iriyama, M. Inaba, and Z. Ogumi, Electrochemistry
Communications, 4, 310-313 (2002).
(9) Photochemical dimerization of acenaphtylene in
surfactant-intercalated graphite oxide, Y. Matsuo, T. Fukutsuka,
and Y. Sugie, Carbon, 40, 958-961 (2002).
(10) Synthesis of polyaniline-intercalated layered materials
via exchange reaction, Y. Matsuo, S. Higashika, K. Kimura, Y.
Miyamoto, T. Fukutsuka, and Y. Sugie, Journal of
Materials Chemistry, 12, 1592-1596 (2002).
(11) 自己組織化による界面活性剤−酸化黒鉛層間化合物中のナノ空間へのアゾベンゼンの導入, 松尾吉晃, 十倉直人, 福
塚友和, 杉江他曾宏, 炭素, 205, 221-225 (2002).
(12) PHOTOCHEMICAL DIMERIZATION OF ACENAPHTYLELE IN
HYDROPHOBIZED GRAPHITE OXIDE, Y. Matsuo, T. Fukunaga, T.
Fukutsuka, and Y. Sugie, Molecular Crystals and Liquid
Crystals, 386, 45-50 (2002).
(13) Butyrolactone derivatives as electrolyte additives for
lithium ion batteries with graphite anodes, Y. Matsuo, K. Fumita, T.
Fukutsuka, Y. Sugie, H. Koyama, and K. Inoue, Journal of
Power Sources, 119-121, 373-377 (2003).
(14) Surface Plasma Modification of Carbonaceous Thin Film
Electrodes, T. Fukutsuka, S. Hasegawa, T. Katayama, Y.
Matsuo, Y. Sugie, T. Abe, and Z. Ogumi, Electrochemistry,
71, 1111-1113 (2003).
(15) Surface Modification of Carbonaceous Thin Films by
Electropolymerization of Pyrrole and its Effects on Electrochemical
Properties (1), T. Doi, K. Takeda, T. Fukutsuka, Y. Iriyama,
T. Abe, and Z. Ogumi, Tanso, 210, 217-220 (2003).
(16) Characterization of n-hexadecylalkylamine-intercalated
graphite oxides as sorbents, Y. Matsuo, K. Watanabe, T.
Fukutsuka, and Y. Sugie, Carbon, 41, 1545-1550
(2003).
(17) Photochemical dimerization of acenaphtylene in
hydrophobized graphite oxide (II), Y. Matsuo, T. Fukunaga, N.
Tokura, T. Fukutsuka, and Y. Sugie, Transactions of
Materials Research Society of Japan, 28, 589-595 (2003).
(18) Electrochemical hydrogenation of carbon from pyrolysis of
graphite oxide, Y. Matsuo, K. Kume, T. Fukutsuka, and Y.
Sugie, Carbon, 41, 2167-2170 (2003).
(19) Preparation and Fluorescent Properties of Rhodamine
B–hexadecylamine-intercalated Graphite Oxide Thin Film, Y. Matsuo, T.
Fukutsuka, and Y. Sugie, Chemistry Letters, 32,
1004-1005 (2003).
(20) Effect of Alloying Elements on the Rate of Growth of
Individual Pits on Stainless Steels, Y. Marinovich, T. Fukutsuka,
Y. Matsuo, and Y. Sugie, Developments in Chemical Engineering
and Mineral Processing, 11, 499-508 (2003).
(21) Lithium ion transfer at interface between carbonaceous
thin film electrode/electrolyte, Z. Ogumi, T. Abe, T. Fukutsuka,
S. Yamate, and Y. Iriyama, Journal of Power Sources,
127(1-2), 72-75 (2004).
(22) Electrochemical Properties of Graphitized Carbonaceous
Thin Films Prepared by PACVD, T. Abe, K. Takeda, T. Fukutsuka,
Y. Iriyama, and Z. Ogumi, Journal of the Electrochemical
Society, 151, C694-C697 (2004).
(23) Preparation of LiMn2O4 Thin-Film
Electrode by the Oxygen Plasma-Assisted Sol-Gel Method, T.
Fukutsuka, K. Sakamoto, Y. Matsuo, Y. Sugie, T. Abe, and Z.
Ogumi, Electrochemical and Solid-State Letters, 7,
A481-A483 (2004).
(24) Silylation of graphite oxide, Y. Matsuo, T. Fukunaga, T.
Fukutsuka, and Y. Sugie, Carbon, 42, 2117-2119
(2004).
(25) Enhanced Fluorescence from Rhodamine B Intercalated into
Hydrophobized Graphite Oxides Containing Perfluoroalkyl Chains, Y.
Matsuo, T. Fukunaga, T. Fukutsuka, and Y. Sugie, Chemistry
Letters, 33, 1432-1433 (2004).
(26) Control of photochemical dimerization of acenaphtylene in
graphite oxide intercalated by n-alkylamines with different alkyl
chain length, Y. Matsuo, T. Fukunaga, N. Tokura, T. Fukutsuka,
and Y. Sugie, Transactions of Materials Research Society of
Japan, 29, 3219-3222 (2004).
(27) メカニカルアローイング法による高窒素添加ステンレス鋼の作製と局部腐食特性評価, 福塚友和,安在哲也,
兼田マミ,松尾吉晃,杉江他曾宏,深浦健三, 材料, 53, 1175-1179 (2004).
(28) Cathode properties of birnessite type manganese oxide
prepared by using vanadium xerogel, Y. Matsuo, Y. Miyamoto, T.
Fukutsuka, and Y. Sugie, Journal of Power Sources,
146(1-2), 300-303 (2005).
(29) Surface modification of graphitized carbonaceous materials
by electropolymerization of thiophene and their effects on
electrochemical properties, T. Doi, K. Takeda, T. Fukutsuka,
Y. Iriyama, T. Abe, and Z. Ogumi, Carbon, 43, 2352-2357
(2005).
(30) Preparation of surface-modified carbonaceous thin-film
electrodes by NF3 plasma and their electrochemical
properties, T. Fukutsuka, S. Hasegawa, Y. Matsuo, Y. Sugie,
T. Abe, and Z. Ogumi, Journal of Power Sources, 146(1-2),
151-155 (2005).
(31) Preparation and characterization of silylated graphite
oxide, Y. Matsuo, T. Tabata, T. Fukunaga, T. Fukutsuka, and
Y. Sugie, Carbon, 43, 2875-2882 (2005).
(32) Dispersion of Organic Dyes in
n-Hexadecylamine-Intercalated Vanadium Xerogel Thin Films, Y.
Matsuo, N. Yamada, T. Fukutsuka, and Y. Sugie, Molecular
Crystals and Liquid Crystals, 452, 133-154, (2006).
(33) Monomeric Dispersion of Covalently Attached Pyrene
Chromophores in Silylated Graphite Oxide, Y. Matsuo, T.
Fukutsuka, and Y. Sugie, Chemistry Letters, 35,
530-531 (2006).
(34) Reaction between dibutyltin oxide and graphite oxide, Y.
Matsuo, Y. Matsumoto, T. Fukutsuka, and Y. Sugie, Carbon,
44, 3134-3135 (2006).
(35) Preparation of carbonaceous thin films by plasma-assisted
chemical vapor deposition using active fluorine atoms, T.
Fukutsuka, Y. Matsuo, Y. Sugie, T. Abe, and Z. Ogumi, Tanso,
230, 293-298 (2007).
(36) Preparation and characterization of
alkylamine-intercalated graphite oxides, Y. Matsuo, T. Miyabe, T.
Fukutsuka, and Y. Sugie, Carbon, 45, 1005-1012
(2007).
(37) Introduction of amino groups into the interlayer space of
graphite oxide using 3-aminopropylethoxysilanes, Y. Matsuo, Y.
Nishino, T. Fukutsuka, and Y. Sugie, Carbon, 45,
1384-1390 (2007).
(38) Preparation of Pillared Carbons by Pyrolysis of Silylated
Graphite Oxide, Y. Matsuo, Y. Sakai, T. Fukutsuka, and Y.
Sugie, Chemistry Letters, 36, 1050-1051 (2007).
(39) Improvement in Corrosion Properties of Carbon-coated
Fe-based Metals for PEFC Bipolar Plate, T. Fukutsuka, T.
Yamaguchi, Y. Matsuo, Y. Sugie, and Z. Ogumi, Electrochemistry,
75, 152-154 (2007).
(40) Carbon-coated stainless steel as PEFC bipolar plate
material, T. Fukutsuka, T. Yamaguchi, SI. Miyano, Y. Matsuo,
Y. Sugie, and Z. Ogumi, Journal Power Sources, 174,
199-205 (2007).
(41) Hydrophilic Treatment of Carbon-coated Metal by Plasma
Fluorination, T. Fukutsuka, SI. Miyano, Y. Matsuo, Y. Sugie,
Chemistry Letters, 36, 1440-1441 (2007).
(42) Removal of formaldehyde from gas phase by silylated
graphite oxide containing amino groups, Y. Matsuo, Y. Nishino, T.
Fukutsuka, and Y. Sugie, Carbon, 46, 1162-1163
(2008).
(43) Silylation of graphite oxide by octyldimethylchlorosilane,
Y. Matsuo, Y. Matsumoto, T. Fukutsuka, and Y. Sugie, Tanso,
233, 115-118 (2008).
(44) Preparation of silylated magadiite thin-film-containing
covalently attached pyrene, chromophores, Y. Matsuo, Y. Yamada, M.
Nishikawa, T. Fukutsuka, and Y. Sugie, Journal of
Fluorine Chemistry, 129, 1150-1155 (2008).
(45) Electrochemical Behavior of Various Kinds of Stainless
Steels in a High-Temperature and High-Pressure Methanol Solution, D.
Shintani, T. Ishida, T. Fukutsuka, Y. Matsuo, and Y. Sugie,
Corrosion, 64, 607-612 (2008).
(46) XPS studies on passive film formed on stainless steel in a
high-temperature and high-pressure methanol solution containing
chloride ions, D. Shintani, T. Ishida, H. Izumi, T. Fukutsuka,
Y. Matsuo, and Y. Sugie, Corrosion Science, 50, 2840-2845
(2008).
(47) Determination of lithium ion diffusion in
lithium-manganese-oxide-spinel thin films by secondary-ion mass
spectrometry, T. Okumura, T. Fukutsuka, Y. Uchimoto, N.
Sakai, K. Yamaji, and H. Yokokawa, Journal of Power Sources,
189, 643-645 (2009).
(48) Electronic structures of partially fluorinated lithium
manganese spinel oxides and their electrochemical properties, K.
Matsumoto, T. Fukutsuka, T. Okumura, Y. Uchimoto, K.
Amezawa, M. Inaba, and A. Tasaka, Journal of Power Sources,
189, 599-601 (2009).
(49) Improvement of Li-ion conductivity in A-site disordering
lithium-lanthanum-titanate perovskite oxides by adding LiF in
synthesis, T. Okumura, T. Fukutsuka, Y. Uchimoto, N. Sakai,
K. Yamaji, and H. Yokokawa, Journal of Power Sources, 189,
536-538 (2009).
(50) Cathode having high rate performance for a secondary
Li-ion cell surface-modified by aluminum oxide nanoparticles, T.
Okumura, T. Fukutsuka, Y. Uchimoto, K. Amezawa, and S.
Kobayashi, Journal of Power Sources, 189, 471-475 (2009).
(51) Preparation and characterization of pillared carbons
obtained by pyrolysis of silylated graphite oxides, Y. Matsuo, Y.
Sakai, T. Fukutsuka, and Y. Sugie, Carbon, 47,
804-811 (2009).
(52) Lithium-Ion conductivity in Lithium Lanthanum Titanates as
Different Local Distortion Model Compounds, T. Okumura, T.
Fukutsuka, Y. Uchimoto, M. Saito, and J. Kuwano, Electrochemistry,
78, 457-459 (2010).
(53) Lithium-ion Transfer at the Interface between Solid and
Liquid Electrolytes under Applying DC Voltage, F. Sagane, K.
Miyazaki, T. Fukutsuka, Y. Iriyama, T. Abe, and Z. Ogumi, Chemistry
Letters, 39, 826-827 (2010).
(54) Ion-solvent interaction for lithium-ion transfer at the
interface between carbonaceous thin-film electrode and electrolyte,
T. Fukutsuka, F. Sagane, K. Miyazaki, T. Abe, T. Toda, Y.
Matsuo, Y. Sugie, and Z. Ogumi, Tanso, 245, 188-191
(2010).
(55) Ionic and Electronic Conductivities and Fuel Cell
Performance of Oxygen Excess-Type Lanthanum Silicates, A. Mineshige,
T. Nakao, Y. Ohnishi, R. Sakamoto, Y. Daiko, M. Kobune, T. Yazawa,
H. Yoshioka, T. Fukutsuka, and Y. Uchimoto, Journal of
the Electrochemical Society, 157, B1465-B1470 (2010).
(56) Improvement in stability of LiMn2O4
thin-film electrodes by oxygen-plasma irradiation to precursor gel,
Y. Matsuo, Y. Sugie, K. Sakamoto, and T. Fukutsuka, Journal
of Solid State Electrochemistry, 15, 503-510 (2011).
(57) Depth-resolved X-ray absorption spectroscopic study on
nanoscale observation of the electrode–solid electrolyte interface
for all solid state lithium ion batteries, T. Okumura, T.
Nakatsutsumi, T. Ina, Y. Orikasa, H. Arai, T. Fukutsuka, Y.
Iriyama, T. Uruga, H. Tanida, Y. Uchimoto, and Z. Ogumi, Journal
of Materials Chemistry, 21, 10051-10060 (2011).
(58) Lithium-Ion Transfer Reaction at the Interface between
Partially Fluorinated Insertion Electrodes and Electrolyte
Solutions, T. Okumura, T. Fukutsuka, K. Matsumoto, Y.
Orikasa, H. Arai, Z. Ogumi, and Y. Uchimoto, Journal of
Physical Chemistry C, 115, 12990-12994 (2011).
(59) Electrochemical properties of graphite electrode in
propylene carbonate-based electrolytes containing lithium and
calcium ions, S. Takeuchi, K. Miyazaki, F. Sagane, T. Fukutsuka,
S-K. Jeong, and T. Abe, Electrochimica Acta, 56,
10450-10453 (2011).
(60) Electronic and local structural changes with lithium-ion
insertion in TiO2-B: X-ray absorption spectroscopy study,
T. Okumura, T. Fukutsuka, A. Yanagihara, Y. Orikasa, H.
Arai, Z. Ogumi, and Y. Uchimoto, Journal of Materials Chemistry,
21, 15369-15377 (2011).
(61) Nanosized Effect on Electronic/Local Structures and
Specific Lithium-Ion Insertion Property in TiO2-B
Nanowires Analyzed by X-ray Absorption Spectroscopy, T. Okumura, T.
Fukutsuka, A. Yanagihara, Y. Orikasa, H. Arai, Z. Ogumi, and
Y. Uchimoto, Chemistry of Materials, 23,3636-3644 (2011).
(62) Role of Local and Electronic Structural Changes with
Partially Anion substitution Lithium Manganese Spinel Oxides on
Their Electrochemical Properties: X-ray Absorption Spectroscopy
Study, T. Okumura, T. Fukutsuka, K. Matsumoto, Y. Orikasa,
H. Arai, Z. Ogumi, and Y. Uchimoto, Dalton Transactions,
40, 9752-9764 (2011).
(63) Factors Affecting the Formation of Carbon Film on the
Stainless Steels for the Bipolar Plate of Polymer Electrolyte Fuel
Cells, S. Miyano, Y. Matsuo, Y. Sugie, and T. Fukutsuka, Journal
of Fuel Cell Science and Technology, 8, 31008-1-31008-5
(2011).
(64) Single-step synthesis of nano-sized perovskite-type
oxide/carbon nanotube composites and their electrocatalytic
oxygen-reduction activities, K. Miyazaki, K. Kawakita, T. Abe, T.
Fukutsuka, K. Kojima, and Z. Ogumi, Journal of Materials
Chemistry, 21, 1913-1917 (2011).
(65) Effect of cation doping on ionic and electronic properties
for lanthanum silicate-based solid electrolytes, A. Mineshige, Y.
Ohnishi, R. Sakamoto, Y. Daiko, M. Kobune, T. Yazawa, H. Yoshioka,
T. Nakao, T. Fukutsuka, and Y. Uchimoto, Solid State
Ionics, 192, 195-199 (2011).
(66) 種々のステンレス鋼への炭素薄膜被覆と固体高分子形燃料電池用セパレータ材料への適用, 宮野真一,福塚友和,
松尾吉晃,杉江他曾宏, 炭素, 247, 54-58 (2011).
(67) Electrochemical oxidation of ethylene glycol on Pt-based
catalysts in alkaline solutions and quantitative analysis of
intermediate products, K. Miyazaki, T. Matsumiya, T. Abe, H. Kurata,
T. Fukutsuka, K. Kojima, and Z. Ogumi, Electrochimica
Acta, 56, 7610-7614 (2011).
(68) Surface Modification of Graphitized Carbonaceous-Thin Film
Electrodes with Silver for Enhancement of Interfacial Lithium-Ion
Transfer, T. Doi, T. Fukutsuka, K. Takeda, T. Abe, K.
Miyazaki, and Z. Ogumi, Journal of Physical Chemistry C,
116, 12422-12425 (2012).
(69) Influences of metal oxides on carbon corrosion under
imposed electrochemical potential conditions, K. Miyazaki, M. Nose,
T. Kinumoto, T. Abe, T. Fukutsuka, Z. Ogumi, Carbon,
50, 1644-1649 (2012).
(70) Formation of "fuzzy" phases with high proton
conductivities in the composites of polyphosphoric acid and metal
oxide nanoparticles, K. Miyazaki, Y. Kato, T. Matsui, S. Hayashi, Y.
Iriyama, T. Fukutsuka, T. Abe, Z. Ogumi, Physical
Chemistry Chemical Physics, 14, 11135-11138 (2012).
(71) Suppression of Dendrite Formation of Zinc Electrodes by
the Modification of Anion-Exchange Ionomer, K. Miyazaki, Y. Lee, T.
Fukutsuka, and T. Abe, Electrochemistry, 80, 725-727
(2012).
(72) Electrochemical Intercalation/De-Intercalation of Lithium
Ions at Graphite Negative Electrode in TMP-Based Electrolyte
Solution, S. Takeuchi, S. Yano, T. Fukutsuka, K. Miyazaki,
and T. Abe, Journal of the Electrochemical Society, 159,
A2089-A2091 (2012).
(73) Fabrication of Step-edge-decorated Graphite Electrodes
with Platinum and Their Electrocatalytic Activities, K. Miyazaki, T.
Fukutsuka, T. Abe, and Z. Ogumi, Chemistry Letters,
42, 606-608 (2013).
(74) Electrochemical properties of carbon nanofibers as the
negative electrode in lithium-ion batteries, S. Maruyama, G. Zhuang,
H. Wang, T. Fukutsuka, K. Miyazaki, T. Abe, T. Doi, and Z.
Ogumi, Tanso, 256, 52-56 (2013).
(75) Electrochemical preparation of a
lithium-graphite-intercalation compound in a dimethyl
sulfoxide-based electrolyte containing calcium ions, S. Takeuchi, T.
Fukutsuka, K. Miyazaki, and T. Abe, Carbon, 57,
232-238 (2013).
(76) Electrochemical lithium ion intercalation into graphite
electrode in propylene carbonate-based electrolytes with dimethyl
carbonate and calcium salt, S. Takeuchi, T. Fukutsuka, K.
Miyazaki, and T. Abe, Journal of Power Sources, 238, 65-68
(2013).
(77) Structural insights into ion conduction of layered double
hydroxides with various proportions of trivalent cations, K.
Miyazaki, Y. Asada, T. Fukutsuka, T. Abe, and L.A.
Bendersky, Journal of Materials Chemistry, A, 1,
14569-14576 (2013).
(78) Catalytic Roles of Perovskite Oxides in Electrochemical
Oxygen Reactions in Alkaline Media, Y. Miyahara, K. Miyazaki, T.
Fukutsuka, and T. Abe, Journal of the Electrochemical
Society, 161, F694-F697 (2014).
(79) Kinetics of Lithium-Ion Transfer at the Interface between
Li4Ti5O12 Thin Films and Organic
Electrolytes, Y. Ishihara, K. Miyazaki, T. Fukutsuka, and T.
Abe, ECS Electrochemistry Letters, 3, A83-A86 (2014).
(80) New Magnesium-ion Conductive Electrolyte Solution Based on
Triglyme for Reversible Magnesium Metal Deposition and Dissolution
at Ambient Temperature, T. Fukutsuka, K. Asaka, A. Inoo, R.
Yasui, K. Miyazaki, T. Abe, K. Nishio, and Y. Uchimoto, Chemistry
Letters, 43, 1788-1790 (2014).
(81) Lithium-Ion Transfer at the Interface between High
Potential Negative Electrodes and Ionic Liquids, Y. Ishihara, K.
Miyazaki, T. Fukutsuka, and T. Abe, Journal of the
Electrochemical Society, 161, A1939-A1942 (2014).
(82) Investigations of Electrochemically Active Regions in
Bifunctional Air Electrodes Using Partially Immersed Platinum
Electrodes, A. Ikezawa, K. Miyazaki, T. Fukutsuka, and T.
Abe, Journal of the Electrochemical Society, 162,
A1646-A1653 (2015).
(83) Lithium-ion transfer at the interfaces between LiCoO2
and LiMn2O4 thin film electrodes and organic
electrolytes, I. Yamada, K. Miyazaki, T. Fukutsuka, Y.
Iriyama, T. Abe, and Z. Ogumi, Journal of Power Sources ,
294, 460-464 (2015).
(84) Electrochemical Performances of Zinc Oxide Electrodes
Coated with Layered Double Hydroxides in Alkaline Solutions, Y.-S.
Lee, K. Miyazaki, T. Fukutsuka, and T. Abe, Chemistry
Letters, 44, 1359-1361 (2015).
(85) Influence of Surface Orientation on the Catalytic
Activities of La0.8Sr0.2CoO3
Crystal Electrodes for Oxygen Reduction and Evolution Reactions, Y.
Miyahara, K. Miyazaki, T. Fukutsuka, and T. Abe, ChemElectroChem,
3, 214-217 (2016).
(86) Electrochemical properties of LiCoPO4-thin film
electrodes in LiF-based electrolyte solution with anion receptors, T.
Fukutsuka, T. Nakagawa, K. Miyazaki, and T. Abe, Journal
of Power Sources, 306, 753-757 (2016).
(87) Electrochemical Intercalation of Bis(fluorosulfonyl)amide
Anion into Graphite, T. Fukutsuka, F. Yamane, K. Miyazaki,
and T. Abe, Journal of the Electrochemical Society, 163,
A499-A503 (2016).
(88) Enhanced resistance to oxidative decomposition of aqueous
electrolytes for aqueous lithium-ion batteries, K. Miyazaki, T.
Shimada, S. Ito, Y. Yokoyama, T. Fukutsuka, and T. Abe, Chemical
Communications, 52, 4979-4982 (2016).
(89) Ion Transport in Organic Electrolyte Solution through the
Pore Channels of Anodic Nanoporous Alumina Membranes, T.
Fukutsuka, K. Koyamada, S. Maruyama, K. Miyazaki, and T. Abe,
Electrochimica Acta, 199, 380-387 (2016).
(90) Suppression of Co-Intercalation Reaction of Propylene Carbonate
and Lithium Ion into Graphite Negative Electrode by Addition of
Diglyme, H.-Y. Song, T. Fukutsuka, K. Miyazaki, and T. Abe,
Journal of the Electrochemical Society, 163
, A1265-A1269 (2016).
(91) Investigation of the Surface Film Forming Process on
Nongraphitizable Carbon Electrodes by In-situ Atomic Force
Microscopy, H.-Y. Song, T. Fukutsuka, K. Miyazaki, and T.
Abe, Electrochemistry, 84, 769-771
(2016).
(92) Effect of the Addition of Bivalent Ions on Electrochemical
Lithium-Ion Intercalation at Graphite Electrodes, S. Takeuchi, R.
Kokumai, S. Nagata, T. Fukutsuka, K. Miyazaki, and T. Abe, Journal
of the Electrochemical Society, 163 ,
A1693-A1696 (2016).
(93) Influence of surfactants as additives to electrolyte solutions
on zinc electrodeposition and potential oscillation behavior, K.
Miyazaki, A. Nakata, Y.-S. Lee, T. Fukutsuka, and T. Abe, Journal
of Applied Electrochemistry , 46 ,
1067-1073 (2016).
(94) Solid electrolyte interphase formation in propylene
carbonate-based electrolyte solutions for lithium-ion batteries
based on the Lewis basicity of the co-solvent and counter anion,
H.-Y. Song, T. Fukutsuka, K. Miyazaki, and T. Abe, Journal
of Applied Electrochemistry, 46 , 1099-1107
(2016).
(95) Electrochemical Behavior of Spinel Lithium Titanate in Ionic
Liquid/Water Bilayer Electrolyte, T. Fukutsuka, H. Miwa, K.
Miyazaki, and T. Abe, Journal of the Electrochemical Society,
163 , A2497-A2500 (2016).
(96) In situ Raman investigation of electrolyte solutions
in the vicinity of graphite negative electrodes, H.-Y. Song, T.
Fukutsuka, K. Miyazaki, and Takeshi Abe, Physical
Chemistry Chemical Physics, 18 ,
27486-27492 (2016).
(97) In Situ AFM Observation of Surface Morphology of Highly
Oriented Pyrolytic Graphite in Propylene Carbonate-Based Electrolyte
Solutions Containing Lithium and Bivalent Cations, T. Fukutsuka,
R. Kokumai, H.-Y. Song, S. Takeuchi, K. Miyazaki, and T. Abe, Journal
of the Electrochemical Society, 164,
A48-A53 (2017).
(98) Investigation of the surface state of LiCoO2
thin-film electrodes using a redox reaction of ferrocene, J.
Inamoto, T. Fukutsuka, K. Miyazaki, and T. Abe, Journal
of the Electrochemical Society, 164,
A555-A559 (2017).
(99) Strontium cobalt oxychlorides: enhanced electrocatalysts for
oxygen reduction and evolution reactions, Y. Miyahara, K. Miyazaki,
T. Fukutsuka , and T. Abe, Chemical Communications,
53, 2713-2716 (2017).
(100) Development of New Electronic Conductivity Measurement Method
for Lithium-ion Battery Electrode-slurry, M. Takeno, T.
Fukutsuka, K. Miyazaki, and T. Abe, Chemistry Letters
, 46, 892-894 (2017).
(101) Investigation on Surface-Film Formation Behavior of LiMn2O4
Thin-Film Electrodes in LiClO4/Propylene Carbonate, J.
Inamoto, T. Fukutsuka, K. Miyazaki, and T. Abe, ChemistrySelect
, 2, 2895-2900 (2017).
(102) Influence of carbonaceous materials on electronic
conduction in electrode-slurry, M. Takeno, T. Fukutsuka, K.
Miyazaki, and T. Abe, Carbon, 122,
202-206 (2017).
(103) Acceptor-type hydroxide graphite intercalation compounds
electrochemically formed in high ionic strength solutions, K.
Miyazaki, A. Iizuka, K. Mikata, T. Fukutsuka, and T. Abe, Chemical
Communications, 53, 10034-10037 (2017).
(104) Insight into the state of the ZrO2 coating on a
LiCoO2 thin-film electrode using the ferrocene redox
reaction, J. Inamoto, T. Fukutsuka, K. Miyazaki, and T. Abe,
Journal of the Applied Electrochemistry, 47,
1203-1211 (2017).
(105) Direct measurements of local current distributions on
electrodes covered with thin liquid electrolyte films, A. Ikezawa,
K. Miyazaki, T. Fukutsuka, and T. Abe, Electrochemistry
Communications, 84, 53-56 (2017).
(106) Local Current Distributions on Electrodes Covered with
Anion-exchange Films, A. Ikezawa, K. Miyazaki, T. Fukutsuka,
and T. Abe, Chemistry Letters, 47,
171-174 (2018).
(107) Investigation of Electronic Resistance in Lithium-ion
Batteries by AC Impedance Spectroscopy, M. Takeno, T. Fukutsuka,
K. Miyazaki, and T. Abe, Journal of the Electrochemical Society
, 164, A3862-A3867 (2017).
(108) Lithium-ion intercalation and deintercalation behaviors of
graphitized carbon nanospheres, S. Maruyama, T. Fukutsuka,
K. Miyazaki, Y. Abe, N. Yoshizawa, and T. Abe, Journal of
Materials Chemistry A, 6, 1128-1137 (2018).
(109) Observation of the intercalation of dimethyl
sulfoxide-solvated lithium ion into graphite and decomposition of
the ternary graphite intercalation compound using in situ
Raman spectroscopy, S. Maruyama, T. Fukutsuka, K. Miyazaki,
and T. Abe, Electrochimica Acta, 265,
41-46 (2018).
(110) Lithium-Ion Intercalation by Calcium-Ion Addition in Propylene
Carbonate-Trimethyl Phosphate Electrolyte Solution, S. Takeuchi, T.
Fukutsuka, K. Miyazaki, and T. Abe, Journal of the
Electrochemical Society , 165, A349-A354
(2018).
(111) Electrochemical Behavior of Graphitized Carbon Nanospheres in
a Propylene Carbonate-Based Electrolyte Solution, S. Maruyama, T.
Fukutsuka, K. Miyazaki, Y. Abe, N. Yoshizawa, and T. Abe, Journal
of the Electrochemical Society, 165,
A2247-A2254 (2018).
(112) Characterization of the Interface between LiMn2O4
Thin-film Electrode and LiBOB-based Electrolyte Solution by Redox
Reaction of Ferrocene, J. Inamoto, T. Fukutsuka, K.
Miyazaki, and T. Abe, Electrochemistry, 86
, 254-259 (2018).
(113) Origin of the Electrochemical Stability of Aqueous
Concentrated Electrolyte Solutions, Y. Yokoyama, T. Fukutsuka,
K. Miyazaki, and T. Abe, Journal of the Electrochemical Society,
165, A3299-A3303 (2018).
(114) Investigation of electrochemical sodium-ion intercalation
behavior into graphite-based electrodes, Y. Kondo, T. Fukutsuka,
K. Miyazaki, Y. Miyahara, and T. Abe, Journal of the
Electrochemical Society, 166, A5323-A5327
(2019).
(115) Electrochemical intercalation of bis(fluorosulfonyl)amide
anions into graphite from aqueous solutions, Y. Kondo, Y. Miyahara,
T. Fukutsuka, K. Miyazaki, and T. Abe, Electrochemistry
Communications, 100, 26-29 (2019).
(116) Sodium-ion intercalation behavior of graphitized carbon
nanospheres covered with basal plane, Y. Kondo, Y. Miyahara, T.
Fukutsuka, K. Miyazaki, and T. Abe, Chemistry Letters,
48, 799-801 (2019).
(117) In situ Raman spectroscopic analysis of solvent
co-intercalation behavior into a solid electrolyte
interphase-covered graphite electrode, S. Maruyama, T. Fukutsuka,
K. Miyazaki, and T. Abe, Journal of the Applied
Electrochemistry, 49, 639-646 (2019).
(118) In situ Measurement of Local pH at Working Electrodes in
Neutral pH Solutions by the Rotating Ring-Disk Electrode Technique,
Y. Yokoyama, K. Miyazaki, Y. Miyahara, T. Fukutsuka, and T.
Abe, ChemElectroChem, 6, 4750-4756
(2019).
(119)
In Situ Local pH Measurements with Hydrated Iridium Oxide Ring
Electrodes in Neutral pH Aqueous Solutions, Y. Yokoyama, K.
Miyazaki, Y. Kondo, Y. Miyahara, T. Fukutsuka, and T. Abe, Chemistry
Letters, 49, 195-198 (2020).
(120)
Lithium-ion Transfer Kinetics through Solid Electrolyte Interphase
on Graphite Electrodes, A. Inoo, T. Fukutsuka, Y. Miyahara,
K. Miyazaki, and T. Abe, Electrochemistry, 88,
69-73 (2020).
(121)
Solvated Lithium Ion Intercalation Behavior of Graphitized Carbon
Nanospheres, S. Maruyama, T. Fukutsuka, K. Miyazaki, and T.
Abe, Electrochemistry, 88, 79-82 (2020).
(122)
Concentrated Sodium Bis(fluorosulfonyl)amide Aqueous Electrolyte
Solutions for Electric Double-layer Capacitors, Y. Kondo, K.
Miyazaki, Y. Yokoyama, Y. Miyahara, T. Fukutsuka, and T.
Abe, Electrochemistry, 88, 91-93 (2020).
(123)
Effect of Electrolyte Additives on Kinetic Parameters of Lithium-ion
Transfer Reactions at Electrolyte/Graphite Interface, A. Inoo, T.
Fukutsuka, Y. Miyahara, Y. Kondo, Y. Yokoyama, K. Miyazaki,
and T. Abe, Electrochemistry, 88,
365-368 (2020).
(124)
Charge-transfer kinetics of the solid-electrolyte interphase on Li4Ti5O12
thin-film electrodes, R. N. Nasara, W. Ma, Y. Kondo, K. Miyazaki, Y.
Miyahara, T. Fukutsuka, C. Lin, S. Lin, and T. Abe, ChemSusChem,
13, 4041-4050 (2020).
(125)
Dual-Site Catalysis of Fe-Incorporated Oxychlorides as Oxygen
Evolution Electrocatalysts, Y. Miyahara, T. Fukutsuka, T.
Abe, and K. Miyazaki, Chemistry of Materials, 32,
8195-8202 (2020).
(126)
Electrochemical Surface Analysis of LiMn2O4
Thin-film Electrodes in LiPF6/Propylene Carbonate at Room
and Elevated Temperatures, J. Inamoto, T. Fukutsuka, K.
Miyazaki, and T. Abe, Electrochemistry, 89,
19-24 (2021).
(127) Kinetic properties of sodium-ion transfer at the interface between graphitic materials and organic electrolyte solutions, Y. Kondo, T. Fukutsuka, Y. Yokoyama, Y. Miyahara, K. Miyazaki, and T. Abe, Journal of Applied Electrochemistry, 51, 629-638 (2021).
(128)
Electrochemical properties of surface-modified hard carbon
electrodes for lithium-ion batteries, R. N. Nasara, W. Ma, S.
Tsujimoto, Y. Inoue, Y. Yokoyama, Y. Kondo, K. Miyazaki, Y.
Miyahara, T. Fukutsuka, S. Lin, and T. Abe, Electrochimica
Acta, 379, 138175 (2021).
(129) Molecular Structural Influence of Glymes on Co-Intercalation Behavior of Solvated Li+ in Graphite Electrodes, A. Inoo, T. Fukutsuka, Y. Miyahara, K. Kondo, Y. Yokoyama, K. Miyazaki, and T. Abe, Journal of the Electrochemical Society, 168, 060525 (2021).
(130)
Sodium/Lithium-Ion Transfer Reaction at the Interface between Low
Crystallized Carbon Nanosphere and Organic Electrolytes, Y. Kondo, T.
Fukutsuka, Y. Yokoyama, Y. Miyahara, K. Miyazaki, and T. Abe,
ACS Omega, 6, 18737 (2021).
(131)
Relation between Mixing Processes and Properties of Lithium-ion
battery Electrode-slurry, M. Takeno, S. Katakura, K. Miyazaki, T.
Abe, and T. Fukutsuka, Electrochemistry, 89,
585-589 (2021).
(132) Impact of Hydrogen Peroxide on Carbon Corrosion in Aqueous KOH Solution, A. Ikezawa, K. Miyazaki, T. Fukutsuka, and T. Abe, Electrochemistry, 90, 017011 (2022).
(133) Kinetics of Interfacial Lithium-ion Transfer between a Graphite Negative Electrode and a Li2S-P2S5 Glassy Solid Electrolyte, D. Yu, M. Huang, Y. Miyahara, K. Miyazaki, A. Hayashi, M. Tatsumisago, T. Abe, and T. Fukutsuka, Electrochemistry, 90, 037003 (2022).
(134)
Effects of Solvation Structures on the Co-intercalation Suppression
Ability of the Solid Electrolyte Interphase Formed on Graphite
Electrodes, A. Inoo, T. Fukutsuka, Y. Miyahara, Y. Kondo, Y.
Yokoyama, K. Miyazaki, and T. Abe, Chemistry Letters, 51,
618 (2022).
(135) Analysis of the Intermediate States of an Electrode slurry by Electronic Conductivity Measurements, M. Takeno, S. Katakura, K. Miyazaki, T. Abe, and T. Fukutsuka, Carbon Reports, 2, 91 (2023).
総説、解説
(1) 新規黒鉛層間化合物の合成とエネルギー貯蔵, 松尾吉晃, 福塚友和, 杉江他曾宏, 表面, 42
, 372-382 (2004).
(2) 酸化黒鉛層間化合物の合成と性質, 松尾吉晃, 福塚友和, 杉江他曾宏, 炭素, 222
, 124-129 (2006).
(3) プラズマCVD法による炭素薄膜作製とエネルギーデバイスへの展開, 福塚友和, 松尾吉晃, 杉江他曾宏,
安部武志, 小久見善八, 炭素, 230 , 352-361 (2007).
(4) 固体高分子形燃料電池用金属セパレータ材料の開発, 杉江他曾宏, 福塚友和, 松尾吉晃, 燃料電池, 8
, 125-130 (2008).
(5) 固体高分子型燃料電池, 内本喜晴, 福塚友和, 未来材料, 12
, 49-55 (2008).
(6) 各種気相析出法による炭素系薄膜材料の作製と機能デバイスへの応用, 大澤善美, 川口雅之, 福塚友和,
炭素, 245 , 211-221 (2010).
(7) モルフォロジーから見たリチウムイオン電池用ナノカーボン負極, 福塚友和, 丸山翔平, 宮崎晃平,
安部武志, 炭素, 255 , 274-279 (2012).
(8) 金属−空気二次電池のための亜鉛負極の研究開発, 宮崎晃平, 李柔信, 福塚友和, 安部武志,
電池技術, 25 , 159-164 (2013).
(9) マグネシウム金属二次電池用電解液の開発, 福塚友和, 宮崎晃平, 安部武志, 内本喜晴,
月刊ファインケミカル, 43 , 42-47 (2014).
(10) マグネシウム金属二次電池の現状と課題, 福塚友和, 宮崎晃平, 安部武志, セラミックス,
49 , 964-967 (2014).
(11) 交流インピーダンス法を用いた多孔質電極の導電ネットワーク構造の解析, 武野光弘, 宮崎晃平, 福塚友和,
安部武志, 電池技術, 27 , 74-82 (2015).
(12) アニオンレセプター含有電解液を用いたリチウムイオン電池の高エネルギー密度化, 福塚友和, 安部武志, Electrochemistry,
85 , 479-483 (2017).
(13) リチウムイオン電池多孔性電極内でのイオン輸送挙動, 福塚友和, 宮崎晃平, 安部武志, 電池技術, 29
, 22-32 (2017).
(14) 黒鉛負極へ適合可能な炭酸プロピレン系電解液の研究, 福塚友和, 炭素, 283,
108-117 (2018). 学術賞受賞レビュー
(15) 多価カチオン系電池の現状, 福塚友和 , 宮原雄人, 宮崎晃平, 安部武志, えねるみくす,
97 , 344-351 (2018).
(16) 負極材, 福塚友和, 安部武志, 工業材料, 66 ,
36-41 (2018).
(17) 亜鉛空気二次電池の課題と展望, 宮崎晃平, 宮原雄人, 福塚友和, 安部武志, 電池技術,
30, 208-214 (2018).
(18) ポーラスアルミナメンブレン中のイオン移動現象, 福塚友和, 宮原雄人, 宮崎晃平, 安部武志, 表
面技術, 70 , 31-34 (2019).
(19) 黒鉛負極/電解液界面でのリチウムイオン移動, 福塚友和,宮原雄人,宮崎晃平,安部武志, 炭素, 291, 9-14 (2020).
(20) 多価カチオン系蓄電池の最新開発動向, 福塚友和,嵯峨根史洋, ペトロテック, 44, 427-432 (2021).
(21) Electrochemical Impedance Spectroscopy Part 1: Fundamentals, K. Ariyoshi, Z. Siroma, A. Mineshige, M. Takeno, T. Fukutsuka, T. Abe, and S. Uchida, Electrochemistry, 90, 102007 (2022).
(22) Electrochemical Impedance Spectroscopy Part 2: Applications, K. Ariyoshi, A. Mineshige, M. Takeno, T. Fukutsuka, T. Abe, S. Uchida, and Z. Siroma, Electrochemistry, 90, 102008 (2022).
(23)
リチウムイオン電池性能を向上させるカーボン負極材料, 福塚友和,安部武志, 電気化学, 91,
24-29 (2023).
書籍
(1) 次世代自動車用リチウムイオン電池の材料開発(監修:金村聖志、分担), 福塚友和, 安部武志,
シーエムシー出版, 第2章第2節, 21-30 (2008).
(2) 次世代自動車用リチウムイオン電池の材料開発(監修:金村聖志、分担), 福塚友和, 内本喜晴,
シーエムシー出版, 第3章第1節, 170-184 (2008).
(3) 図解革新型蓄電池のすべて(監修:小久見善八、西尾晃治、分担), 福塚友和 , 安部武志, 工業調査会,
第3章第1節, 78-87 (2010).
(4) 第6版 電気化学便覧(電気化学会編、分担), 福塚友和, 丸善出版, 第8章, 330-331
(2013).
(5) 電気化学/インピーダンス測定のノウハウと正しいデータ解釈(分担), 福塚友和, 宮崎晃平,
技術情報協会, 第3章第1節[6], 119-122 (2013).
(6) 蓄電デバイスの今後の展開と電解液の研究開発(監修:鳶島真一、分担), 福塚友和, 宮崎晃平,
安部武志, 内本喜晴, シーエムシー出版, 第3編第4章, 258-266 (2014).
(7) ポストリチウムに向けた革新的二次電池の材料開発(監修:境 哲男、分担), 宮崎晃平, 宮原雄人, 福塚友和,
安部武志, NTS, 第6章第6節, 285-292 (2018).
(8) 電気化学・インピーダンス測定のデータ解析手法と事例集(分担), 福塚友和, 宮原雄人, 宮崎晃平,
安部武志, 技術情報協会, 第3章第8節, 179-187 (2018).
(9)
リチウムイオン二次電池用炭素系負極材の開発動向(分担), 福塚友和, 安部武志, シーエムシー出版, 第I編第1章,
3-13 (2019).
(10) 全固体電池の界面抵抗低減と作製プロセス、評価技術(分担), 福塚友和, 安部武志, 技術情報協会, 第10章第14節, 417-423 (2020).
(11)
ポストリチウムイオン二次電池開発(監修:櫻井庸司、分担), 嵯峨根史洋, 福塚友和, NTS, 第1編第3章,
43-56 (2023).
Doctoral Thesis
Studies on Preparation of Carbonaceous Thin Films and Their
Electrochemical Properties
(炭素薄膜の作製とその電気化学特性に関する研究)
Kyoto University 2005/3 Dr. Eng.
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