2017年 環境物質工学科 学術論文等

ᵐᵎᵏᵕ ࠰ᴾ ࿢ؾཋឋ߻ܖᅹᴾ

ܖᘐᛯ૨ሁᴾ

ཎ

ཎⴭㄽᩥ㸦ᰝㄞ࠶ࡾ㸧

1. G. Sajiki, Y. Benino, C. Oki, K. Ohara, H. Okano, T. Nanba㸭Structural Analyses and Reverse Monte Carlo Modeling of Niobium Oxide Amorphous Film Prepared by Sputtering Method㸭J. Ceram. Soc. Japan, 125 (10) 760-765.㸭2017 ᖺ

2. M. Miyake, S. Matsumoto, S. Nishimoto, Y. Kameshima㸭Performance of Ni0.8-xCu0.2Mx (M = Fe and Co) Alloy-based Cermet Anodes for Intermediate-temperature Solid Oxide Fuel Cells Fueled with Syngas㸭J. Ceram. Soc. Japan, 125㸭2017 ᖺ

3. M. Miyake, M. Iwami, K. Goto, K. Iwamoto, K. Morimoto, M. Shiraishi, K. Takatori, M. Takeuchi, S. Nishimoto, Y. Kameshima㸭Intermediate-temperature Solid Oxide Fuel Cell Employing Reformed Effective Biogas: Power Generation and Inhibition of Carbon Deposition㸭J. Power Sources, 340㸭2017 ᖺ

4. H. Miyake, T. Tajima, Y. Takaguchi 㸭 Thiophene Derivatives Bearing Ferrocenylthiocarbonyl Groups㸭Chem. Lett. 46, 48-50㸭2017 ᖺ

5. T. Tajima, S. Yamamoto, Y. Sakamoto, S. Takagi, T. Nakaya, Y. Takaguchi, A. Igashira-Kamiyama, N. Yoshinari, T. Konno 㸭 Ligand Exchange Reaction of (Me4N)4[Cd10S4(SPh)16] with Diphenyl Diselenide㸭Bull. Chem. Soc. Jpn. 90, 384-386㸭 2017 ᖺ

6. K. Ishimoto, T. Tajima, H. Miyake, M. Yamagami, W. Kurashige, Y. Negishi, Y. Takaguchi 㸭 Photo-induced H2 Evolution from Water via the Dissociation of Excitons in Water-Dispersible Single-Walled Carbon Nanotube Sensitizers㸭Chem. Comm., in press, DOI:10.1039/C7CC07194A㸭2017 ᖺ

7. S. Nishimura, T. Tajima, T. Hasegawa, Y. Takaguchi, Y. Oaki, H. Imai㸭Synthesis of poly(amidoamine) dendrimer having a 1,10-bis(decyloxy)decane core and its use in fabrication of carbon nanotube/calcium carbonate hybrids through biomimetic mineralization㸭Can. J. Chem. 95, 935-941.㸭2017 ᖺ

8. K. Kurniawan, T. Tajima, Y. Kubo, H. Miyake, W. Kurashige, Y. Negishi, Y. Takaguchi㸭 Incorporating a TiOx Shell in Single-Walled Carbon Nanotube/Fullerodendron Coaxial Nanowires: Increasing the Photocatalytic Evolution of H2 from Water under Irradiation with Visible Light 㸭RSC Advances 7, 31767-31770.㸭2017 ᖺ

9. K. Kubo, T. Tajima, H. Shirai, T. Nishihama, Y. Takaguchi 㸭 Self-assembly and Fluorescence Properties of [60]fullerene-Pentacene Mono Adducts㸭ChemstrySelects 8, 2452-2456㸭2017 ᖺ

10. N. Murakami, Y. Tango, H. Miyake, T. Tajima, Y. Nishina, W. Kurashige, Y. Negishi, Y. Takaguchi 㸭 SWCNT Photocatalyst for Hydrogen Production from Water upon Photoexcitation of (8,3)SWCNT at 680-nm Light㸭Sci. Rep. 2017, 7, 43445㸭2017 ᖺ 11. L. Pop, N. Kurokawa, H. Ebata, K. Tomizawa, T. Tajima, M. Saito㸭Synthesis and

Structures of Sterically Encumbered Group 14 Monolithio Compounds and Unexpected Differences in Their Reactivity 㸭 Eur. J. Inorg. Chem., in press, DOI: 10.1002/ejic.201700945㸭2017 ᖺ

12. K. Ishimoto, T. Tajima, H. Miyake, M. Yamagami, W. Kurashige, Y. Negishi, Y. Takaguchi 㸭 Photo-induced H2 Evolution from Water via the Dissociation of Excitons in Water-Dispersible Single-Walled Carbon Nanotube Sensitizers 㸭 Chemical Communications, in press, DOI:10.1039/C7CC07194A㸭2017 ᖺ

13. H. Nakayama, N. Adachi, H. Atarashi, T. Uchida, S. Yamazaki, K. Kimura㸭Size Control of Aromatic Polyamide Hollow Spheres Prepared by Reaction-induced Phase Separation㸭 Polymer 111, 239-243㸭2017 ᖺ

14. M. Nakanishi, Md. Azhar Uddin, Y. Kato, Y. Nishina, A.M.Hapipi㸭Effect of Preparation Method on the Properties of Cobalt Supported E-Zeolite Catalysts for Fischer-Tropsch Synthesis㸭Catalyst Today, in press㸭2017 ᖺ

15. G. Takeuchi, H. Tamaki, Md. A. Uddin, Y. Kato, E. Kiso, K. Takahashi㸭Mutual Effect of Steelmaking Slag Layer Depth and Diameter on Alkali Elution Rate in Open Channel Vessels with Straitened Seawater Flow㸭J. Sustain Metall. 3, 459-468㸭2017 ᖺ

16. T. Okuno, Md. A. Uddin, Y. Kato, S-B. Lee, Y-H. Kim㸭Effect of Particle Penetration Depth on Solid/Liquid Mass Transfer Rate by Particle Blowing Technique㸭ISIJ Int. 57, 1902-1910㸭2017 ᖺ

17. S. Sumitomo, H. Koizumi, Md. A. Uddin, Y. Kato㸭Comparison of Dispersion Behavior of Agglomeration Particles in Liquid between Ultrasonic Irradiation and Mechanical Stirring 㸭Ultrasonics-Sonochemistry in press㸭2017 ᖺ

18. S. Sumitomo, K. Yoshitomi, Md. A. Uddin, Y. Kato㸭Comparison of Agglomeration Behavior of Fine Particles in Liquid among Various Mixing Operations㸭ISIJ Int. in press 㸭2017 ᖺ

19. A. M. Hapipi, Md. A. Uddin, Y. Kato㸭Carbonization of Sugarcane Bagasse and heat transfer property by pyrolysis in Superheated Steam and Nitrogen Atmosphere,㸭᪥ᮏ࢚ࢿ ࣝࢠ࣮Ꮫ఍ㄅ, in press㸭2017 ᖺ

20. R. Imamura, N. Murata, T. Shimanouchi, K. Yamashita, M. Fukuzawa, M. Noda㸭A Label-Free Fluorescent Array Sensor Utilizing Liposome Encapsulating Calcein for Discriminating Target Proteins by Principal Component Analysis㸭Sensors 17, 1630㸭 2017 ᖺ

21. S. Fukuma, T. Shimanouchi, K. Hayashi, Y. Kimura㸭Effect of Protein Orientation Pattern to Vesicle Membranes for Protein-Induced Calcein Leakage Behavior㸭Chem. Lett. 46,

1036-1039㸭2017 ᖺ

22. K. Hayashi, H. Iwai, T. Kamei, K. Iwamoto, T. Shimanouchi, S. Fujita, H. Nakamura, H. Umakoshi 㸭 Tailor-made Drug Carrier: Comparison of Formation-dependent Physicochemical Properties within Self-assembled Aggregates for an Optimal Drug Carrier, 㸭Colloids and Surfaces B, 152, 269-276㸭2017 ᖺ

23. T. Shimanouchi, K. Yamamoto, S. Fujioka, K. Terasaka, Y. Kimura㸭Characterization and Correlation Study of Biphasic Water/Organic Solvent System of Slug Flows Formed in Mirocapillary㸭Multiscale Multiphase Process Engineering, 3, 255-260㸭2017 ᖺ

24. T. Shimanouchi, A. Kondo, S. Fujioka, K. Terasaka, Y. Kimura㸭Mechanistic Study on Emulsification Assisted by Subcritical Water: Formation of Finely Dispersed Emulsion㸭 Multiscale Multiphase Process Engineering, 3, 310-313㸭2017 ᖺ

25. T. Shimanouchi, M. Tanaka, Y. Kimura㸭2D Dynamics of Protein Assemblies on Lipid Membranes㸭Proc. 11th International Conference on Separation Science and Technology, GO-01㸭2017 ᖺ

26. T. Shimanouchi, S. Fukuma, Y. Kimura㸭High Sensitive Detection of Amyloid Beta Using The Quartz Crystal Microbalance Method Combined with The Immobilization of Lipid Membranes㸭Proc. 11th International Conference on Separation Science and Technology, GP-07㸭2017 ᖺ

⥲ ⥲ㄝ➼

1. ᱞᩜ๛, ᒸ㔝ᐶ, ⣚㔝Ᏻᙪ, 㞴Ἴᚨ㑻㸭ᨺᑕගࢆ฼⏝ࡋࡓ㠀ᬗ㉁㓟໬ࢽ࢜ࣈⷧ⭷ࡢ ᵓ㐀ゎᯒ㸭ࢭ࣑ࣛࢵࢡࢫ 52(5), 362-364, 2017㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍㸭2017 ᖺ 2. 㞴Ἴᚨ㑻, ᓮ⏣┿୍, ⣚㔝Ᏻᙪ㸭࢞ࣛࢫࡢᵓ㐀࡜⤖ྜ≧ែ㸭Journal of the Society of

Inorganic Materials Japan, 24, 339-344, 2017㸭↓ᶵ࣐ࢸࣜ࢔ࣝᏛ఍㸭2017 ᖺ

3. 㧗ཱྀ㇏㸭࣮࢝࣎ࣥࢼࣀࢳ࣮ࣗࣈࢆගゐ፹࡜ࡋ࡚฼⏝ࡍࡿࡓࡵࡢ⏺㠃ᵓ㐀ไᚚ㸭C & I Commun, 42, 22-23 (2017).㸭᪥ᮏ໬Ꮫ఍ ࢥࣟ࢖ࢻ࠾ࡼࡧ⏺㠃໬Ꮫ㒊఍㸭2017 ᖺ 4. ᓥෆᑑᚨ㸪⚟㛫᪩⣖㸪ᮌᮧᖾᩗ㸭࣐࢖ࢡࣟ࢟ࣕࣆ࣮ࣛࣜᆺỈ⇕཯ᛂศ㞳⿦⨨ࡢᛂ⏝ ᢏ⾡㸭ศ㞳ᢏ⾡఍⦅ࠕศ㞳ᢏ⾡ࡢࢩ࣮ࢬ࡜ࣛ࢖ࢭࣥࢫᢏ⾡ࡢᐇ⏝໬ࠖ㸭2017 ᖺ 5. 㧗ཱྀ㇏㸪⏣ᔱᬛஅ㸭ኴ㝧ග࢚ࢿࣝࢠ࣮࡛Ỉ࠿ࡽỈ⣲ࢆ〇㐀ࡍࡿேᕤගྜᡂ⏝ගゐ፹ ᪂ᢏ⾡㸭ᒸᒣ኱Ꮫ⎔ቃሗ࿌᭩ p16㸭2017 ᖺ

6. K. Kurniawan, N. Murakami, Y. Tango, T. Izawa, K. Nishikawa, K. Watanabe, H. Miyake, T. Tajima, Y. Takaguchi㸭H2-evolving SWCNT Photocatalyst for Effective Use of Solar Energy㸭Proceedings of the Nature Research Society,1, 01004.㸭2017 ᖺ

7. N. Murakami, Y. Tango, H. Miyake, T. Tajima, Y. Nishina, W. Kurashige, Y. Negishi, Y. Takaguchi㸭Innovative Carbon Nanotube Photocatalytic Materials for Efficient Solar Energy Conversion and Hydrogen Production (Research Highlights)㸭Okayama Univ. e-Bulletin Vol. 19, 14-17.㸭2017 ᖺ

8. ⚟㛫᪩⣖㸭࣏ࣜ࢔ࢽࣜࣥࡢ㓝⣲ⓗ㔜ྜ཯ᛂ࡟୚࠼ࡿᙳ㡪㹼⬡㉁ᖹ㠃⭷࡜࣋ࢩࢡࣝ ⭷ࡢẚ㍑㹼㸭⭷㸭2017 ᖺ

ᣍ ᣍᚅㅮ₇ࡲࡓࡣᇶㄪㅮ₇ 1. 㞴Ἴᚨ㑻㸭࢞ࣛࢫࡢᇶ♏ⓗᛶ㉁࠿ࡽᛂ⏝ࡲ࡛㸫ᙜ◊✲ᐊࡢ◊✲஦౛ࢆ㏻ࡋ࡚㸫㸭 ⏘ᴗᢏ⾡㐃ᦠ᥎㐍఍㆟࣭࢞ࣛࢫᢏ⾡ศ⛉఍㸭㫽ྲྀ㸭2017 ᖺ 10 ᭶ 2. 㞴Ἴᚨ㑻㸭ㅮ⩏㸯㸸ࢭ࣑ࣛࢵࢡࢫࡢᴫㄽ㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍୰ᅜᅄᅜᨭ㒊࣭ࢭ ࣑ࣛࢵࢡࢫࡢᇶ♏Ꮫၥ◊ಟ఍㸭ᒸᒣ㸭2017 ᖺ 11 ᭶ 3. ⣚㔝Ᏻᙪ㸭ㅮ⩏㸱㸸࢞ࣛࢫࡢ≉ᛶ㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍୰ᅜᅄᅜᨭ㒊࣭ࢭ࣑ࣛࢵ ࢡࢫࡢᇶ♏Ꮫၥ◊ಟ఍㸭ᒸᒣ㸭2017 ᖺ 11 ᭶

4. Y. Takaguchi㸭H2-evolving SWCNT Photocatalysts for Effective Use of Solar Energy㸭 Nano-Micro Conference 2017㸭Shanghai, Chaina㸭2017 ᖺ 6 ᭶

5. 㧗ཱྀ㇏㸭ኴ㝧ගࢆ฼⏝ࡋࡓỈ⣲〇㐀ࢆྍ⬟࡜ࡍࡿ࣮࢝࣎ࣥࢼࣀࢳ࣮ࣗࣈගゐ፹ࡢ 㛤Ⓨ㸭㏆␥኱Ꮫ኱Ꮫ㝔⥲ྜ⌮ᕤᏛ◊✲⛉ᖹᡂ 29 ᖺᗘࠕᏛ㝿◊✲࣭ࠖࠕㄢእࢭ࣑ࢼ࣮ࠖ 㸭2017 ᖺ 11 ᭶

6. 㧗ཱྀ㇏㸭ኴ㝧ගࡢ᭷ຠ฼⏝ࢆᣦྥࡋࡓ࣮࢝࣎ࣥࢼࣀࢳ࣮ࣗࣈගゐ፹ࡢ㛤Ⓨ㸭᪥ᮏ ໬Ꮫ఍ᮾᾏᨭ㒊ㅮ₇఍㸭㛗㔝㸭2017 ᖺ 11 ᭶

7. Y. Takaguchi㸭SWCNT Photocatalysts for Hydrogen Evolution from Water㸭KJFP2017㸭 Inha UniversityࠊKorea㸭2017 ᖺ 10 ᭶

8. Y. Takaguchi㸭Single-walled Carbon Nanotube (SWCNT) Photocatalyst for Hydrogen Production from Water㸭GCC-2017㸭Shanghai, Chaina㸭2017 ᖺ 10 ᭶

9. 㧗ཱྀ㇏㸭SWCNT Photocatalysts for Hydrogen Evolution from Water㸭International Mini-Symposium on Photocatalytic Systems㸭Ube, Japan㸭2017 ᖺ 9 ᭶

10. T. Shimanouchi㸭Accumulation of amyloidgenic protein on the variety types of lipid membranes㸭International Seminar on Biophysics and Chemical Biology of Biomembrane and Lipid Bilayers㸭Osaka, Japan㸭2017 ᖺ 10 ᭶

◊✲ㅮ₇࣭Ⓨ⾲ 1. ሷ⏣ᑗ኱㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭SnO-ZnO-P2O5⣔࢞ࣛࢫࡢᵓ㐀࡜Ⓨග ≉ᛶ㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍ࢭ࣑ࣛࢵࢡࢫᇶ♏⛉Ꮫウㄽ఍㸭ᒸᒣ㸭2017 ᖺ 1 ᭶ 2. Ọ஭⚟ே㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭ᅵተ୰ࡢࢭࢩ࣒࢘ࡢ᥹Ⓨᣲື࡟ᑐࡍࡿ ᨭ㓄ᅉᏊࡢ᥈⣴㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍ࢭ࣑ࣛࢵࢡࢫᇶ♏⛉Ꮫウㄽ఍㸭ᒸᒣ㸭 2017 ᖺ 1 ᭶ 3. ⳥ᕝᗣ୍㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭BPI ࢞ࣛࢫᅛ໬యࡢศᏊືຊᏛࢩ࣑ࣗ ࣮ࣞࢩࣙࣥࢆ⏝࠸ࡓᵓ㐀ゎᯒ㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍ࢭ࣑ࣛࢵࢡࢫᇶ♏⛉Ꮫウㄽ ఍㸭ᒸᒣ㸭2017 ᖺ 1 ᭶ 4. ᑠᯘᙬ⳹㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭ࣜࣥ㓟ሷ࢞ࣛࢫࡢᅽ⦰ኚᙧ࡟ࡼࡿຊᏛ ⓗ␗᪉ᛶ㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍ᖺ఍㸭ᮾி㸭2017 ᖺ 3 ᭶ 5. ⣚㔝Ᏻᙪ㸪ᯇᮏಟ἞㸪ᶫᮏⱥᶞ㸪㞴Ἴᚨ㑻㸪㧗⏣₶㸭⨨᥮ඖ⣲ࢆྵࡴ 2-line ࣇ࢙ࣜ ࣁ࢖ࢻࣛ࢖ࢺࡢ㠀ᬗ㉁ᵓ㐀ゎᯒ㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍⛅Ꮨࢩ࣏ࣥࢪ࣒࢘㸭⚄ᡞ 㸭2017 ᖺ 9 ᭶ 6. ඖୗ▱Ꮨ㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸪ᑠཎ┿ྖ㸭X ⥺␗ᖖᩓ஘ἲ࡟ࡼࡿ 2 ᡂ ศ⣔ࢸࣝࣛ࢖ࢺ࢞ࣛࢫࡢᵓ㐀ゎᯒ㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍⛅Ꮨࢩ࣏ࣥࢪ࣒࢘㸭⚄

ᡞ㸭2017 ᖺ 9 ᭶ 7. ᱞᩜ๛㸪⣚㔝Ᏻᙪ㸪ᒸ㔝ᐶ㸪㞴Ἴᚨ㑻㸭ࢫࣃࢵࢱἲ࡛〇⭷ࡉࢀࡓ㓟໬ࢽ࢜ࣈⷧ⭷ࡢ స〇᮲௳ࡀ㟁Ẽ໬Ꮫⓗ࣭ග㟁Ẽ໬Ꮫⓗ≉ᛶ࡟୚࠼ࡿᙳ㡪㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍⛅ Ꮨࢩ࣏ࣥࢪ࣒࢘㸭⚄ᡞ㸭2017 ᖺ 9 ᭶ 8. ሷ⏣ᑗ኱㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭⁐⼥㞺ᅖẼࡢㄪᩚ࡟ࡼࡿ SnOx-ZnO-P2O5 ࢞ࣛࢫࡢస〇࡜ホ౯㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍⛅Ꮨࢩ࣏ࣥࢪ࣒࢘㸭⚄ᡞ㸭2017 ᖺ 9 ᭶ 9. 㧗℩㝧௓㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭㧗 ⁐⼥ἲ࡟ࡼࡾㄪ〇ࡉࢀࡓࢫࣛࢢࡢ ᵓᡂඖ⣲ࡢ⁐ฟᣲື㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍⛅Ꮨࢩ࣏ࣥࢪ࣒࢘㸭⚄ᡞ㸭2017 ᖺ 9 ᭶ 10. ᮌከⱥᩯ㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭㑏ඖ⁐⼥᫬࡟࠾ࡅࡿ⬺ࣜࣥࢫࣛࢢࡢᵓ ᡂඖ⣲ࡢศ㓄ᣲື㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍⛅Ꮨࢩ࣏ࣥࢪ࣒࢘㸭⚄ᡞ㸭2017 ᖺ 9 ᭶ 11. ୰ᑿᩥᙲ㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭⁐⼥ἲ࡟ࡼࡿࢭࢩ࣒࢘ởᰁᅵተฎ⌮࡟ ࠾ࡅࡿ᥹Ⓨᣲື㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍୰ᅜᅄᅜᨭ㒊ࣖࣥࢢࢭ࣑ࣛࢫࢺ࣑࣮ࢸ࢕ ࣥࢢ in ୰ᅄᅜ㸭ᮾᗈᓥ㸭2017 ᖺ 12 ᭶ 12. ⸨⃝ᘯⓏ㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭㒔ᕷࢦ࣑⁐⼥ࢫࣛࢢࡢᵓᡂඖ⣲ࡢ⁐ฟ ᣲື㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍୰ᅜᅄᅜᨭ㒊ࣖࣥࢢࢭ࣑ࣛࢫࢺ࣑࣮ࢸ࢕ࣥࢢ in ୰ᅄ ᅜ㸭ᮾᗈᓥ㸭2017 ᖺ 12 ᭶ 13. ᘯ⏣ኟᏊ㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭ఙ㛗࣭ᅽ⦰ฎ⌮࡟ࡼࡿ␗᪉ᛶ࢞ࣛࢫࡢ స〇㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍୰ᅜᅄᅜᨭ㒊ࣖࣥࢢࢭ࣑ࣛࢫࢺ࣑࣮ࢸ࢕ࣥࢢ in ୰ᅄ ᅜ㸭ᮾᗈᓥ㸭2017 ᖺ 12 ᭶ 14. ᒸᮏ࿴㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭SnO-P2O5⣔࢞ࣛࢫࡢᵓ㐀ゎᯒ㸭᪥ᮏࢭ ࣑ࣛࢵࢡࢫ༠఍୰ᅜᅄᅜᨭ㒊ࣖࣥࢢࢭ࣑ࣛࢫࢺ࣑࣮ࢸ࢕ࣥࢢ in ୰ᅄᅜ㸭ᮾᗈᓥ㸭 2017 ᖺ 12 ᭶ 15. ࿴Ἠᬛஓ㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭ḟୡ௦ᆺࣜࢳ࣒࢘࢖࢜ࣥ㟁ụࡢ඘ᨺ㟁 ࡟క࠺ά≀㉁ࡢᵓ㐀ኚ໬㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍୰ᅜᅄᅜᨭ㒊 ࣖࣥࢢࢭ࣑ࣛࢫࢺ ࣑࣮ࢸ࢕ࣥࢢ in ୰ᅄᅜ㸭ᮾᗈᓥ㸭2017 ᖺ 12 ᭶ 16. Ώ㒊⍞㈗㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭࣍࢘㓟ሷ⣔࢞ࣛࢫࡢሷᇶᗘホ౯࡜࢞ࣛ ࢫᵓ㐀࡜ࡢ┦㛵ゎ᫂㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍୰ᅜᅄᅜᨭ㒊ࣖࣥࢢࢭ࣑ࣛࢫࢺ࣑࣮ ࢸ࢕ࣥࢢ in ୰ᅄᅜ㸭ᮾᗈᓥ㸭2017 ᖺ 12 ᭶ 17. ᳃ᕝឡክ㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭ᾮᬗ࢞ࣛࢫࡢࣜࢧ࢖ࢡࣝᡭἲࡢ☜❧㸭 ᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍୰ᅜᅄᅜᨭ㒊ࣖࣥࢢࢭ࣑ࣛࢫࢺ࣑࣮ࢸ࢕ࣥࢢ in ୰ᅄᅜ㸭ᮾ ᗈᓥ㸭2017 ᖺ 12 ᭶

18. S. Fukuma, T. Shimanouchi, Y. Kimura, K. Hayashi㸭Binding of Horse Radish Peroxidase to Vesicular Membranes for a Control of Enzymatic Polymerization Reaction㸭11th International Conference on Separation Science and Technology㸭Busan, Korea㸭2017 ᖺ 11 ᭶

19. Y. Kitagawa, R. Nishiguchi, T. Shimanouchi, Y. Kimura㸭Hybrid Material Combined Metal Catalyst with Gel Matrix and Lipid Membranes㸭11th International Conference on Separation Science and Technology㸭Busan, Korea㸭2017 ᖺ 11 ᭶

Complex for Poly(Lacticacid) Polymerization 㸭 11th International Conference on Separation Science and Technology㸭Busan, Korea㸭2017 ᖺ 11 ᭶

21. D. Hirota, T. Shimanouchi, Y. Kimura㸭Polymerization in Emulsion under Hydrothermal Conditions for Nano-Sized Particles㸭11th International Conference on Separation Science and Technology㸭Busan, Korea㸭2017 ᖺ 11 ᭶

22. T. Shimanouchi, M. Shimizu, Y. Kimura㸭Estimate of Supersaturation of Amyloidgenic Proteins Using The Effect of Inhibitors and Lipid Membranes 㸭 11th International Conference on Separation Science and Technology㸭Busan, Korea㸭2017 ᖺ 11 ᭶

23. ᓥෆᑑᚨ, ኱ሯ୓㔛ዉ, ᮌᮧᖾᩗ㸭2-࢚ࢳࣝ࣊࢟ࢧࣥ㓟ࢫࢬࡢ 2 ḟඖ┦ศ㞳ᣲື࡟ ᇶ࡙ࡃ࣏ࣜங㓟㔜ྜ཯ᛂࡢゐ፹άᛶไᚚ㸭⭷ࢩ࣏ࣥࢪ࣒࢘ 2017㸭ᐩᒣ㸭2017 ᖺ 11 ᭶ 24. ⚟㛫᪩⣖, ᓥෆᑑᚨ, ᮌᮧᖾᩗ㸭࣏ࣜ࢔ࢽࣜࣥࡢ㓝⣲ⓗ㔜ྜ཯ᛂ࡟୚࠼ࡿᙳ㡪㹼⬡ ㉁ᖹ㠃⭷࡜࣋ࢩࢡࣝ⭷ࡢẚ㍑㹼㸭⭷ࢩ࣏ࣥࢪ࣒࢘ 2017㸭ᐩᒣ㸭2017 ᖺ 11 ᭶ 25. ➟஭᫛Ⰻ, ᓥෆᑑᚨ, ᑠᕸ᪋♳⧊, ᮌᮧᖾᩗ㸭࢔࣑ࣟ࢖ࢻE࣌ࣉࢳࢻࡢ࢔ࣝ࢝ࣥࢳ ࣮࢜ࣝㄏᑟయࡢసᡂ࡜⭷ୖ࡛ࡢ࢔࣑ࣟ࢖ࢻᙧᡂ࡬ࡢᙳ㡪㸭⭷ࢩ࣏ࣥࢪ࣒࢘ 2017㸭 ᐩᒣ㸭2017 ᖺ 11 ᭶ 26. Ọ෬ᜤྖ, ᓥෆᑑᚨ, ᮌᮧᖾᩗ㸭࢖࣑ࣥࡢ⦰ྜ཯ᛂࢆࢣ࣮ࢫࢫࢱࢹ࢕࣮࡜ࡍࡿ࣏ࣜ ࢯ࣮࣒⭷ࡢᚤᑠ⢓ᛶࡢᙳ㡪㸭໬ᏛᕤᏛ఍ ➨ 49 ᅇ⛅Ꮨ኱఍㸭ྡྂᒇ㸭2017 ᖺ 9 ᭶ 27. ⚟㛫᪩⣖, ᓥෆᑑᚨ, ᮌᮧᖾᩗ㸭⏺㠃άᛶ๣࣋ࢩࢡࣝࢆ⏝࠸ࡓ㧗ឤᗘࢭࣥࢧᮦᩱࡢ 㛤Ⓨ㸭໬ᏛᕤᏛ఍ ➨ 49 ᅇ⛅Ꮨ኱఍㸭ྡྂᒇ㸭2017 ᖺ 9 ᭶ 28. ᓥෆᑑᚨ, ➟஭᫛Ⰻ, ᮌᮧᖾᩗ㸭࢔࣑ࣟ࢖ࢻᙧᡂ࡟ࡼࡿࢳ࣮ࣗࣈᵓ㐀ࡢㄏᑟ㸭᪥ᮏ ⭷Ꮫ఍➨ 39 ᖺ఍㸭ᮾி㸭2017 ᖺ 5 ᭶ 29. ⚟㛫᪩⣖, ᓥෆᑑᚨ, ᮌᮧᖾᩗ㸭㗪ᆺຠᯝࢆㄏᑟࡍࡿࢱࣥࣃࢡ㉁ࡢ⭷㓄ྥ≉ᛶࡢホ ౯㸭᪥ᮏ⭷Ꮫ఍➨ 39 ᖺ఍㸭ᮾி㸭2017 ᖺ 9 ᭶ 30. ⸨ཎᩗ, ᓥෆᑑᚨ, ᮌᮧᖾᩗ㸭࣏ࣜࢯ࣮࣒⭷ࢆ཯ᛂሙ࡜ࡍࡿ஺ᕪ࢔ࣝࢻ࣮ࣝ཯ᛂࡢ ไᚚ㸭᪥ᮏ⭷Ꮫ఍➨ 39 ᖺ఍㸭ᮾி㸭2017 ᖺ 9 ᭶ 31. ➟஭᫛Ⰻ, ᓥෆᑑᚨ, ᮌᮧᖾᩗ㸭࢔࣑ࣟ࢖ࢻࢆ⏝࠸ࡓ᪂つ࡞࢘࢖ࣝࢫ࣋ࢡࢱ࣮ἲࡢ 㛤Ⓨ㸭᪥ᮏ⭷Ꮫ఍➨ 39 ᖺ఍㸭ᮾி㸭2017 ᖺ 9 ᭶ 32. ᓥෆᑑᚨ, ㏆⸨᫂ᗈ, ᘅ⏣኱ᆅ, ᮌᮧᖾᩗ㸭࣐࢖ࢡࣟ࢟ࣕࣆ࣮ࣛࣜ࡟ࡼࡿள⮫⏺Ỉ ங໬࡟ᇶ࡙ࡃࢼࣀ࢚࣐ࣝࢩࣙࣥᙧᡂ㸭ศ㞳ᢏ⾡఍ᖺ఍ 2017㸭⚄ዉᕝ㸭2017 ᖺ 5 ᭶ 33. ᘅ⏣኱ᆅ, ྜྷ⏣ᨻᩥ, ᓥෆᑑᚨ, ᮌᮧᖾᩗ㸭Polymer-in-oil ࢼࣀ࢚࣐ࣝࢩࣙࣥ࡟ࡼࡿ ࢭ࣮ࣝࣟࢫ-ࣜࢢࢽࣥ⣔ᅽຊᡂᙧ≀ࡢ⾲㠃ᨵ㉁㸭ศ㞳ᢏ⾡఍ᖺ఍ 2017㸭⚄ዉᕝ㸭 2017 ᖺ 5 ᭶ 34. ᓥෆᑑᚨ, ᒸᮧ᪩ⓒྜ, ᮌᮧᖾᩗ㸭ࢱࣥࣃࢡ㉁ࡢ⬡㉁⭷࡬ࡢ⵳✚࡟ཬࡰࡍ⭷ᦂࡽࡂ ࡢᙳ㡪㸭໬ᕤᏛ఍➨ 82 ᖺ఍㸭ᮾி㸭2017 ᖺ 3 ᭶ 35. ᓥෆᑑᚨ, ΎỈ┿✑, ᮌᮧᖾᩗ㸭㏿ᗘㄽⓗゎᯒ࡟ࡼࡿ࢔࣑ࣟ࢖ࢻEࢱࣥࣃࢡ㉁ࡢ㐣 㣬࿴ࡢホ౯㸭໬ᕤᏛ఍➨ 82 ᖺ఍㸭ᮾி㸭2017 ᖺ 3 ᭶ 36. ᓥෆᑑᚨ, ⓑ㧨ຬᏘ, ᮌᮧᖾᩗ㸭⬡㉁ᖹ㠃⭷ୖ࡛ࡢࣜࢰࢳ࣒࢘ࡢ఍ྜ≉ᛶ࡜⤖ᬗ໬ 㸭໬ᕤᏛ఍➨ 82 ᖺ఍㸭ᮾி㸭2017 ᖺ 3 ᭶

37. H. Atarashi㸭Structures of Poly(methyl methacrylate) Films under Non-solvents㸭The 6th International Commemorative Symposium of GMAP/LPIC/NGAP㸭Yamagata, Japan㸭

2017 ᖺ 1 ᭶ 38. 㰺⸨⣧ᕼ㸪ᒣᓮៅ୍㸪᪂ྐ⣖㸪ᮌᮧ㑥⏕㸭┤㙐≧࣏࢚ࣜࢳࣞࣥ࡟⎔≧࣏࢚ࣜࢳࣞࣥ ࢆῧຍࡋࡓ⣔ࡢὶືሙ⤖ᬗ໬࡟୧ᡂศศᏊ㔞ࡀཬࡰࡍᙳ㡪㸭➨ 66 ᅇ㧗ศᏊᖺḟ኱ ఍㸭༓ⴥ㸭2017 ᖺ 5 ᭶ 39. ᑠᒣு㸪ව㧗♸㍜㸪᪂ྐ⣖㸪ᒣᓮៅ୍㸪ᮌᮧ㑥⏕㸭ࣇࣛࣥ⣔࣏ࣜࢣࢺࣥࡢྜᡂ㸭ᖹ ᡂ 2 9 ᖺᗘ⧄⥔Ꮫ఍ᖺḟ኱఍㸭2017 ᖺ 6 ᭶ 40. ୕⏣⫱ᐇ㸪ව㧗♸㍜㸪᪂ྐ⣖㸪ᒣᓮៅ୍㸪ᮌᮧ㑥⏕㸭࣋ࣥࢰࣅࢫࢳ࢔ࢰ࣮ࣝ㦵᱁ࢆ ྵࡴ࣏ࣜ࢖࣑ࢻ࡜࣏ࣜ࢔࣑ࢻࡢㄪ〇㸭ᖹᡂ 2 9 ᖺᗘ⧄⥔Ꮫ఍ᖺḟ኱఍㸭2017 ᖺ 6 ᭶ 41. ኱ᕝ㞞ᘯ㸪ᒣᓮៅ୍㸪᪂ྐ⣖㸪ᮌᮧ㑥⏕㸭㐃⤖Ⅼ࡟࣊ࢸࣟཎᏊࢆྵࡲ࡞࠸୧ᮎ➃࡟ ࣃ࣮ࣇࣝ࢜ࣟ࢔ࣝ࢟ࣝᇶࢆ᭷ࡍࡿ࣏࢚ࣜࢳࣞࣥࡢྜᡂ࡜⤖ᬗ໬㸭ᖹᡂ 2 9 ᖺᗘ⧄⥔ Ꮫ఍ᖺḟ኱఍㸭2017 ᖺ 6 ᭶ 42. ᑠཎ㐩▮㸪▼ཎᗈᓫ㸪᪂ྐ⣖㸪ᒣᓮៅ୍㸪ᮌᮧ㑥⏕㸭࢚ࢫࢸ̺ࣝ࢔࣑ࢻ஺᥮཯ᛂㄏ ㉳ᆺ⤖ᬗ໬ࢆ฼⏝ࡋࡓ࣏࢚ࣜࢳࣞࣥࢸࣞࣇࢱ࣮ࣞࢺ࠿ࡽ࣏ࣜ(1,4-ࣇ࢙ࢽࣞࣥࢸࣞ ࣇࢱࣝ࢔࣑ࢻ)ࡢㄪ〇㸭ᖹᡂ 29 ᖺᗘ➨ 47 ᅇ⧄⥔Ꮫ఍ኟᏘࢭ࣑ࢼ࣮㸭ᒱ㜧㸭2017 ᖺ 8 ᭶ 43. ᮡᮏṇ㎿㸪᪂ྐ⣖㸪ᒣᓮៅ୍㸪ᮌᮧ㑥⏕㸭㔜ྜ┦ኚ໬࡟ࡼࡿࢹ࢕ࣥࣉࣝᆺ࣏ࣜ(p-࢜࢟ࢩࣇ࢙ࣝࣟ࢖ࣝ)⌫≧ᚤ⢏Ꮚࡢㄪ〇㸭ᖹᡂ 29 ᖺᗘ➨ 47 ᅇ⧄⥔Ꮫ఍ኟᏘࢭ࣑ࢼ ࣮㸭ᒱ㜧㸭2017 ᖺ 8 ᭶ 44. ᪂ྐ⣖㸪࿴⏣ಙᖹ㸪ᷓᇉὈኈ㸪ᒣᓮៅ୍㸪ᮌᮧ㑥⏕㸭㔜ྜ⤖ᬗ໬࡟ࡼࡿ⨨᥮ᇶᆺ࣏ ࣜ(4-࢜࢟ࢩ࣋ࣥࢰ࢖ࣝ)ࡢ㧗ḟᵓ㐀ไᚚ㸭➨ 66 ᅇ㧗ศᏊウㄽ఍㸭ឡ፾㸭2017 ᖺ 9 ᭶ 45. ྜྷ⏣ἋኸⳀ㸪᪂ྐ⣖㸪ᒣᓮៅ୍㸪ᮌᮧ㑥⏕㸭⎔≧ PLLA ࡢ࢚ࢫࢸࣝ஺᥮཯ᛂ࡟ࡼࡿ ศᏊ㔞ኚ໬࡜┤㙐≧ PLLA ࡟ᑐࡍࡿ᰾⏕ᡂಁ㐍ຠᯝࡢศᏊ㔞౫Ꮡᛶ㸭➨ 66 ᅇ㧗ศ Ꮚウㄽ఍㸭ឡ፾㸭2017 ᖺ 9 ᭶ 46. ᪥࿴బ๛㸪ᒣᓮៅ୍㸪᪂ྐ⣖㸪ᮌᮧ㑥⏕㸭┤㙐≧࣏ࣜங㓟࡟ᫍᆺ࣏ࣜங㓟ࢆῧຍࡋ ࡓ⣔ࡢὶືሙ⤖ᬗ໬࡟࠾ࡅࡿศᒱⅬ࡜⭎ࡢ㛗ࡉࡢᙺ๭㸭➨ 66 ᅇ㧗ศᏊウㄽ఍㸭ឡ ፾㸭2017 ᖺ 9 ᭶ 47. 㔝ᓮ⳯᦬㸪᪂ྐ⣖㸪ᒣᓮៅ୍㸪ᮌᮧ㑥⏕㸭㔜ྜ⤖ᬗ໬࡟ࡼࡿᇶᯈ࡟ᆶ┤࡟㓄ྥࡋࡓ ࣏ࣜ ( p - ࢜࢟ࢩ࣋ࣥࢰ࢖ࣝ ) ࢘࢕ࢫ࣮࢝ࡢㄪ〇㸭➨ 32 ᅇ୰ᅜᅄᅜᆅ༊㧗ศᏊⱝ ᡭ◊✲఍㸭ᒣཱྀ㸭2017 ᖺ 11 ᭶ 48. ᮾᾏ┿ኸ㸪᪂ྐ⣖㸪ᒣᓮៅ୍㸪ᮌᮧ㑥⏕㸭୧ᮎ➃ᇶࡢ࠿ࡉ㧗ࡉࡀ␗࡞ࡿࢸࣞࢣࣜࢵ ࢡ࣏࢚ࣜࢳࣞࣥࡢྜᡂ࡜ࡑࡢࣈࣞࣥࢻ⣔ࡢ⤖ᬗ໬ᣲື㸭➨ 32 ᅇ୰ᅜᅄᅜᆅ༊㧗ศ Ꮚⱝᡭ◊✲఍㸭ᒣཱྀ㸭2017 ᖺ 11 ᭶ 49. ᪂ᐙᝡྐ㸪᪂ྐ⣖㸪ᒣᓮៅ୍㸪ᮌᮧ㑥⏕㸭⎔໬ἲࡀ␗࡞ࡿ⎔≧࣏ࣜ㸦H㸫࢝ࣉࣟࣛ ࢡࢺࣥ㸧ࡢ⌫ᬗࣔࣝࣇ࢛ࣟࢪ࣮࡜⌫ᬗᡂ㛗㏿ᗘࡢẚ㍑㸭➨ 32 ᅇ୰ᅜᅄᅜᆅ༊㧗ศ Ꮚⱝᡭ◊✲఍㸭ᒣཱྀ㸭2017 ᖺ 11 ᭶

ᄂᆮإԓᴾ

1. Structural analyses and reverse Monte Carlo modeling of niobium oxide amorphous film prepared by sputtering method

Go Sajiki, Yasuhiko Benino, Chinatsu Oki, Koji Ohara, Hiroshi Okano,

Tokuro Nanba ··· 125 2. ࢞ࣛࢫࡢᵓ㐀࡜⤖ྜ≧ែ

㞴Ἴᚨ㑻㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ··· 126 3. ᨺᑕගࢆ฼⏝ࡋࡓ㠀ᬗ㉁㓟໬ࢽ࢜ࣈⷧ⭷ࡢᵓ㐀ゎᯒ

ᒸᒣ኱Ꮫ⎔ቃ⌮ᕤᏛ㒊◊✲ሗ࿌Vol.23 ⎔ቃ≀㉁ᕤᏛ⛉

Structural analyses and reverse Monte Carlo modeling of niobium oxide

amorphous film prepared by sputtering method

Go Sajiki1)_{, Yasuhiko Benino}2)_{, Chinatsu Oki}3)_{, Koji Ohara}4)_{, Hiroshi Okano}5)_{, Tokuro Nanba}6) ڦSummary ڦ

Structural analyses of niobium oxide (NbOx) amorphous film prepared with a sputtering method have been

performed by using synchrotron X-ray radiation at SPring-8. The composition was determined as Nb2O5·0.8H2O from the measurements of Rutherford back scattering, X-ray fluorescence, X-ray absorption near edge structure, and thermal desorption spectroscopy. Structural information was obtained by extended X-ray absorption fine structure and high energy X-ray diffraction measurements. It was supposed from the experimental data that NbOx

consisted of distorted NbOn polyhedra connected by corner- and edge-sharing. Structural models were constructed

with reverse Monte Carlo (RMC) simulations. In the RMC models, the structural characteristics were successfully reproduced, and H atoms were, however, randomly distributed. Then, bond valence sum (BVS) constraint was introduced to the RMC simulation. As the results, narrower distribution in BVS was achieved for all the constituent atoms, and distinct OH bonds were effectively generated in the RMC model.

Fig. 4. RMC model of the amorphous niobium oxide, Nb2O5·0.8H2O optimized with BVS constraint. Green: niobium, red: oxygen, and pink: hydrogen. Nb-O and O-H bonds are drawn for the respective pairs within 2.8 and 1.5Å.

Fig. 8. (right) Distribution of coordination numbers in RMC models. Average coordination numbers are given in the parentheses.

ڦKey word ڦ 

Structural analysis, Amorphous film, Niobium oxide, Synchrotron radiation, High energy X-ray diffraction, X-ray absorption fine structure, Reverse Monte Carlo simulation, Bond valence sum

ڦAffiliation ڦ

1) Technical Personnel, National Institute of Technology, Kagawa College 2) Associate Professor, Graduate School of Environmental and Life Science 3) Student, Graduate School of Environmental and Life Science

4) Researcher, Japan Synchrotron Radiation Research Institute 5) Professor, National Institute of Technology, Kagawa College 6) Professor, Graduate School of Environmental and Life Science ڦ P r i n t i n g ڦ

ᒸᒣ኱Ꮫ⎔ቃ⌮ᕤᏛ㒊◊✲ሗ࿌Vol.23 ⎔ቃ≀㉁ᕤᏛ⛉

࢞ࣛࢫࡢᵓ㐀࡜⤖ྜ≧ែ

Structure and bonding states of glasses

㞴Ἴᚨ㑻1)_{㸪ᓮ⏣┿୍}2)_{㸪⣚㔝Ᏻᙪ}3)

Tokuro Nanba1)_{㸪Shinichi Sakida}2)_{㸪Yasuhiko Benino}3) ڦ ᴫ せ ڦ  SiO2࢞ࣛࢫ࡟ Na2O ࢆῧຍࡍࡿ࡜㸪ඹ᭷⤖ྜᛶࡢ㧗࠸ Si㸫O㸫Si ᯫᶫ⤖ྜࡀῶᑡࡋ㸪࢖࢜ࣥ⤖ྜᛶࡢ㧗 ࠸ Na㸫O ⤖ྜࡀቑຍࡍࡿࠋࡇࡢࡓࡵ㸪Na2O ྵ᭷㔞ࡢቑຍ࡟࡜ࡶ࡞࠸㸪࢞ࣛࢫࡣ࢖࢜ࣥ⤖ྜᛶࡀ㧗ࡃ࡞ࡿ ࡜ࡢ⌮ゎࡀ୍⯡ⓗ࡛࠶ࡿࠋ☜࠿࡟㸪X ⥺ග㟁Ꮚศගἲ㸦XPS㸧࡟ࡼࡾ ᐃࡋࡓ O1s ㌶㐨ࡢ᮰⦡࢚ࢿࣝࢠ࣮ ࡣ㸪Na2O ྵ᭷㔞ࡢቑຍ࡜࡜ࡶ࡟㸪ప᮰⦡࢚ࢿࣝࢠ࣮ഃ࡬ࢩࣇࢺࡍࡿࡇ࡜࠿ࡽ㸪㓟⣲ཎᏊࡢ㈇㟁Ⲵࡢቑຍ ࡀ♧၀ࡉࢀࡿࠋࡋ࠿ࡋࡇࡢ᫬㸪Si2p ࡸ Na1s ㌶㐨ࡢ᮰⦡࢚ࢿࣝࢠ࣮ࡶྠ᫬࡟ప᮰⦡࢚ࢿࣝࢠ࣮ഃ࡬ࢩࣇࢺ ࡋ࡚࠾ࡾ㸪ぢ࠿ࡅୖࡣ࢞ࣛࢫࡢᵓᡂཎᏊࡍ࡭࡚ࡢ㟁Ꮚᐦᗘࡀቑຍࡋࡓࡇ࡜࡟࡞ࡿࠋࡇࡢ⤖ᯝࡣ㸪࢖࢜ࣥ⤖ ྜᛶࡢቑຍ࡜࠸࠺ࡼࡾࡣඹ᭷⤖ྜᛶࡢቑຍ㸦ඹ᭷㟁Ꮚࡢቑຍ㸧ࢆ♧၀ࡍࡿࡶࡢ࡛࠶ࡿࠋ  ୖグࡢ౛௨እ࡟ࡶ㸪࢞ࣛࢫࢆᵓᡂࡍࡿ໬Ꮫ⤖ྜࡢᛶ㉁࡟ࡘ࠸࡚ࡣ㸪ᗈࡃᾐ㏱ࡋ࡚࠸ࡿ⌮ゎ࡜ࡣ␗࡞ࡿࡶ ࡢࡶ࠶ࡿࡼ࠺࡟ᛮࢃࢀࡿࠋᮏ✏࡛ࡣ㸪ᙜ◊✲ࢢ࣮ࣝࣉࡀࡇࢀࡲ࡛࡟⾜ࡗ࡚ࡁࡓ㸪࢞ࣛࢫࡢཎᏊ㓄ิࡸ㟁Ꮚ ≧ែࡢゎᯒ⤖ᯝ࡜࢞ࣛࢫࡢ໬Ꮫ⤖ྜ≧ែ࡟ࡘ࠸࡚㸪ࢣ࢖㓟ሷ࢞ࣛࢫ㸪࣍࢘㓟ሷ⣔࢞ࣛࢫ㸪ࡑࡋ࡚࣍࢘ࢣ࢖ 㓟ሷ⣔࢞ࣛࢫ࡟㛵ࡍࡿ◊✲ᡂᯝࢆ⤂௓ࡋࡓࠋ  ࣍࢘㓟ሷ⣔࢞ࣛࢫࡢ໬Ꮫ⤖ྜ≧ែࢆホ౯ࡍࡿࡓࡵ࡟㸪✀ࠎࡢ࣍࢘㓟ሷ⤖ᬗ࠿ࡽࢡࣛࢫࢱ࣮ࢆษࡾฟࡋ㸪 ศᏊ㌶㐨ィ⟬࡟ࡼࡾ࣍࢘⣲࡜㓟⣲㛫ࡢ⤖ྜ㟁Ⲵ QBOࢆồࡵࡓ㸦ᅗ㸲㸧ࠋB3-O-B3 ᯫᶫ⤖ྜࡢ⤖ྜ㟁Ⲵ QB3O ࢆぢ࡚ࡳࡿ࡜㸪࢔ࣝ࢝ࣜࢆྵࢇࡔ⤖ᬗࡢ᪉ࡀᑠࡉ࡞್࡟࡞ࡗ࡚࠸ࡿࠋࡇࢀࡣ㸪ࢣ࢖㓟ሷ⣔⤖ᬗࡢ QSiO࡛ࡶ ぢࡽࢀࡓഴྥ࡛࠶ࡿࠋ࣍࢘㓟ሷ⣔ࡢሙྜࡶ㸪ᯫᶫ㓟⣲࡟࢔ࣝ࢝ࣜࡀ┦஫స⏝ࡍࡿࡇ࡜࡟ࡼࡾ㸪ᯫᶫ⤖ྜࡀ ᙅࡃ࡞ࡿഴྥ࡟࠶ࡿ࡜࠸࠼ࡿࠋḟ࡟㓄఩ᩘࡀ␗࡞ࡿ B3-O-B4 ᯫᶫ⤖ྜ࡟ࡘ࠸࡚ぢ࡚ࡳࡿ࡜㸪QB3Oࡢ᪉ࡀ

QB4Oࡼࡾࡶ㧗࠸್࡟࡞ࡗ࡚࠸ࡿࠋ୧⪅ࡢᕪࡣ㸪B3-O-B3 ࡜ B4-O-B4 ᯫᶫ⤖ྜࡢ QB3O࡜ QB4Oࡢᕪࡼࡾࡶ኱

ࡁ࠸ࠋB3-O-B4 ᯫᶫ⤖ྜ࡛ࡣ㸪㟁ᏊࡣS⤖ྜࡢ㧗࠸ B3-O ⤖ྜࡢ᪉࡟೫ࡗ࡚Ꮡᅾࡍࡿ࡜⪃࠼ࡽࢀࡿࠋ

0.2 0.4 0.6 0.8 1.0 Bond overlap population, Q_BO

B₂O₃-I B₂O₃-II Li₂B₄O₇ Na₂B₄O₇ K₂B₄O₇ B3-O(-B3) B4-O(-B4) B4-O(-B4u2) B3-O(-B4) B4-O(-B4) B4-O(-B3) B3-O(-B3) B4-O(-B3)

B4-O(-B4) B3-O(-B4) B3-O(-Na) B3-O(-B4) B4-O(-B4) B4-O(-B3) ᅗ㸲 ✀ࠎࡢ࣍࢘㓟ሷ⤖ᬗ࠿ࡽษࡾฟࡋࡓࢡࣛࢫࢱ ࣮ࣔࢹࣝ࠿ࡽศᏊ㌶㐨ィ⟬࡟ࡼࡾồࡵࡓ㸪B-O ⤖ྜ ࡢ⤖ྜ㟁Ⲵ QBOࠋBn㸸n 㓄఩࣍࢘⣲㸪Bn-O(-Bm)㸸 Bn-O-Bm ᯫᶫ୰ࡢ Bn-O ⤖ྜ㸪㸩㸸ྠ✀ࡢ⤖ྜࡢᖹ ᆒ್ࠋ 0.2 0.4 0.6 0.8 1.0 Bond overlap population, Q_MO

Si-O(-Si) Si-O(-B4) B4-O(-Si) Si-O(-Si) Si-O(-Na) Al-O(-Si) Si-O(-Al) B4-O(-B3) B4-O(-B4)

B3-O(-B3) B3-O(-B4) B3-O(-Na)

NaBSi₃O₈ Na₂Si₂O₅ Na₂B₄O₇ KNa₃Al₄Si₄O₁₆ ᅗ㸳 ✀ࠎࡢ⤖ᬗ࠿ࡽษࡾฟࡋࡓࢡࣛࢫࢱ࣮ࣔࢹࣝ࠿ࡽ ศᏊ㌶㐨ィ⟬࡟ࡼࡾồࡵࡓ㸪M-O ⤖ྜࡢ⤖ྜ㟁Ⲵ QMOࠋ Bn㸸n 㓄఩࣍࢘⣲㸪M-O(-M̓)㸸M-O-M̓ᯫᶫ୰ࡢ M-O ⤖ྜ㸪㸩㸸ྠ✀ࡢ⤖ྜࡢᖹᆒ್ࠋ ڦ࣮࣮࢟࣡ࢻڦ ࢞ࣛࢫ㸪ᵓ㐀㸪㟁Ꮚ≧ែ㸪໬Ꮫ⤖ྜ≧ែ ڦ ᡤ ᒓ ڦ 1) ኱Ꮫ㝔⎔ቃ⏕࿨⛉Ꮫ◊✲⛉ ᩍᤵ㸪2) ⎔ቃ⟶⌮ࢭࣥࢱ࣮ ෸ᩍᤵ㸪3) ኱Ꮫ㝔⎔ቃ⏕࿨⛉Ꮫ◊✲⛉ ෸ᩍᤵ ڦ ᥖ㍕ඛ ڦ

↓ᶵ࣐ࢸࣜ࢔ࣝᏛ఍Ⓨ⾜㸪Journal of the Society of Inorganic Materials Japan, 24, 339-344, 2017.

ᒸᒣ኱Ꮫ⎔ቃ⌮ᕤᏛ㒊◊✲ሗ࿌Vol.23 ⎔ቃ≀㉁ᕤᏛ⛉

ᨺᑕගࢆ฼⏝ࡋࡓ㠀ᬗ㉁㓟໬ࢽ࢜ࣈⷧ⭷ࡢᵓ㐀ゎᯒ

Structural Analysis of Amorphous NbOx Thinfilm using Synchrotron Radiation

ᱞᩜ ๛1)_{㸪ᒸ㔝 ᐶ}2)_{㸪⣚㔝Ᏻᙪ}3)_{㸪㞴Ἴᚨ㑻}4)

Go Sajiki1)_{, Hiroshi Okano}2)_{, Yasuhiko Benino}3)_{, Tokuro Nanba}4) ڦ ᴫ せ ڦ  ➹⪅ࡽࡣ㸪཯ᛂᛶ RF ࣐ࢢࢿࢺࣟࣥࢫࣃࢵࢱࣜࣥࢢἲ࡛㔠ᒓⷧ⭷ᇶᯈୖ࡟ሁ✚ࡉࡏࡿࡇ࡜࡟ࡼࡾ㸪ࢼࣀ ࢔࢖ࣛࣥࢻᙧែࢆ᭷ࡍࡿ㓟໬ࢽ࢜ࣈⷧ⭷ࢆస〇ࡋ㸪㟁Ẽ໬Ꮫ≉ᛶ࠾ࡼࡧග㟁Ẽ໬Ꮫ≉ᛶ࡟╔┠ࡋࡓ◊✲ࢆ 㐍ࡵ࡚ࡁࡓࠋࡇࡇ࡛㸪ࢼࣀ࢔࢖ࣛࣥࢻ࡜ࡣ㸪nm ࣮࢜ࢲ࣮ࡢ┤ᚄ࡛ᓥ≧ࡢሁ✚≀ࡀᇶᯈୖ࡟ศᩓࡋ࡚࠸ࡿ ≧ែࢆᣦࡋ㸪ࡇࡢ≉ᚩⓗ࡞ᙧ≧࡟㉳ᅉࡍࡿග㟁ኚ᥮ᶵ⬟ࡢⓎ⌧࡜ࡑࡢ࣓࢝ࢽࢬ࣒ゎ᫂࡟ࡣ㸪኱࠸࡟⯆࿡ࢆ ចࡁࡘࡅࡿࡶࡢࡀ࠶ࡿࠋ⾲㠃ᙧែࡀᮦᩱᶵ⬟࡜㛵㐃ࡋ࡚࠸ࡿࡇ࡜ࡔࡅ࡛࡞ࡃ㸪ග㟁ኚ᥮࣓࢝ࢽࢬ࣒ࡢゎ᫂ ࡟ࡣ㸪㟁Ꮚᵓ㐀ࡢ⌮ゎࡀ๓ᥦ࡜࡞ࡿࡓࡵ㸪㓟໬ࢽ࢜ࣈ⤖ᬗࡢ㟁Ꮚᵓ㐀ゎᯒࢆ㐍ࡵ࡚࠸ࡿࠋ୍᪉࡛㸪ࢫࣃࢵ ࢱࣜࣥࢢἲ࡛⵨╔ࡉࢀࡿ㓟໬ࢽ࢜ࣈࡢከࡃࡣ㠀ᬗ㉁࡛࠶ࡾ㸪ࡑࡢ▷㊥㞳࣭୰㊥㞳ᵓ㐀ࢆ▱ࡾ㸪ᵓ㐀ࢆࣔࢹ ࣝ໬ࡍࡿࡇ࡜ࡶḞ࠿ࡏ࡞࠸ࠋ๓㏙ࡢ㏻ࡾ㸪ከᵝ࡞⤖ᬗከᙧࢆ᭷ࡍࡿ㓟໬ࢽ࢜ࣈ⣔ࡢ㠀ᬗ㉁ᵓ㐀ゎᯒࡣ㸪ᒁ ᡤᵓ㐀ࡢከᵝᛶࢆゎ᫂ࡍࡿࡇ࡜࡟ࡶ⤖ࡧࡘࡃ࡜⪃࠼ࡽࢀࡿࠋ  ᮏ✏࡛ࡣ㸪RF ࣐ࢢࢿࢺࣟࣥࢫࣃࢵࢱࣜࣥࢢἲ࡛స〇ࡋࡓ㓟໬ࢽ࢜ࣈⷧ⭷ࢆᑐ㇟࡜ࡋ㸪SPring-8 ᨺᑕග ᪋タࡢ」ᩘࡢࣅ࣮࣒ࣛ࢖ࣥࢆά⏝ࡋࡓ㠀ᬗ㉁ⷧ⭷ࡢᵓ㐀ゎᯒᐇ㦂ࡢᐇ౛ࢆ⤂௓ࡋࡓࠋຍ࠼࡚㸪ᚓࡽࢀࡓᵓ 㐀᝟ሗࢆ฼⏝ࡋ࡚㏫ࣔࣥࢸ࢝ࣝࣟ㸦RMC㸧ἲ࡟ࡼࡿᵓ㐀ࢩ࣑࣮ࣗࣞࢩࣙࣥࡢヨࡳ࡜ᒁᡤᵓ㐀ࡢ⌮ゎ࡟ྥࡅ ࡓ௒ᚋࡢᒎᮃ࡟ࡘ࠸࡚㏙࡭ࡓࠋ ᅗ㸱 㸦ྑ㸧࣏ࣜ࢖࣑ࢻࢸ࣮ࣉୖ࡟ NbOxࢆ〇⭷ࡋࡓ HEXRD  ᐃ⏝ヨᩱ࠾ࡼࡧ㸦ᕥ㸧ẚ㍑⏝࣏ࣜ࢖࣑ࢻࢸ࣮ࣉࠋ ᅗ㸲 HEXRD  ᐃ࡟ࡼࡿ NbOxⷧ⭷/࣏ࣜ࢖࣑ࢻࢸ࣮ࣉ࠾ ࡼࡧẚ㍑⏝࣏ࣜ࢖࣑ࢻࢸ࣮ࣉࡢᩓ஘ࣃࢱ࣮ࣥࠋ ᅗ㸳 RMC ᵓ㐀ࢩ࣑࣮ࣗࣞࢩࣙࣥ࡟࠾ࡅࡿ (a) X ⥺ ᵓ㐀ᅉᏊ㸪(b) EXAFS ࣃࢱ࣮ࣥ㸦┬␎㸧㸪࠾ࡼࡧ(c) Nb-O 㒊ศືᚄศᕸࠋⓑᢤࡁⅬ࠾ࡼࡧᐇ⥺ࡣ㸪ࡑࢀࡒ ࢀᐇ ࡜ RMC ィ⟬್ࠋ ڦ࣮࣮࢟࣡ࢻڦ

Structural analysis, Amorphous niobium oxide, HEXRD, XAFS, XRR ڦ ᡤ ᒓ ڦ 1) 㤶ᕝ㧗➼ᑓ㛛Ꮫᰯ ᢏ⾡⫋ဨ㸪2) 㤶ᕝ㧗➼ᑓ㛛Ꮫᰯ ᩍᤵ㸪3) ኱Ꮫ㝔⎔ቃ⏕࿨⛉Ꮫ◊✲⛉ ෸ᩍᤵ㸪4) ኱ Ꮫ㝔⎔ቃ⏕࿨⛉Ꮫ◊✲⛉ ᩍᤵ ڦ ᥖ㍕ඛ ڦ ᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍Ⓨ⾜㸪ࢭ࣑ࣛࢵࢡࢫ, Vol.52(5), pp.362-364, 2017. ᰝㄞ㸸↓㸪ゝㄒ㸸᪥ᮏㄒ

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ࢭ࣑ࣛࢵࢡࢫᮦᩱᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸㞴Ἴᚨ㑻࣭⣚㔝Ᏻᙪ࣭ᓮ⏣┿୍㸧 1. ࣜࢳ࣒࢘࢖࢜ࣥ㟁ụࡢ඘ᨺ㟁࡟క࠺ 2-line ࣇ࢙ࣜࣁ࢖ࢻࣛ࢖ࢺࡢᵓ㐀ኚ໬  2. SnO-P2O5⣔࢞ࣛࢫࡢᵓ㐀ゎᯒ 

3. Effect of Additives on the Dissolution Behaviour of the Constituent Elements of the Municipal Waste Molten Slag

4. ࣍࢘㓟ሷ⣔࢞ࣛࢫࡢሷᇶᗘホ౯࡜࢞ࣛࢫᵓ㐀࡟୚࠼ࡿᙳ㡪ホ౯  5. 㓟໬≀࢞ࣛࢫࡢሷᇶᗘホ౯ᡭἲࡢ᳨ウ 6. ᾮᬗ࢞ࣛࢫࡢࣜࢧ࢖ࢡࣝᡭἲࡢ㛤Ⓨ࡟ಀࢃࡿᇶ♏ⓗ◊✲   ↓ᶵᶵ⬟ᮦᩱ໬Ꮫ◊✲ᐊ㸦ᣦᑟᩍဨ㸸டᓥḠ୍࣭すᮏಇ௓㸧 7. MgFe ⣔ᒙ≧」Ỉ㓟໬≀(LDH)࡟ࡼࡿࢠ㓟࢖࢜ࣥศゎࡢ᳨ウ  8. ຍ‵ CH4ࡢ┤᥋౪⤥ୗ࡛ࡢ Ni0.8Zn0.2/Gd0.1Ce0.9O1.95࢔ࣀ࣮ࢻࡢ᳨ウ  9. 㔠ᢸᣢ㓟໬ࢳࢱࣥගゐ፹࡜㐣㓟໬Ỉ⣲ࡢే⏝࡟ࡼࡿỈ㉁ί໬  10. ࢻࣛ࢖ࢤࣝࢥࣥࣂ࣮ࢪࣙࣥἲ࡟ࡼࡿ࢔࣑ࣝࢼୖ࡬ࡢ A ᆺࢮ࢜ࣛ࢖ࢺࡢᡂ⭷  11. ᗫ࢞ࣛࢫࢆཎᩱ࡟⏝࠸ࡓࢪ࣏࣐࣮࢜ࣜࡢస〇 12. 㓟໬ࢳࢱࣥ࡟ࡼࡿࣃࢱ࣮ࣥ⾲㠃ࡢỈ୰᧕Ἔᛶ   ᭷ᶵᶵ⬟ᮦᩱᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸㧗ཱྀ㇏࣭⏣ᔱᬛஅ㸧 13. ࣓ࣝ࢝ࣉࢺ࢘ࣥࢹ࢝ࣄࢻࣟࢻࢹ࣮࢝࣎ࣞࢺࢆᮎ➃࡟ࡶࡘࢹࣥࢻ࣐࣮ࣜࡢྜᡂ࡜ SWCNT ࡜ࡢ」ྜ໬  14. ࢳ࢜࢝ࣝ࣎ࢽࣝⰍ⣲ෆໟSWCNT/ࣇࣛࣟࢹࣥࢻࣟࣥ㉸ศᏊ」ྜయࡢྜᡂ࡜ගቑឤ స⏝   15. N,N’-ࣅࢫ(2-࢚ࢳࣝ࣊࢟ࢩࣝ)-6,13-ࢪࣄࢻࣟ࣌ࣥࢱࢭࣥ[2,3:9,10]ࣅࢫ࢝ࣝ࣎࢟ࢩ࢖ ࣑ࢻ༢⤖ᬗࡢ⺯ග≉ᛶ  16. ༢ᒙ࣮࢝࣎ࣥࢼࣀࢳ࣮ࣗࣈගゐ፹ࢆ⏝࠸ࡓ㔠ᇶᯈୖ࡬ࡢỈ⣲⏕ᡂග㟁ᴟࡢస〇   ⎔ቃ㧗ศᏊᮦᩱᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸ᮌᮧ㑥⏕࣭ᒣᓮៅ୍࣭᪂ྐ⣖㸧 17. ⎔≧࣏࢚ࣜࢳࣞࣥ࡜ᫍᆺ࣏࢚ࣜࢳࣞࣥࡢࣈࣞࣥࢻ⣔࡟࠾ࡅࡿ⤖ᬗ໬ᣲື  18. PET ᶞ⬡࠿ࡽㄪ〇ࡋࡓ࣏ࣜ㸦p-ࣇ࢙ࢽࣞࣥࢸࣞࣇࢱࣝ࢔࣑ࢻ㸧ࡢ㧗ศᏊ㔞໬ 19. ⧞ࡾ㏉ࡋ༢఩࡜ࡣ␗࡞ࡿࢺࣜ࢔ࢰ㸫ࣝ⎔ᵓ㐀ࡢᏑᅾࡀ⎔≧㧗ศᏊࡢ⤖ᬗ໬࡜ࣔࣝ ࣇ࢛ࣟࢪ࣮࡟ཬࡰࡍᙳ㡪 20. ࣇ࢙ࣝࣛ㓟ࢆཎᩱ࡜ࡋࡓ㔜ྜ┦ኚ໬࡟ࡼࡿ␗ᙧᚤ⢏Ꮚࡢㄪ〇 21. 㔜ྜ┦ኚ໬࡟ࡼࡾㄪ〇ࡋࡓ࣏ࣜ(p-࢜࢟ࢩ࣋ࣥࢰ࢖ࣝ)࢘࢕ࢫ࣮࢝ࡢ㓄ิไᚚ 22. 㔜ྜ┦ኚ໬ࢆ฼⏝ࡋ࡚ㄪ〇ࡋࡓⰾ㤶᪘࣏ࣜ࢔࣑ࢻ࢖࣑ࢻ⤖ᬗࡢᙧែ࡟ཬࡰࡍ࢔࣑ ࢻ⤖ྜࡢᙳ㡪 23. ࢭ࣮ࣝࣟࢫࢼࣀ⤖ᬗ࠾ࡼࡧࡑࡢㄏᑟయࡢ⤖ᬗ໬᰾๣࡜ࡋ࡚ࡢ᭷⏝ᛶࡢ᳨ウ  

⎔ቃࣉࣟࢭࢫᕤᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸ᮌᮧᖾᩗ࣭ᓥෆᑑᚨ㸧 24. 㔠ᒓゐ፹ࡢ࣋ࢩࢡࣝ⭷ୖ࡟࠾ࡅࡿ⮬ᕫ㞟✚≉ᛶ࡜㔜ྜ཯ᛂ࡬ࡢᛂ⏝  25. ⬡㉁࣏࣐࣮ࣜ⏺㠃ࡢỈ࿴≉ᛶ࡜ࡺࡽࡂࡢホ౯  26. ࢔ࢽࣜࣥ࡜࣋ࣥࢬ࢔ࣝࢹࣄࢻࡢ⦰ྜ཯ᛂ࡟ᇶ࡙ࡃ࣏ࣜࢯ࣮࣒ࡢ཯ᛂሙ≉ᛶࡢホ౯  27. ࣏ࣜࢯ࣮࣒ࢆ⏝࠸ࡓ᪂つࣁ࢖ࣈࣜࢵࢻゐ፹ࡢ๰〇 ̿ࢢࣜࢭ࣮ࣟࣝࡢ⎔≧࢔ࢭࢱ ࣮ࣝ໬཯ᛂࢆࢣ࣮ࢫࢫࢱࢹ࢕࣮࡜ࡋ࡚̿ 28. 㔠ᒓࢼࣀࢡࣛࢫࢱ࣮ࡢᙧᡂࢆ┠ᣦࡋࡓ⬡㉁⭷ୖ࡛ࡢ໬Ꮫ㑏ඖἲࡢ㛤Ⓨ  29. ࢔࣑ࣟ࢖ࢻᡂ㛗࡟ᑐࡍࡿ⭷⏺㠃ࡺࡽࡂࡢᙳ㡪  ⎔ቃ཯ᛂᕤᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸ຍ⸨჆ⱥ࣭࢔ࢬࣁ࢘ࢵࢹ࢕ࣥ㸧 30. ࣋ࣥࢮࣥࡢ㓟໬࡟㐺ࡋࡓ㔠ᒓ㓟໬≀ゐ፹ࡢ㛤Ⓨ 31. 㓑㓟ࢭ࣮ࣝࣟࢫ࠿ࡽࡢάᛶⅣࡢㄪ〇࡜ࡑࡢ྾╔ᛶ⬟ホ౯ 32. ᅛᾮ⣔ᶵᲔ᧠ᢾ᧯స࡟࠾ࡅࡿศᩓ⢏య࡟ࡼࡿ㐃⥆┦ࡢΰྜಁ㐍ຠᯝ 33. Ⅳ໬ࡋࡓ㕲(Ϫ)ᢸᣢᆺ㝧࢖࢜ࣥ஺᥮ᶞ⬡࡛ࡢỈ㖟㝖ཤ 34. ᾋ㐟ศ㞳ἲ࡟ࡼࡿࢩࣜࢥࣥ⣔ᗫኴ㝧㟁ụ⢊ᮎ୰ࡢ୙⣧≀㝖ཤ 35. ࢼࣀࢧ࢖ࢬ✀⤖ᬗࢆ฼⏝ࡋࡓ໬Ꮫࢭࣥࢧ⏝ගࣇ࢓࢖ࣂ࣮࡬ࡢ ZSM-5 ⭷ྜᡂ 36. ᶵᲔ᧠ᢾ᫬ࡢᅛᾮ㛫≀㉁⛣ື㏿ᗘ࡟࠾ࡼࡰࡍỿ㝆⢏Ꮚࡢᾋ㐟ᣲືࡢᙳ㡪

̲ٟᛯ૨ᴾ

ࢭ࣑ࣛࢵࢡࢫᮦᩱᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸㞴Ἴᚨ㑻࣭⣚㔝Ᏻᙪ࣭ᓮ⏣┿୍㸧 1. ㏫ࣔࣥࢸ࢝ࣝࣟἲ࡜ศᏊືຊᏛἲࢆే⏝ࡋࡓ BPI ࢞ࣛࢫᅛ໬యࡢᵓ㐀ࣔࢹࣝᵓ⠏  2. ᅵተ୰ࡢࢭࢩ࣒࢘ࡢ᥹Ⓨᣲື࡟ᑐࡍࡿῧຍ≀ࡢຠᯝ  ↓ᶵᶵ⬟ᮦᩱ໬Ꮫ◊✲ᐊ㸦ᣦᑟᩍဨ㸸டᓥḠ୍࣭すᮏಇ௓㸧 3. ຓゐ፹ࢆᢸᣢࡋࡓ㓟໬ࢱࣥࢢࢫࢸࣥගゐ፹࡜㐣㓟໬Ỉ⣲࡜ࢆే⏝ࡋࡓỈ㉁ί໬ 4. ࢔ࣝࢥ࣮ࣝ୰࡛ࡢࣆࢥࣜࣥ㓟/ᒙ≧」Ỉ㓟໬≀」ྜయࡢྜᡂ 5. 㔠ᒓ-㓟໬ࢳࢱࣥ」ྜయࡢస〇࡜⇕㟁≉ᛶホ౯ 6. Fe-Ni ⣔⇞ᩱ㟁ụ⏝࢝ࢯ࣮ࢻᮦᩱࡢ㛤Ⓨ  ᭷ᶵᶵ⬟ᮦᩱᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸㧗ཱྀ㇏࣭⏣ᔱᬛஅ㸧 7. N,N’-ࣅࢫ࣊࢟ࢩࣝ-6,13-ࢪࣄࢻࣟ࣌ࣥࢱࢭࣥ[2,3:9,10]ࣅࢫ࢝ࣝ࣎࢟ࢩ࢖࣑ࢻࡢྜᡂ ࡜ᅛయ⺯ග≉ᛶ 8. Pt(II)ຓゐ፹ࢆᢸᣢࡋࡓ༢ᒙ࣮࢝࣎ࣥࢼࣀࢳ࣮ࣗࣈගゐ፹ࡢከẁ㝵㟁Ꮚ⛣ື㐣⛬ 9. ࢹࣥࢻ࣐࣮ࣜ࡟ࡼࡿ⾲㠃ಟ㣭ࢆ฼⏝ࡋࡓࣂࢵ࣮࣮࢟࣌ࣃ࣮/ࣄࢻࣟ࢟ࢩ࢔ࣃࢱ࢖ࢺ 」ྜࣇ࢕࣒ࣝࡢస〇   ⎔ቃ㧗ศᏊᮦᩱᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸ᮌᮧ㑥⏕࣭ᒣᓮៅ୍࣭᪂ྐ⣖㸧 10. 㐃⤖Ⅼ࡟࣊ࢸࣟཎᏊࢆྵࡲ࡞࠸୧ᮎ➃࡟ࣃ࣮ࣇࣝ࢜ࣟ࢔ࣝ࢟ࣝᇶࢆ᭷ࡍࡿ࣏࢚ࣜ ࢳࣞࣥࡢྜᡂ࡜⤖ᬗ໬ 11. ࣇࣛࣥ㦵᱁ࢆ᭷ࡍࡿ㧗ᛶ⬟ࣂ࢖࢜ࣉࣛࢫࢳࢵࢡࡢㄪ〇 12. ┤㙐≧࣏࢚ࣜࢳࣞࣥ࡟⎔≧࣏࢚ࣜࢳࣞࣥࢆῧຍࡋࡓࣈࣞࣥࢻ⣔ࡢ⤡ࡳྜ࠸≧ែࡢ ኚ໬ࡀ shish ⏕ᡂ࡟ཬࡰࡍᙳ㡪 13. ࣋ࣥࢰࣅࢫࢳ࢔ࢰ࣮ࣝ㦵᱁ࢆྵࡴ࣏ࣜ࢖࣑ࢻ࡜࣏ࣜ࢔࣑ࢻࡢㄪ〇࡜㧗ḟᵓ㐀ᙧᡂ 14. 㔜ྜ┦ኚ໬ࢆ฼⏝ࡋ࡚ㄪ〇ࡋࡓ࢝ࣉࢺࣥᆺ࣏ࣜ࢖࣑ࢻ⤖ᬗࡢᙧែᆒ୍ᛶࡢྥୖ 15. ┤㙐≧࣏ࣜங㓟࡟ᫍᆺ࣏ࣜங㓟ࢆῧຍࡋࡓ⣔ࡢὶືሙ⤖ᬗ໬࡟࠾ࡅࡿศᒱⅬࡢᙺ ๭ 16. 㔜ྜ┦ኚ໬ἲࢆ⏝࠸ࡓ⨨᥮ᇶᆺ࣏ࣜ(4-࢜࢟ࢩ࣋ࣥࢰ࢖ࣝ)⤖ᬗࡢᙧែไᚚ  ⎔ቃࣉࣟࢭࢫᕤᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸ᮌᮧᖾᩗ࣭ᓥෆᑑᚨ㸧 17. ⾑⟶ෆືែࡢᨵၿࢆ┠ᣦࡋࡓ┬ࣉࣟࢭࢫ࡞࣏ࣜࢯ࣮࣒㸫㧗ศᏊ」ྜయࡢㄪ〇࡜≉ ᛶホ౯ 18. ࢔࣑ࣟ࢖ࢻEࢱࣥࣃࢡ㉁ࡢ࢔࣑ࣟ࢖ࢻᡂ㛗࡟㛵ࡍࡿ㏿ᗘㄽⓗゎᯒ 㸫㐣㣬࿴ᗘ࡜ᡂ 㛗ᢚไࡢホ౯㸫 19. ⬡㉁⭷ࢆࢯࣇࢺ⏺㠃࡜ࡍࡿ᪂つ࡞ᬗᯒἲࡢ㛤Ⓨ 㸫ࣜࢰࢳ࣒࢘ࢆࢣ࣮ࢫࢫࢱࢹ࢕࣮ ࡜ࡋ࡚㸫 20. ┬ࣉࣟࢭࢫ໬ࢆ┠ᣦࡋࡓ⸆≀㏦㐩ᢸయタィࡢࡓࡵࡢᶵ⬟ᛶ࣌ࣉࢳࢻࡢ≉ᛶホ౯

21. ࣋ࢩࢡࣝࡢࢯࣇࢺ⏺㠃࡟ࡼࡿ㗪ᆺຠᯝ 㸫࣏ࣜ࢔ࢽࣜࣥ㔜ྜ཯ᛂࢆࢣ࣮ࢫࢫࢱࢹ࢕ ࣮࡜ࡋ࡚㸫 22. ࣐࢖ࢡࣟὶ㊰ෆࢫࣛࢢὶ࡛ࡢ≀㉁⛣ື≉ᛶࡢホ౯࡜⏺㠃ࡺࡽࡂࡢᙳ㡪  ⎔ቃ཯ᛂᕤᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸ຍ⸨჆ⱥ࣭࢔ࢬࣁ࢘ࢵࢹ࢕ࣥ㸧 23. ᾮ㠃࡬ࡢ⢏Ꮚ྿ࡁࡘࡅ᫬ࡢᅛ㸫ᾮ㛫≀㉁⛣ື㏿ᗘ࡜⢏Ꮚ౵ධ῝ࡉ 24. ᶵᲔ᧠ᢾ᫬ࡢᾮ㸫ᾮ㛫ΰྜࣃࢱ࣮ࣥ࡜ὶື≉ᛶ 25. NH3ࢆ⏝࠸ࡓ CO2࣓ࢱࣥ໬࡟࠾ࡅࡿ Ru ᢸᣢゐ፹࡬ࡢ࢔ࣝ࢝ࣜ㔠ᒓࠊ࢔ࣝ࢝ࣜᅵ㢮 㔠ᒓῧຍࡢຠᯝ

26. Effect of iron-cerium oxide catalysts on steam gasification of rubber wood sawdust