2016年 環境物質工学科 学術論文等

ᵐᵎᵏᵔ ࠰ᴾ ࿢ؾཋឋ߻ܖᅹᴾ

ܖᘐᛯ૨ሁᴾ

ⴭ  ᭩ 1. டᓥḠ୍㸪すᮏಇ௓㸪୕Ꮿ㏻༤㸭ᒙ≧」Ỉ㓟໬≀㸦LDH㸧ࢆ฼⏝ࡋࡓ⎔ቃί໬ᮦᩱ 㸭᭱᪂↓ᶵ㧗ศᏊࡢ⏝㏵㛤Ⓨ㸪ࢩ࣮࢚࣒ࢩ࣮ฟ∧㸭2016 ᖺ 12 ᭶㸦ฟ∧ணᐃ㸧 2. ୹ᚋభᩯ, ᮧୖ⠊Ṋ, ▼ᮏᐶః㸪⏣ᔱᬛஅ㸪㧗ཱྀ㇏㸭ࢼࣀⅣ⣲ᮦᩱࢆ⏝࠸ࡓỈ࠿ࡽ ࡢỈ⣲〇㐀㸭෌⏕ྍ⬟࢚ࢿࣝࢠ࣮࡟ࡼࡿỈ⣲〇㐀㸪S㸤T ฟ∧㸪➨㸱⠇㸪p135-142. 㸭2016 ᖺ 10 ᭶ ཎⴭㄽᩥ

1. C. Oki, G. Sajiki, S. Sakida, Y. Benino, T. Nanba㸭Investigation of electronic structure of amorphous niobium oxide based on the DFT calculation of crystalline niobium pentoxide polymorphs㸭Journal of the Ceramic Society of Japan, 124(12) 1221-1225.㸭᪥ᮏࢭ࣑ࣛ ࢵࢡࢫ༠఍㸭2016 ᖺ

2. A. Mukunoki, T. Chiba, Y. Benino, T. Sakuragi㸭Microscopic structural analysis of lead borate-based glass㸭Progress in Nuclear Energy, 9 339̽344.㸭Elsevier㸭2016 ᖺ

3. S. Kohara, K. Ohara, H. Tajiri, C. Song, O. Sakata, T. Usuki, Y. Benino, A. Mizuno, A. Masuno, J.T. Okada, T. Ishikawa, S. Hosokawa㸭Synchrotron X-ray scattering measure- ments of disordered materials㸭Zeitschrift für Physikalische Chemie, 230, 339-368.㸭DE GRUYTER㸭2016 ᖺ

4. ୕℩༓ᬡ, ∦᱒క἞, すᮏಇ௓, டᓥḠ୍, ୕Ꮿ㏻༤㸭␆⋇㦵ṧ´࠿ࡽศ㞳ࡋࡓỈ

㓟໬࢔ࣃࢱ࢖ࢺ࡟ࡼࡾ㞴⁐໬ࡋࡓᅵተ୰࢝ࢻ࣑࣒࢘ࡢゎᯒ㸭᪥ᮏᅵተ⫧ᩱᏛ఍ㄅ, 87, 9-14.㸭᪥ᮏᅵተ⫧ᩱᏛ఍㸭2016 ᖺ

5. M. Miyake, S. Matsumoto, M. Iwami, S. Nishimoto, Y. Kameshima㸭Electrochemical performances of Ni1-xCux/SDC cermet anodes for intermediate-temperature SOFCs using syngas fuel㸭Int. J. Hydrogen Energy, 41, 13625-13631.㸭Elsevier㸭2016 ᖺ

6. 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, in press.㸭Elsevier㸭2016 ᖺ

ferrocenylthiocarbonyl groups㸭Chem. Lett. DOI: 10.1246/cl.160866.㸭᪥ᮏ໬Ꮫ఍㸭 2016 ᖺ

8. H. Shirai, T. Tajima, K. Kubo, T. Nishihama, H. Miyake, Y. Takaguchi㸭Synthesis and crystal structure of a [70]fullerene̽pentacene monoadduct㸭Bull. Chem. Soc. Jpn., 89, 437-443.㸭᪥ᮏ໬Ꮫ఍㸭2016 ᖺ

9. H. Goto, T. Tajima, K. Kobayashi, Y. Takaguchi, K. Nueangnoraj, H. Nishihara㸭Synthesis and photoproperties of edge-functionalized zeolite-templated carbon with bromine or carbazole groups㸭Chem. Lett., 45, 601-603.㸭᪥ᮏ໬Ꮫ఍㸭2016 ᖺ

10. H. Suda, Md. A. Uddin, Y. Kato㸭Chlorine removal from incinerator bottom ash by superheated steam㸭Fuel, 184,753-760.㸭2016 ᖺ

11. K. Yoshitomi, M. Nagase, Md. A. Uddin, Y. Kato㸭Fluid mixing in ladle of RH degasser induced by down flow㸭ISIJ INt., 56, 1119-1123.㸭2016 ᖺ

12. Ⱚ❳ኴ㑻, Md. A. Uddin, ຍ⸨჆ⱥ㸭ᶵᲔᨩᢾ᫬ࡢᅛᾮ㛫ΰྜࣃࢱ࣮ࣥ࡜ࡑࡢᾮᾮ

⣔࡜ࡢẚ㍑, Solid/liquid mixing pattern and its comparison with liquid/liquid one in a mechanically-stirred vessel㸭㕲࡜㗰, 102, 196-201.㸭2016 ᖺ

13. Y. Kawabe, Md. A. Uddin, Y. Kato, M. O. Seok, S. B. Lee㸭Correlation between liquid/liquid nass transfers in a top/bottom blowing converter㸭ISIJ INt., in press.㸭2016 ᖺ

14. G. Takeuchi, H. Tamaki, Md. A. Uddin, Y. Kato, E. Kiso, K. Takahashi㸭Mutual effect of steedmaking srag laler depth and diameter on alkali elution rate in open channel vessels with straitened seawater flow㸭J. Sustain. Metall., in press.㸭2016 ᖺ

15. T. Shimanouchi, S. Fujioka, Y. Kataoka, T. Tanifuji, Y. Kimura㸭Chemical conversion and liquid-liquid extraction of 5-hydroxymethylfurfural from fructose by slug flow microreactor㸭AIChE J., 62, 2135-2143㸭AIChE㸭2016 ᖺ

16. Y. Yokoyama, S. Aoyagi, T. Shimanouchi, M. Iwamura, H. Iwai㸭ToF-SIMS analysis of amyloid beta aggregation on different lipid membranes㸭Biointerphases, 11, 02A314㸭AIP Publishing, LLC㸭2016 ᖺ

17. S. Aoyagi, M. Iwamura, T. Shimanouchi, Y. Yokoyama, H. Iwai㸭The structural evaluation of amyloid beta on lipid membranes㸭Surf. Interface Anal., DOI: 10.1002/sia.6086.㸭⾲㠃 ⛉Ꮫ఍㸭2016 ᖺ

18. T. Shimanouchi, S. Fukuma, Y. Kimura㸭Molecular recognition/transformation based on membrane dynamics㸭Membrane, 41(5), 244-249.㸭᪥ᮏ⭷Ꮫ఍㸭2016 ᖺ

19. S. Mikawa, C. Mizuguchi, K. Nishitsuji, T. Baba, A. Shigenaga, T. Shimanouchi, N. Sakashita, A. Otaka, K. Akaji, H. Saito㸭Heparin promotes fibril formation by the N-terminal fragment of amyloidogenic apolipoprotein A-I 㸭 FEBS Lett., DOI: 10.1002/1873-3468.12426.㸭Elsevier㸭2016 ᖺ

20. 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 physico- chemical properties within self-assembled aggregates for an optimal drug carrier㸭Coll. Surf. B, in press.㸭Elsevier㸭2016 ᖺ

2,5-furandicarboxylic acid via nucleophilic aromatic substitution polymerization㸭J. Polym. Sci. Part A: Polym. Chem., 54, 3094-3101.㸭2016 ᖺ

22. T. Ohnishi, M. Nakagawa, K. Wakabayashi, T. Uchida, S. Yamazaki, K. Kimura㸭 Preparation of helical crystals of aromatic poly(ester-imide) and on-off switching of helix formation㸭Polymer, 98, 378-386.㸭2016 ᖺ

23. Y. Kanetaka, S. Yamazaki, K. Kimura㸭Preparation of Poly(ether ketone)s Derived from 2,5-Furandicarboxylic Acid by Polymerization in Ionic Liquid㸭Macromolecules, 49, 1252-1258.㸭2016 ᖺ

24. Y. Kanetaka, S. Yamazaki, K. Kimura 㸭 Synthesis of Poly(ether ketone)s from 2,5-Thiophenedicarboxylic Acid㸭J. Photopolym. Sci. Technol., 29, 243-246.㸭2016 ᖺ

⥲ㄝ➼ 1. 㞴Ἴᚨ㑻, ᓮ⏣┿୍, ⣚㔝Ᏻᙪ㸭ࢫࣛࢢ࠿ࡽࡢࣜࣥ㈨※ࡢᅇ཰㸭Phosphorus Letter, 86, 40-46㸭᪥ᮏ↓ᶵࣜࣥ໬Ꮫ఍㸭2016 ᖺ ᣍᚅㅮ₇ࡲࡓࡣᇶㄪㅮ₇ 1. すᮏಇ௓㸭㓟໬ࢳࢱࣥ⾲㠃ࡢỈ୰࡟࠾ࡅࡿ᧕Ἔᛶࡢホ౯࡜⎔ቃㄪ࿴ᢏ⾡࡬ࡢᛂ⏝ 㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍ 2016 ᖺᖺ఍ࢧࢸࣛ࢖ࢺࣉࣟࢢ࣒ࣛࠕ➨㸱ᅇ㈨※࣭⎔ቃ㛵 㐃ࢭ࣑ࣛࢵࢡࢫᮦᩱ࣭ᢏ⾡◊✲ㅮ₇఍ࠖ㸭2016 ᖺ 3 ᭶

2. Y. Kameshima 㸭 ENHANCEMENT OF THE PHOTOCATALYTIC ACTIVITY OF NITROGEN DOPED TITANIUM OXIDE / CLAY COMPOSITE BY A BLACKENING TREATMENT㸭The 3rd Asian Clay Conference 2016㸭2016 ᖺ 11 ᭶

3. ⏣ᔱᬛஅ㸭෇⟄≧࣐ࢡࣟᏍ㓄ิࢆᣢࡘ㓟໬ࢫࢬࡢྜᡂ࡜⼥ྜ࣐ࢸࣜ࢔ࣝ࡬ࡢᒎ㛤

㸭➨ 11 ᅇ᭷ᶵඖ⣲໬Ꮫࢭ࣑ࢼ࣮㸭2016 ᖺ 6 ᭶

4. ᓥෆᑑᚨ㸭⭷ࡢືⓗ≉ᛶࢆ฼⏝ࡋࡓศᏊㄆ㆑/ศᏊኚ᥮㸭⭷Ꮫ఍ 38 ᖺ఍㸭2016 ᖺ 5

᭶

5. ᓥෆᑑᚨ㸭Growth Behavior of Amyloid Fibrils on Membrane Interfaces of Lipid Membranes㸭Annual Meetings of AIChE㸭2016 ᖺ 11 ᭶

6. ᓥෆᑑᚨ㸭࢔ࣝࢶࣁ࢖࣐࣮⑓㛵㐃ࢱࣥࣃࢡ㉁ࡢ᳨▱࡜Ⓨ⑕ᢚไ࡟ྥࡅࡓྲྀࡾ⤌ࡳ 㸭࡯ࡗ࡜஺ὶ఍㸭2016 ᖺ 6 ᭶ ◊✲ㅮ₇࣭Ⓨ⾲ 1. ⥙⏣ྜྷఙ㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭㒔ᕷࡈࡳ⁐⼥ࢫࣛࢢࡢᵓᡂඖ⣲ࡢ⁐ฟ ᣲືㄪᰝ㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍ࢭ࣑ࣛࢵࢡࢫᇶ♏⛉Ꮫウㄽ఍㸭2016 ᖺ 1 ᭶ 2. ᐑᮏ⿱ኴ㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭Ag+_௅1D+_{㟁⏺࢖࢜ࣥ஺᥮࡟ࡼࡾࢸࣝࣛ} ࢖ࢺ࢞ࣛࢫ୰࡟⏕ᡂࡍࡿ㖟ᚤᏊࡢ≧ែ㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍ࢭ࣑ࣛࢵࢡࢫᇶ♏ ⛉Ꮫウㄽ఍㸭2016 ᖺ 1 ᭶ 3. ᯇ஭㑳ஓ㸪ᑠ㔝㄃ᘺ㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭࢝ࣝࢩ࣒࢘ࣜࣥ㓟ሷ⣔ఙ㛗

࢞ࣛࢫࡢศᏊືຊᏛᵓ㐀ࣔࢹࣝ໬㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍ 2016 ᖺ఍㸭2016 ᖺ 3 ᭶ 4. ᮾ฼ᙪ㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭㔠ᒓ㟁ᴟ㈏ධ࡟క࠺࢞ࣛࢫࡢ⤖ᬗ໬㸭᪥ ᮏࢭ࣑ࣛࢵࢡࢫ༠఍ 2016 ᖺ఍㸭2016 ᖺ 3 ᭶ 5. 㧗℩㝧௓㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭࢞ࢫ໬⁐⼥ἲ࡟ࡼࡾㄪ〇ࡉࢀࡓࢫࣛࢢ ࡢᵓᡂඖ⣲ࡢ⁐ฟᣲື࡟㛵ࡍࡿ◊✲㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍ 2016 ᖺ఍㸭2016 ᖺ 3 ᭶ 6. ඖୗ▱Ꮨ㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸪ᑠཎ┿ྖ㸭X ⥺␗ᖖᩓ஘࡟ࡼࡿࢸࣝࣛ ࢖ࢺ࢞ࣛࢫࡢᵓ㐀ゎᯒ㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍⛅Ꮨࢩ࣏ࣥࢪ࣒࢘㸭2016 ᖺ 9 ᭶ 7. ሷ⏣ᑗ኱㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭SnO ࢻ࣮ࣉ ZnO-P2O5 ⣔࢞ࣛࢫࡢⓎග ≉ᛶ㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍⛅Ꮨࢩ࣏ࣥࢪ࣒࢘㸭2016 ᖺ 9 ᭶ 8. ᮌከⱥᩯ㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭㑏ඖ⁐⼥᫬࡟࠾ࡅࡿ⬺ࣜࣥࢫࣛࢢࡢᵓ ᡂඖ⣲ࡢศ㓄ᣲື㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍⛅Ꮨࢩ࣏ࣥࢪ࣒࢘㸭2016 ᖺ 9 ᭶ 9. ⸨ᮏెᜨ㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭᪂ࡓ࡞ሷᇶᗘホ౯ᡭἲࡢ㛤Ⓨ㸭᪥ᮏࢭ ࣑ࣛࢵࢡࢫ༠఍ࣖࣥࢢࢭ࣑ࣛࢫࢺ࣑࣮ࢸ࢕ࣥࢢ in ୰ᅄᅜ㸭2016 ᖺ 12 ᭶ 10. ࣇ࢓ࣛ࢔࣐ࣜࢼ ࣅࣥࢸ࢖࢝ࣝࢽࢨ㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭㒔ᕷࡈࡳ⁐ ⼥ࢫࣛࢢࡢᵓᡂඖ⣲ฟᣲື㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍ࣖࣥࢢࢭ࣑ࣛࢫࢺ࣑࣮ࢸ࢕ࣥ ࢢ in ୰ᅄᅜ㸭2016 ᖺ 12 ᭶ 11. 㟷◒⨾✑㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭ࣜࢳ࣒࢘࢖࢜ࣥ㟁ụࡢ඘ᨺ㟁࡟క࠺㠀 ᬗ㉁ࣇ࢙ࣁࢻࣛ࢖ࢺࡢᵓ㐀ኚ໬㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍ࣖࣥࢢࢭ࣑ࣛࢫࢺ࣑࣮ࢸ ࢕ࣥࢢ in ୰ᅄᅜ㸭2016 ᖺ 12 ᭶ 12. ᳃ᕝᑦ⨾㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭ᾮᬗ࢞ࣛࢫࡢࣜࢧ࢖ࢡࣝᡭἲࡢ㛤Ⓨ㸭 ᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍ࣖࣥࢢࢭ࣑ࣛࢫࢺ࣑࣮ࢸ࢕ࣥࢢ in ୰ᅄᅜ㸭2016 ᖺ 12 ᭶ 13. ᑠᯘᙬ⳹㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭␗᪉ᛶ࢞ࣛࢫࡢస〇࡜ホ౯㸭᪥ᮏࢭࣛ ࣑ࢵࢡࢫ༠఍ࣖࣥࢢࢭ࣑ࣛࢫࢺ࣑࣮ࢸ࢕ࣥࢢ in ୰ᅄᅜ㸭2016 ᖺ 12 ᭶ 14. ⸨ᮏᜨ㔛ⰼ㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭࢔࣑ࣝࣀ࣍࢘㓟ሷ⣔࢞ࣛࢫࡢ㸲㓄఩ ࣍࢘⣲⏕ᡂࡢᨭ㓄ᅉᏊ㸭᪥ᮏࢭ࣑ࣛࢵࢡࢫ༠఍ࣖࣥࢢࢭ࣑ࣛࢫࢺ࣑࣮ࢸ࢕ࣥࢢ in ୰ᅄᅜ㸭2016 ᖺ 12 ᭶ 15. ཎ⨾Ꮨ㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ㸪㞴Ἴᚨ㑻㸭SnO-P2O5⣔࢞ࣛࢫࡢᵓ㐀ゎᯒ㸭᪥ᮏࢭࣛ ࣑ࢵࢡࢫ༠఍ࣖࣥࢢࢭ࣑ࣛࢫࢺ࣑࣮ࢸ࢕ࣥࢢ in ୰ᅄᅜ㸭2016 ᖺ 12 ᭶

16. Y. Takaguchi㸭Fabrication and Photosensiting Property of Coaxial Nanowires Having Carbon Nanotube Core㸭CATALYSIS at Okayama University Brainstorming Session㸭 2016 ᖺ 1 ᭶

17. Y. Takaguchi㸭Carbon Nanotube Hybrids Having Well-controlled Interface Structures㸭 International Workshop for Interplay between Nanocarbon, Supramolecule, and Biochemistry㸭2016 ᖺ 3 ᭶

18. T. Tajima㸭Fabrication of Novel Core-shell Microspheres Consisting of Single-walled Carbon Nanotubes and CaCO3 through Biomimetic Mineralization 㸭 International Workshop for Interplay between Nanocarbon, Supramolecule, and Biochemistry㸭2016 ᖺ 3 ᭶

19. ⓑ஭ோኈ㸪⏣ᔱᬛஅ㸪ஂಖ೺ኴ㑻㸪すཎඞဢ㸪㧗ཱྀ㇏㸭6,13-ࢪࣄࢻࣟ࣌ࣥࢱࢭࣥࢆ

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35. ஂಖ೺ኴ㑻㸪⏣ᔱᬛஅ㸪ⓑ஭ோኈ㸪す℈ᣅஓ㸪㧗ཱྀ㇏㸭[60]ࣇ࣮ࣛࣞࣥ-࣌ࣥࢱࢭࣥ ௜ຍయࡢ⮬ᕫ఍ྜ࠾ࡼࡧ⺯ගᣲື㸭2016 ග໬Ꮫウㄽ఍㸭2016 ᖺ 9 ᭶ 36. ᖹᒣ㝯ኴ㑻㸪⏣ᔱᬛஅ㸪㧗ཱྀ㇏㸭ࢹࣥࢻ࣐࣮ࣜᆺศᩓ๣࡜ MoS2࠿ࡽ࡞ࡿ㉸ศᏊ」 ྜయࡢගㄏ㉳㟁Ꮚ⛣ື㸭2016 ග໬Ꮫウㄽ఍㸭2016 ᖺ 9 ᭶ 37. ⏣ᔱᬛஅ㸪࢟࢟ ࢡࣝࢽ࢔࣡ࣥ㸪ஂಖ㝧♸㸪୕Ꮿ⚽᫂㸪㧗ཱྀ㇏㸭༢ᒙ࣮࢝࣎ࣥࢼࣀ ࢳ࣮ࣗࣈ/ࣇࣛࣟࢹࣥࢻࣟࣥ/TiO2 ㉸ศᏊගቑឤ๣ࢆ฼⏝ࡋࡓỈ⣲⏕ᡂ㸭➨ 65 ᅇ㧗 ศᏊウㄽ఍㸭2016 ᖺ 9 ᭶ 38. 㧗ཱྀ㇏㸪⏣୰ᬛ❶㸪すᮧಇ୍㸪⏣ᔱᬛஅ㸪୕Ꮿ⚽᫂㸪㔠᪥㱟㸪኱ᵳ୺⛯㸭࣏ࣜ࢔࣑ ࢻ࢔࣑ࣥࢹࣥࢻ࣐࣮ࣜࢆ฼⏝ࡋࡓ࣮࢝࣎ࣥࢼࣀࢳ࣮ࣗࣈ/ࣄࢻࣟ࢟ࢩ࢔ࣃࢱ࢖ࢺ⼥ ྜ࣐ࢸࣜ࢔ࣝࡢྜᡂ㸭➨ 65 ᅇ㧗ศᏊウㄽ఍㸭2016 ᖺ 9 ᭶ 39. 㧗ཱྀ㇏㸪ᮧୖ⠊Ṋ㸪▼ᮏᐶః㸪୹ᚋభᩯ㸪⏣ᔱᬛஅ㸪୕Ꮿ⚽᫂㸭༢ᒙ࣮࢝࣎ࣥࢼࣀ ࢳ࣮ࣗࣈࢆࢥ࢔࡟ᣢࡘࢼࣀྠ㍈࣡࢖࣮ࣖࢆගቑឤ๣࡟⏝࠸ࡓỈ⣲⏕ᡂ཯ᛂ㸭➨ 65 ᅇ㧗ศᏊウㄽ఍㸭2016 ᖺ 9 ᭶ 40. ⏣୰ᬛ❶㸪すᮧಇ୍㸪⏣ᔱᬛஅ㸪୕Ꮿ⚽᫂㸪㔠᪥㱟㸪኱ᵳ୺⛯㸪㧗ཱྀ㇏㸭ࢹࣥࢻࣜ ࣐࣮ࢆ⏝࠸ࡓ␲ఝయᾮ୰࡛ࡢ࣮࢝࣎ࣥࢼࣀࢳ࣮ࣗࣈ/ࣄࢻࣟ࢟ࢩ࢔ࣃࢱ࢖ࢺࢼࣀࣁ ࢖ࣈࣜࢵࢻ⏕ᡂ㸭➨ 65 ᅇ㧗ศᏊウㄽ఍㸭2016 ᖺ 9 ᭶ 41. すᮧಇ୍㸪⏣୰ᬛ❶㸪⏣ᔱᬛஅ㸪୕Ꮿ⚽᫂㸪㧗ཱྀ㇏㸭஺஫ᾐₕἲࢆ⏝࠸ࡓࢹࣥࢻࣜ ࣐࣮ಟ㣭ࣂࢵ࣮࣮࢟࣌ࣃ࣮ࡢ࢔ࣃࢱ࢖ࢺࢥ࣮ࢸ࢕ࣥࢢ㸭➨ 65 ᅇ㧗ศᏊウㄽ఍㸭 2016 ᖺ 9 ᭶ 42. ୕Ꮿ⚽᫂㸪▼ᮏᐶః㸪ᮧୖ⠊Ṋ㸪⏣ᔱᬛஅ㸪㧗ཱྀ㇏㸭ࢳ࢜࢝ࣝ࣎ࢽࣝⰍ⣲ࢆෆໟ ࡋࡓ࣮࢝࣎ࣥࢼࣀࢳ࣮ࣗࣈࡢ㛤Ⓨ࠾ࡼࡧගゐ፹࡬ࡢᛂ⏝㸭➨ 43 ᅇ᭷ᶵ඾ᆺඖ⣲໬ Ꮫウㄽ఍㸭2016 ᖺ 12 ᭶ 43. ▼ᮏᐶః㸪኱ὠ⿱㈗㸪⏣ᔱᬛஅ㸪୕Ꮿ⚽᫂㸪㧗ཱྀ㇏㸭༢ᒙ࣮࢝࣎ࣥࢼࣀࢳ࣮ࣗࣈ ࡟ෆໟࡉࢀࡓࢳ࢜࢝ࣝ࣎ࢽࣝⰍ⣲ࡢගቑឤᶵ⬟㸭➨ 43 ᅇ᭷ᶵ඾ᆺඖ⣲໬Ꮫウㄽ఍ 㸭2016 ᖺ 12 ᭶ 44. ᮧ ୖ ⠊ Ṋ , す ᕝ ⩧ , ⏣ ᔱ ᬛ அ , ୕ Ꮿ ⚽ ᫂ , 㧗ཱྀ㇏㸭ࢳ࢜࢝ࣝ࣎ࢽࣝⰍ ⣲ ෆ ໟ SWCNT/ࣇࣛࣟࢹࣥࢻࣟࣥ㉸ศᏊ」ྜయࡢྜᡂ࡜ගቑឤస⏝㸭➨ 43 ᅇ᭷ᶵ඾ᆺඖ ⣲໬Ꮫウㄽ఍㸭2016 ᖺ 12 ᭶ 45. ᓥෆᑑᚨ, ㏆⸨᫂ᗈ, ᮌᮧᖾᩗ㸭ள⮫⏺Ỉ᮲௳࡜࣐࢖ࢡࣟ࢟ࣕࣆ࣮ࣛࣜࢆ⤌ࡳྜࢃ ࡏࡓ O/W ࢚࣐ࣝࢩࣙࣥᙧᡂ㐣⛬ࡢ᳨ウ㸭➨ 35 ᅇ⁐፹ᢳฟウㄽ఍㸭2016 ᖺ 11 ᭶ 46. ᒣᮏ೺ኴ, ᓥෆᑑᚨ, ᮌᮧᖾᩗ㸭ࢫࣛࢢὶ࡛ࡢ≀㉁⛣ື≉ᛶ࡟ཬࡰࡍ⏺㠃ࡺࡽࡂࡢ ᙳ㡪㸭➨ 35 ᅇ⁐፹ᢳฟウㄽ఍㸭2016 ᖺ 11 ᭶ 47. ᓥෆᑑᚨ, ⓑ㧨ຬᏘ, ᮌᮧᖾᩗ㸭࣏ࣜࢯ࣮࣒⭷ࡢືⓗ⏺㠃ࢆ฼⏝ࡍࡿࣜࢰࢳ࣒࢘⤖ ᬗ໬ไᚚ㸭໬ᏛᕤᏛ఍➨ 48 ᅇ⛅Ꮨ኱఍㸭2016 ᖺ 9 ᭶ 48. ᓥෆᑑᚨ, ᒾᮧ⨾ᶞ, ᮌᮧᖾᩗ㸭⦪᪉ྥᦂࡽࡂ࡜ᶓ᪉ྥᦂࡽࡂ࡟ᇶ࡙ࡃ⬡㉁⭷⏺㠃 ࡢືⓗᵓ㐀ࡢホ౯㸭໬ᏛᕤᏛ఍➨ 48 ᅇ⛅Ꮨ኱఍㸭2016 ᖺ 9 ᭶

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㞴Ἴᚨ㑻㸪ᓮ⏣┿୍㸪⣚㔝Ᏻᙪ ··· 115 2. Synchrotron X-ray Scattering Measurements of Disordered Materials

Shinji Kohara, Koji Ohara, Hiroo Tajiri, Chulho Song, Osami Sakata, Takeshi Usuki, Yasuhiko Benino, Akitoshi Mizuno, Atsunobu Masuno, Junpei T. Okada, Takehiko Ishikawa, Shinya Hosokawa ··· 116 3. Microscopic structural analysis of lead borate-based glass

Atsushi Mukunoki, Tamotsu Chiba, Yasuhiko Benino, Tomofumi Sakuragi ··· 117 4. Investigation of electronic structure of amorphous niobium oxide based on the

density functional theory calculation of crystalline niobium pentoxide polymorphs Chinatsu Oki, Go Sajiki, Shinichi Sakida, Yasuhiko Benino, Tokuro Nanba ··· 118

ᒸᒣ኱Ꮫ⎔ቃ⌮ᕤᏛ㒊◊✲ሗ࿌Vol.22 ⎔ቃ≀㉁ᕤᏛ⛉

ࢫࣛࢢ࠿ࡽࡢࣜࣥ㈨※ࡢᅇ཰

Recovery of Phosphorous from Slags

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  ᐙᗞࡈࡳ࡞࡝ࡢ୍⯡ᗫᲠ≀ࡢ↝༷⅊ࡸ⁐⼥ࢫࣛࢢ㸪⏘ᴗ࠿ࡽ᤼ฟࡉࢀࡿ㖔ࡉ࠸ࡸởἾ࡞࡝ࡣ㸪SiO2㸪 CaO㸪Al2O3 ࡞࡝ࡢ↓ᶵ⣔ࡢ໬Ꮫᡂศࢆከࡃྵࡳ㸪◁ࡸ▼࡟ఝࡓᛶ≧ࢆᣢࡘࡇ࡜ࡀ▱ࡽࢀ࡚࠸ࡿࠋ໬Ꮫ ⓗ࡟ࡶᏳᐃ࡛࠶ࡿࡓࡵ㸪◁ࡸ◁฼ࡢ௦᭰࡜ࡋ࡚෌฼⏝ࡉࢀ࡚ࡁࡓࠋࡋ࠿ࡋ㸪ᇙࡵ❧࡚ฎศࡉࢀࡿ㔞ࡶᑡ ࡞ࡃ࡞࠸ࡇ࡜࡟ຍ࠼㸪ࣜࣥࡸࢳࢱࣥ࡞࡝㈨※࡜ࡋ࡚౯್ࢆ᭷ࡍࡿᡂศࡀྵࡲࢀ࡚࠸ࡿ࡟ࡶ㛵ࢃࡽࡎ㸪ࣜ ࣥ㈨※࡞࡝࡜ࡋ࡚ࡢ෌฼⏝ࡸ฼ά⏝ࡣ࡞ࡉࢀ࡚࠸࡞࠸ࡢࡀ⌧≧࡛࠶ࡿࠋᙜ◊✲ᐊ࡛ࡣ↓ᶵ⣔෌㈨※໬≀ ࡢ໬Ꮫ⤌ᡂࡀ࢞ࣛࢫ࡟㢮ఝࡋ࡚࠸ࡿࡇ࡜࡟╔┠ࡋ㸪࢞ࣛࢫࡢᛶ㉁ࢆ฼⏝ࡋࡓࣜࢧ࢖ࢡࣝࣉࣟࢭࢫࡢ㛤Ⓨ ࡟ྲྀࡾ⤌ࢇ࡛ࡁࡓࠋ  ◊✲㛤ጞᙜึࡣ㸪࢞ࣛࢫࡢ┦ศ㞳⌧㇟ࢆ฼⏝ࡋࡓ᭷⏝㈨※ࡢ㑅ᢥⓗᅇ཰ࢆ௻ᅗࡋࡓࡓࡵ㸪ศ┦ಁ㐍๣ ࡜ࡋ࡚ B2O3 ࢆ෌㈨※໬≀࡟ῧຍࡋ࢞ࣛࢫ໬ࡉࡏ㸪⇕ฎ⌮࣭㓟ฎ⌮ࢆ⤒࡚ᵓᡂᡂศࢆᅛ┦࡜ᾮ┦࡟ศ㞳 ࡉࡏࡓࠋ㧗⅔Ỉ○ࢫࣛࢢࡸᐙᗞࡈࡳ⁐⼥ࢫࣛࢢࢆ⏝࠸࡚ᐇ㦂ࢆ⾜ࡗࡓ࡜ࡇࢁ㸪SiO2 ྵ᭷㔞ࡢ㧗࠸↓Ⰽ㏱ ᫂࡞࢞ࣛࢫᅛ໬యࢆᚓࡿࡇ࡜࡟ᡂຌࡍࡿ࡜࡜ࡶ࡟㸪ࡑࡢ㝿ࣜࣥࡸࢳࢱࣥࡀ࢞ࣛࢫᅛ໬య࡟㑅ᢥⓗ࡟ྲྀࡾ ㎸ࡲࢀࡿࡇ࡜ࢆぢ࠸ࡔࡋࡓࠋࡇࢀࡼࡾ㸪┦ศ㞳ࡢ㝿࡟ࣜࣥࡸࢳࢱࣥࡀ SiO2 ࣜࢵࢳ࡞࢞ࣛࢫ┦࡟ྲྀࡾ㎸ ࡲࢀࡓ࡜⪃ᐹࡋࡓࠋᐙᗞࡈࡳ⁐⼥ࢫࣛࢢ࡟ࡘ࠸࡚ࡣࡑࡢᚋ㸪┦ศ㞳ࡣ㉳ࡇࡗ࡚࠾ࡽࡎ㸪㓟ฎ⌮᫬ࡢ⁐ゎ ෌ᯒฟ࡟ࡼࡾ࢞ࣛࢫᅛ໬యࡀ⏕ᡂࡋ࡚࠸ࡿࡇ࡜࡞࡝㸪᪂ࡓ࡞▱ぢࢆᚓ࡚࠸ࡿࠋࡲࡓ᭱㏆࡛ࡣ㸪⁐⼥㑏ඖ ࡟ࡼࡿࣜࢧ࢖ࢡࣝࣉࣟࢭࢫࡢ㛤Ⓨ࡟ࡶྲྀࡾ⤌ࢇ࡛࠸ࡿࠋᮏ✏࡛ࡣ㸪ᐙᗞࡈࡳ⁐⼥ࢫࣛࢢ࡜⬺ࣜࣥࢫࣛࢢ ୰ࡢࣜࣥࡢࣜࢧ࢖ࢡࣝࢆ┠ⓗ࡜ࡋࡓ᭱㏆ࡢ◊✲ᡂᯝࢆ⤂௓ࡋࡓࠋ 0 20 40 60 80 100 6 7 8 9 10 Mg P Ca Ti Mn Fe Di str ibuti o n r a te i n to gl a s s ph as e ( % ) Flour dosage (g) (a) B1 crucible 0 20 40 60 80 100 6 7 8 9 10 Mg P Ca Ti Mn Fe Di str ibuti o n r a te i n to gl a s s ph as e ( % ) Flour dosage (g) (b) C1 crucible ᅗ 8 㑏ඖ⁐⼥ฎ⌮࡟ࡼࡿ⬺ࣜࣥࢫࣛࢢᵓᡂᡂศࡢ࢞ࣛࢫ┦࡬ࡢศ㓄⋡ ⬺ࣜࣥࢫࣛࢢ࡟ᑠ㯏⢊㸪SiO2 ࡜ Na2CO3 ࢆῧຍࡋ࡚⁐⼥ࡋࡓ࡜ࡇࢁ㸪ࡿࡘࡰᗏ㒊࡟ Fe ࢆ୺ᡂศ ࡜ࡍࡿ⌫≧ࡢ㔠ᒓࡀ☜ㄆࡉࢀࡓࠋࢫࣛࢢᵓᡂᡂศࡀ⁐⼥ᚋࡢ࢞ࣛࢫ┦࡬ศ㓄ࡉࢀࡓ๭ྜ㸦ᅗ 8㸧 ࡼࡾ㸪እᚄࡢᑠࡉ࡞ C1 ᆺࡿࡘࡰࡢ᪉ࡀ Fe ᡂศࢆࡼࡾከࡃ㑏ඖࡍࡿࡇ࡜ࡀ࡛ࡁࡿ࡜࠸࠼ࡿࠋࡲࡓ P ᡂศࡢྵ᭷㔞࡟ࡘ࠸࡚ࡣ㸪C1 ᆺࡿࡘࡰ࡛ࡣ࡯ࡰࢮࣟ࡟࡞ࡗ࡚࠸ࡓࠋ ڦ࣮࣮࢟࣡ࢻڦ  ᐙᗞࡈࡳ⁐⼥ࢫࣛࢢ㸪⬺ࣜࣥࢫࣛࢢ㸪ࣜࣥᅇ཰ࣉࣟࢭࢫ㸪㑏ඖ⁐⼥ἲ ڦ ᡤ ᒓ ڦ  1)኱Ꮫ㝔⎔ቃ⏕࿨⛉Ꮫ◊✲⛉ ᩍᤵ㸪2)⎔ቃ⟶⌮ࢭࣥࢱ࣮ ຓᩍ㸪3) ኱Ꮫ㝔⎔ቃ⏕࿨⛉Ꮫ◊✲⛉ ෸ᩍᤵ ڦ ᥖ㍕ඛ ڦ 

᪥ᮏ↓ᶵࣜࣥ໬Ꮫ఍Ⓨ⾜㸪Phosphorus Letter, Vol.86, pp.40-46, 2016.

ᒸᒣ኱Ꮫ⎔ቃ⌮ᕤᏛ㒊◊✲ሗ࿌Vol.22 ⎔ቃ≀㉁ᕤᏛ⛉

Synchrotron X-ray Scattering Measurements of Disordered Materials

Shinji Kohara1,2,3,4)_{, Koji Ohara}4)_{, Hiroo Tajiri}4)_{, Chulho Song}2)_{, Osami Sakata}1,2)_{, Takeshi Usuki}5)_{, Yasuhiko} Benino6)_{, Akitoshi Mizuno}7)_{, Atsunobu Masuno}8)_{, Junpei T. Okada}9)_{, Takehiko Ishikawa}9)_{, Shinya Hosokawa}10)

ڦSummary ڦ

With the advent of third-generation synchrotron sources and the development of light source techniques, X-ray scattering techniques have become feasible, leading to new approaches for studying the structures of disordered materials in a quantitative manner. We introduce a dedicated diffractometer for high-energy total X-ray scattering measurement and a newly developed anomalous X-ray spectrometer at SPring-8. As advanced methodologies for the measurement of liquids, we now offer three state-of-art levitation instruments for aerodynamic levitation, electrostatic levitation, and acoustic levitation at the SPring-8 beamlines, covering a wide temperature range of í40-3000qC. Furthermore, scientific investigations of glasses, liquids, and amorphous materials reported in the last five years at SPring-8 are reviewed.

Figure 6: D'LIIHUHQWLDOVWUXFWXUHIDFWRUVǻܵ(ܳ) for Nb in 25BaO-50Nb2O5-25P2O5glass together with the total structure factor ܵ(ܳ) obtained by HEXTS measurement and (b) total correlation functions ܶ(ݎ) for 25BaO-50Nb2O5-25P2O5 glass. ܵ(ܳ) and ܶ(ݎ) for HEXTS are displaced upward by 3 and 5 units, respectively, for clarity. The solid and dashed curves of ܶ(ݎ) were obtained by Fourier transformation with ܳmax = 9.9 Åí1and 25 Åí1, respectively.

ڦ Key word ڦ

High-energy X-ray Scattering, Anomalous X-ray Scattering, Glass, Liquid, Amorphous Materials. ڦAffiliation ڦ

1) Quantum Beam Unit, National Institute for Materials Science (NIMS) 2) Synchrotron X-ray Station at SPring-8, NIMS

3) Information Integrated Materials Research Unit, Research Center For Information Integrated Materials, NIMS 4) Research & Utilization Division, Japan Synchrotron Radiation Research Institute

5) Graduate School of Science and Engineering, Yamagata University 6) Graduate School of Environmental and Life Science, Okayama University 7) Department of Physics, Gakushuin University

8) Institute of Industrial Science, The University of Tokyo

9) Institute of Space and Astronautical Science (ISAS), Japan Aerospace Exploration Agency (JAXA) 10) Department of Physics, Graduate School of Science and Technology, Kumamoto University ڦ P r i n t i n g ڦ

Zeitschrift für Physikalische Chemie, 2016; Vol. 230(3), pp.339-368, 2016.3, doi: 10.1515/zpch-2015-0654. Peer-reviewed, Language: English

ᒸᒣ኱Ꮫ⎔ቃ⌮ᕤᏛ㒊◊✲ሗ࿌Vol.22 ⎔ቃ≀㉁ᕤᏛ⛉

Microscopic structural analysis of lead borate-based glass

Atsushi Mukunoki1)_{, Tamotsu Chiba}1)_{, Yasuhiko Benino}2)_{, Tomofumi Sakuragi}3)

ڦSummary ڦ

The development of an iodine immobilization technique that can retain radioactive iodine in a waste form for a long period and constrain its leaching into pore water is necessary in order to secure the long term safety of geological disposal of transuranic waste. Lead borate glass vitrified at a low temperature is regarded as a promising material for immobilizing the Iodine-129 that is recovered from spent AgI filters used in reprocessing plants in Japan.

Structural models of lead borate-based glass were constructed by the Reverse Monte Carlo (RMC) method based on experimental information from such sources as neutron and high-energy X-ray diffraction, XAFS, and 11_{B MAS NMR spectroscopic analyses.}

The neutron structure factors [SN(Q)] and X-ray structure factors [SX(Q)] that were calculated by RMC and measured by J-PARC/MLF-BL20 and SPring-8/BL04B2 suggest that RMC results are consistent with experimental measurements and reveal that structural information of neutrons is indispensable for analyzing the surrounding boron structures.

Fig. 7. Comparison of structure factors between RMC calculations and experimental results.

Fig. 8 (left). A typical structure of Pb

coordination with shared corners and edges.

Fig. 9 (right). Pb-I binding in the structural

model of BPI vitrified glass ڦ Key word ڦ

Iodine, Lead borate glass, Reverse Monte Carlo method, Neutron structure factor ڦAffiliation ڦ

1) JGC Corporation

2) Graduate School of Environmental and Life Science, Okayama University, 3) Radioactive Waste Management Funding and Research Center

ڦ P r i n t i n g ڦ

Progress in Nuclear Energy, 2016, Vol. 91, pp.339-344, 2016.8. , doi: 10.1016/j.pnucene.2016.05.008

ᒸᒣ኱Ꮫ⎔ቃ⌮ᕤᏛ㒊◊✲ሗ࿌Vol.22 ⎔ቃ≀㉁ᕤᏛ⛉

Investigation of electronic structure of amorphous niobium oxide based on the

density functional theory calculation of crystalline niobium pentoxide polymorphs

Chinatsu Oki1)_{, Go Sajiki}2)_{, Shinichi Sakida}3)_{, Yasuhiko Benino}4)_{, Tokuro Nanba}5)

ڦSummary ڦ

Electronic structure of amorphous niobium oxide prepared by a sputtering method was investigated based on optical absorption and photoelectron spectroscopies. In the valence band photoelectron spectra, broad peaks without any characteristic components were observed. Then, theoretical calculations based on a density functional theory were performed to interpret the experimental spectra by using three Nb2O5 polymorphs. Among the polymorphs, M-phase with tetragonal structure showed better reproducibility than the other B- and R-phases with monoclinic structure. It was finally concluded that the amorphous niobium oxide had a similar electronic structure to M-Nb2O5, and it was supposed that the broad feature in the photoelectron spectra was due to the broad distribution of NbO bonds in NbO6polyhedra, which was characteristic in M-Nb2O5.

(a) XPS (b) UPS

Fig. 5. (a) XPS and (b) UPS of B-, R-, and M-phases of Nb2O5 obtained from DFT calculations and experimental spectra of amorphous NbOx.

ڦ Key word ڦ

Niobium oxide, Electronic structure, Photoelectron spectrum, Optical absorption spectrum, Density functional theory calculation

ڦAffiliation ڦ

1) Student, Graduate School of Environmental and Life Science

2) Technical Personnel, National Institute of Technology, Kagawa College 3) Assistant Professor, Environmental Management Center

4) Associate Professor, Graduate School of Environmental and Life Science 5) Professor, Graduate School of Environmental and Life Science

ڦ P r i n t i n g ڦ

Journal of the Ceramic Society of Japan, 2016, Vol. 124(12), pp.1221-1225, 2016.12, .doi:10.2109/jcersj2.16180. Peer-reviewed, Language: English

ҡಅᛯ૨ᴾ

ࢭ࣑ࣛࢵࢡࢫᮦᩱᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸㞴Ἴᚨ㑻࣭⣚㔝Ᏻᙪ࣭ᓮ⏣┿୍㸧 1. ࣉ࣮ࣟࣈ࢖࢜ࣥࢆ⏝࠸ࡓ࢞ࣛࢫࡢሷᇶᗘホ౯ 2. ࢣ࢖⣲ࠊࣜࣥ⨨᥮㠀ᬗ㉁ࣇ࢙ࣜࣁ࢖ࢻࣛ࢖ࢺࡢᵓ㐀ࣔࢹࣜࣥࢢ 3. 㑏ඖ⁐⼥ἲ࡟ࡼࡿ෌㈨※໬≀࠿ࡽࡢࣜࣥᅇ཰ࣉࣟࢭࢫࡢ㛤Ⓨ 4. SnO-ZnO-P2O5⣔࢞ࣛࢫࡢⓎග≉ᛶ 5. X ⥺␗ᖖᩓ஘࡟࠾ࡅࡿᙉᗘ⿵ṇᡭἲࡢ☜❧  ↓ᶵᶵ⬟ᮦᩱ໬Ꮫ◊✲ᐊ㸦ᣦᑟᩍဨ㸸டᓥḠ୍࣭すᮏಇ௓㸧 6. TiO2 ගゐ፹⾲㠃࡟ࢩࣜࣝᇶࢆᑟධࡋࡓ」ྜⷧ⭷ࡢస〇࡜ࢭࣝࣇࢡ࣮ࣜࢽࣥࢢ≉ᛶ ホ౯ 7. Fe ࢆྵࢇࡔᒙ≧」Ỉ㓟໬≀ (LDH) ࡟ࡼࡿ㐣㓟໬Ỉ⣲ศゎ 8. Ỉ୰࡛㉸᧕Ἔᛶࢆ♧ࡍ㓟໬ࢳࢱࣥࢳ࣮ࣗࣈ࠿ࡽࡢᚤᑠἜ⁲ࡢศὀ 9. CH4ࢆ⇞ᩱ࡟⏝࠸ࡓ SOFC ࡟࠾ࡅࡿ࢔ࣀ࣮ࢻࡢ᳨ウ 10. ࢻࣛ࢖ࢤࣝࢥࣥࣂ࣮ࢪࣙࣥἲ࡟ࡼࡿⅣ໬ࢣ࢖⣲ᇶᯈୖ࡬ࡢ ZSM-5 ࡢᡂ⭷ 11. ࢮ࢜ࣛ࢖ࢺࢆཎᩱ࡟⏝࠸ࡓࢪ࣏࣐࣮࢜ࣜࡢస〇 12. 㓟໬ࢳࢱࣥ⾲㠃࡟࠾ࡅࡿ✀ࠎࡢ⬡⫫㓟ࡢ⃿ࢀᣲື  ᭷ᶵᶵ⬟ᮦᩱᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸㧗ཱྀ㇏࣭⏣ᔱᬛஅ㸧 13. ༢ᒙ࣮࢝࣎ࣥࢼࣀࢳ࣮ࣗࣈ/ࣇࣛࣟࢹࣥࢻࣟࣥ/TiO2ྠ㍈ࢼࣀ࣡࢖࣮ࣖࡢస〇᮲௳᭱ 㐺໬࡜Ỉ⣲Ⓨ⏕ගቑឤ๣࡬ࡢᛂ⏝ 14. 1,10-ࣅࢫ(ࢹࢩࣟ࢟ࢩ)ࢹ࢝ࣥࢆࢥ࢔࡟ᣢࡘࢹࣥࢻ࣐࣮ࣜࢆ⏝࠸ࡓⰍ⣲ෆໟ࣮࢝࣎ ࣥࢼࣀࢳ࣮ࣗࣈࡢ⾲㠃ಟ㣭࡜ගቑឤᶵ⬟ 15. 1,10-ࣅࢫ(ࢹࢩࣟ࢟ࢩ)ࢹ࢝ࣥࢆࢥ࢔࡟ᣢࡘࢹࣥࢻ࣐࣮ࣜࢆ⏝࠸ࡓ࣮࢝࣎ࣥࢼࣀࢳ ࣮ࣗࣈ/ࣄࢻࣟ࢟ࢩ࢔ࣃࢱ࢖ࢺࢼࣀࣁ࢖ࣈࣜࢵࢻࡢస〇 16. N,N̓-ࣅࢫ(2-࢚ࢳࣝ࣊࢟ࢩࣝ)⨨᥮ 6,13-ࢪࣄࢻࣟ࣌ࣥࢱࢭࣥࣅࢫ࢖࣑ࢻࡢྜᡂ࡜ᛶ ㉁ 17. ࢔ࣥࢺࣜࣝࢹࣥࢻࣟࣥࢆ⏝࠸ࡓ MoS2ࡢ≀⌮ಟ㣭࡜⺯ගᾘගᣲື 18. (8,3), (7,5), ࠾ࡼࡧ (6,5)༢ᒙ࣮࢝࣎ࣥࢼࣀࢳ࣮ࣗࣈගゐ፹࡬ࡢⓑ㔠㘒యᢸᣢ࡜άᛶ ホ౯  ⎔ቃ㧗ศᏊᮦᩱᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸ᮌᮧ㑥⏕࣭ᒣᓮៅ୍㸧 19. 㔜ྜ┦ኚ໬ࢆ฼⏝ࡋࡓ࢔࣑ࣛࢻ୰✵ᚤ⢏Ꮚࡢ⢏ᚄไᚚ 20. ࡏࢇ᩿ὶືሙ࡛ࡢ࢜ࣜࢦ࣐࣮⤖ᬗ໬ࢆ฼⏝ࡋࡓ࣏ࣜங㓟ࡢගᏛศ๭㔜ྜ 21. ୧ᮎ➃ᇶࡢ࠿ࡉ㧗ࡉࡀ␗࡞ࡿࢸࣞࢣࣜࢵࢡ࣏࢚ࣜࢳࣞࣥࡢࣈࣞࣥࢻ⣔ࡢ᰾⏕ᡂᣲ ື 22. 2,5-ࣇࣛࣥࢪ࢝ࣝ࣎ࣥ㓟࡜࢝ࣝࢻᆺࢪ࣮࢜ࣝ࡟ࡼࡿ㧗ᛶ⬟ⰾ㤶᪘࣏࢚ࣜࢫࢸࣝࡢㄪ 〇

23. ⎔≧࣏ࣜங㓟ࡢ࢚ࢫࢸࣝ஺᥮཯ᛂ࡟ࡼࡿศᏊ㔞ࡢኚ໬࡜⤖ᬗ໬᰾๣࡜ࡋ࡚ࡢ᭷⏝ ᛶࡢ᳨ウ  ⎔ቃࣉࣟࢭࢫᕤᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸ᮌᮧᖾᩗ࣭ᓥෆᑑᚨ㸧 24. ࢜ࢡࢳࣝ㓟ࢫࢬ」ྜ໬࣏ࣜࢯ࣮࣒ࢆ཯ᛂሙ࡜ࡍࡿ࣏ࣜங㓟㔜ྜ཯ᛂ 25. ࢔࣑ࣟ࢖ࢻᛶࢱࣥࣃࢡ㉁ࡢ⭷⾲㠃࡬ࡢ⵳✚࡜⏺㠃ࡺࡽࡂ࡜ࡢ㛵ಀ 26. ࣋ࢩࢡࣝ/࢔࣑ࣟ࢖ࢻ」ྜయࢆ⏝࠸ࡓ᪂つ࡞㉸ศᏊ࣐ࢩࢼ࣮ࣜࡢ๰〇 27. ᪂つ࡞཯ᛂศ㞳ᮦࢆ┠ᣦࡋࡓ⬡㉁/㧗ศᏊ/ゐ፹」ྜ໬࡟㛵ࡍࡿᇶ♏ⓗ᳨ウ 28. ࢔࣑ࣟ࢖ࢻᙧᡂไᚚࢆ┠ᣦࡋࡓ࣏ࣜங㓟ࣂ࢖࢜࢖ࣥࢱ࣮ࣇ࢙࣮ࢫࡢ㛤Ⓨ 29. ஺ᕪ࢔ࣝࢻ࣮ࣝ཯ᛂ࡟ࡼࡿࢪࣕࢫ࣑ࣥ࢔ࣝࢹࣄࢻࡢྜᡂ࡟ཬࡰࡍ࣏ࣜࢯ࣮࣒ࡢῧ ຍຠᯝ 30. ள⮫⏺Ỉங໬ἲ࡜⁐፹ᣑᩓἲࢆ⏝࠸ࡓ࣋ࢩࢡࣝㄪ〇ἲࡢ㛤Ⓨ  ⎔ቃ཯ᛂᕤᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸ຍ⸨჆ⱥ࣭࢔ࢬࣁ࢘ࢵࢹ࢕ࣥ㸧 31. ㉸㡢Ἴ↷ᑕ࡟ࡼࡿᾮ㸫ᾮ⣔ศᩓ┦ࡢᚤ⣽໬ᣲື 32. ✀ࠎࡢ᧠ᢾ᧯స࡟࠾ࡅࡿᾮ୰ᚤ⢏Ꮚࡢจ㞟࣭ྜయ㏿ᗘ 33. 3 ᡂศ⣔㔠ᒓ㓟໬≀࡟ࡼࡿ▼Ⅳ࢞ࢫ໬࢞ࢫ୰࠿ࡽࡢỈ㖟㝖ཤ 34. Fischer-Tropsch ྜᡂ⏝ Co/E-zeolite ゐ፹ࡢㄪ〇ἲࡢ᳨ウ 35. ࣂ࢞ࢫࡢ࢞ࢫ໬࡛⏕ࡌࡿࢱ࣮ࣝࡢศゎ⏝ゐ፹ࡢ㛤Ⓨ 36. 㓟ฎ⌮࡟ࡼࡿᗫኴ㝧㟁ụࣔࢪ࣮ࣗࣝ⏤᮶ࡢ⢊య࠿ࡽࡢࢩࣜࢥࣥ⣧໬

̲ٟᛯ૨ᴾ

ࢭ࣑ࣛࢵࢡࢫᮦᩱᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸㞴Ἴᚨ㑻࣭⣚㔝Ᏻᙪ࣭ᓮ⏣┿୍㸧 1. 㒔ᕷࡈࡳ⁐⼥ࢫࣛࢢࡢᵓᡂඖ⣲ࡢ⁐ฟᣲື 2. 㔠ᒓࣆࣥ㈏ධ࡟క࠺࢞ࣛࢫࡢ⤖ᬗ໬ 3. ィ⟬ᶵࢩ࣑࣮ࣗࣞࢩࣙࣥ࡟ࡼࡿ㠀ᬗ㉁ NbOxⷧ⭷ࡢᵓ㐀࡜㟁Ꮚ≧ែゎᯒ 4. Ag+_-Na+_{㟁⏺࢖࢜ࣥ஺᥮࡟ࡼࡾࢸࣝࣛ࢖ࢺ࢞ࣛࢫ୰࡟⏕ᡂࡍࡿ㖟ᚤ⢏Ꮚࡢ≧ែ࡜ග} ᑟἼ≉ᛶ  ↓ᶵᶵ⬟ᮦᩱ໬Ꮫ◊✲ᐊ㸦ᣦᑟᩍဨ㸸டᓥḠ୍࣭すᮏಇ௓㸧 5. Ni0.8Cu0.2/㟁ゎ㉁ࢧ࣮࣓ࢵࢺ࠿ࡽ࡞ࡿ SOFC ⏝ከᒙ࢔ࣀ࣮ࢻࡢホ౯ 6. ࢮ࢜ࣛ࢖ࢺࣂࣝࢡయࢆᢸయ฼⏝ࡋࡓ࣓ࢱࣥ࠿ࡽࡢ࣋ࣥࢮࣥྜᡂ 7. Si/Al ẚࡢ␗࡞ࡿࢮ࢜ࣛ࢖ࢺࣂࣝࢡయࡢస〇࡜ࡑࡢศ㞳ᛶ⬟ࡢホ౯ 8. ㉸㡢Ἴฎ⌮ࡀ␗࡞ࡿ⾲㠃ᙧែࡢ㓟໬ࢳࢱࣥ⾲㠃ࡢỈ୰࡟࠾ࡅࡿἜࡢ⃿ࢀᛶ࡟୚࠼ ࡿᙳ㡪 9. Mg/Al ẚࡢ␗࡞ࡿᒙ≧」Ỉ㓟໬≀㸦LDH㸧ศᩓࢤࣝࢆ฼⏝ࡋࡓ LDH ᅛ໬యࡢస〇  ᭷ᶵᶵ⬟ᮦᩱᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸㧗ཱྀ㇏࣭⏣ᔱᬛஅ㸧 10. SnO2/㓟໬ࢢࣛࣇ࢙ࣥࢼࣀࣁ࢖ࣈࣜࢵࢻࡢྜᡂ࡜࣮ࣟࢲ࣑ࣥ B ྍどගศゎ཯ᛂ࡬ࡢ ᛂ⏝ 11. N,N'-ࢪࢺࣜࢹࢩࣝ⨨᥮ 6,13-ࢪࣄࢻࣟ࣌ࣥࢱࢭࣥࣅࢫ࣑ࢻࡢྜᡂ࡜ᛶ㉁  ⎔ቃ㧗ศᏊᮦᩱᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸ᮌᮧ㑥⏕࣭ᒣᓮៅ୍㸧 12. PET ᶞ⬡ࡢ࢔ࢵࣉࢢ࣮ࣞࢻᆺࣜࢧ࢖ࢡࣝἲࡢ㛤Ⓨ 13. 㧗ศᏊ」ྜᮦᩱࡢ࣏࣡ࣥࢵࢺྜᡂࢆ┠ᣦࡋࡓ࣏࢚ࣜࢳࣞࣥࡢ୰࡛ࡢ࣏ࣜ࢖࣑ࢻ⤖ ᬗࡢㄪ〇 14. ୺㙐࡟୍ᐃ๭ྜ࡛࣓ࢳࣝᇶࡀᑟධࡉࢀࡓ⎔≧ཬࡧ┤㙐≧࣏࣓ࣜࢳࣞࣥࡢ⤖ᬗ໬࡟ ཬࡰࡍࢺ࣏ࣟࢪ࣮ຠᯝ 15. పศᏊ㔞⎔≧࣏࢚ࣜࢳࣞࣥࡢ⤖ᬗ໬࡟ཬࡰࡍᢡࡾࡓࡓࡳࡢຠᯝ࡜┤㙐㢮ఝయ࡜ࡢ ࣈࣞࣥࢻ࡟ࡼࡿ⤖ᬗ໬ไᚚ  ⎔ቃࣉࣟࢭࢫᕤᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸ᮌᮧᖾᩗ࣭ᓥෆᑑᚨ㸧 16. ࢱࣥࣃࢡ㉁ࡢ␗ᖖ⵳✚࣭⤖ᬗ໬ࢆไᚚྍ⬟࡞ᮦᩱ⏺㠃ࡢタィ 17. ள⮫⏺Ỉங໬ἲ࡟ࡼࡿࢼࣀ࢚࣐ࣝࢩࣙࣥᙧᡂᶵᵓࡢゎ᫂ 18. ⢾ಟ㣭⬡㉁⭷⏺㠃ࡢ≉ᛶホ౯࡜ศᏊㄆ㆑ᶵ⬟࡬ࡢᙳ㡪㹼࢔࣑ࣟ࢖ࢻᙧᡂࢆ஦౛࡟ 㹼 19. ᭷⏝࡞ࣂ࢖࣐࢜ࢫኚ᥮཯ᛂ࡟ཬࡰࡍ࣏ࣜࢯ࣮࣒ࡢಁ㐍ຠᯝ 20. ள⮫⏺Ỉங໬ἲ࡟ࡼࡿ㧗ศᏊྵ᭷࢚࣐ࣝࢩࣙࣥࡢㄪ〇࡜⾲㠃ᨵ㉁ᢏ⾡࡬ࡢᛂ⏝ 

⎔ቃ཯ᛂᕤᏛ◊✲ᐊ㸦ᣦᑟᩍဨ㸸ຍ⸨჆ⱥ࣭࢔ࢬࣁ࢘ࢵࢹ࢕ࣥ㸧 21. ప⃰ᗘ࣋ࣥࢮࣥࡢ᏶඲㓟໬࡟㐺ࡋࡓ㓟໬㖡୍㓟໬ࢥࣂࣝࢺ⣔ゐ፹ࡢㄪ〇࡜ホ౯ 22. ὶ㏻ᘧᐜჾ࡟ࡼࡿ〇㗰ࢫࣛࢢ࠿ࡽᾏỈ୰࡬ࡢ࢔ࣝ࢝ࣜ⁐ฟᣲື 23. ࢮࣟ౯㕲⢊ࢆ⏝࠸ࡓỈ୰ள㖄࢖࢜ࣥࡢ㝖ཤ㏿ᗘ 24. ගࣇ࢓࢖ࣂ⾲㠃࡬ࡢ ZSM-5 ⭷ྜᡂ