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㸦㸱㸧䭜 Ꮥ♸ࠊࠕࣜࢳ࣒࢘࢜ࣥ㟁ụ㧗ᐜ㔞ṇᴟά≀㉁Li2MnSiO4ࡢస〇ホ౯ࠖ
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㸦㸳㸧ᰗ ኴࠊࠕࢰࣝ-ࢤࣝἲ࠾ࡼࡧW/O࢚࣐ࣝࢩࣙࣥἲࡼࡿEu3+ྵ᭷Ta2O5⌫≧⢏Ꮚ⺯
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㸦㸷㸧ᰘ㔝 ㅬኴᮁࠊࠕSiᇶᯈୖ⦪ᆺ῝⣸እLEDࡢ㛤Ⓨࠖ
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㸦㸯㸷㸧 ྜྷᆏṇࠊࠕ◁ࡢ㣕⩧య㧗㏿㈏ධᐇ㦂࠾ࡅࡿᣲືィ ᡭἲࡢ☜❧࣐ࢢࢿࢵࢺ࣭
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㸦㸰㸮㸧 Ώ㑔ᬛஅࠊࠕ7L$O9 ྜ㔠ࡢ㧗ࡦࡎࡳຍᕤࡼࡿㄪ⤌⧊ไᚚࠖ
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㸦㸰㸵㸧 ୗᇛၨ♸ࠊࠕ↓㟁ゎ 1L ࡵࡗࡁࢆ⏝࠸ࡓ⣧ 1L ࡢ⤌⧊ไᚚኚᙧᣲືࠖ
㸦㸰㸶㸧 7RQJ%Rࠊࠕ686/ ࣮࢜ࢫࢸࢼࢺ⣔ࢫࢸࣥࣞࢫ㗰ࡢຊᏛ≉ᛶཬࡰࡍㄪ⤌⧊
ࡢᙺࠖ
㸦㸰㸷㸧 ᒣཱྀ⌮ࠊࠕ&R&U0R ྜ㔠ㄪ⤌⧊ᮦᩱࡢ⤌⧊ᙧᡂ࠾ࡼࡧኚᙧᣲືࠖ
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㸦㸱㸯㸧 ஂᮌ⚈ᖹࠊࠕ7L$O9 ྜ㔠ࡢኚᙧᣲືཬࡰࡍㄪ⤌⧊ไᚚࡢᙳ㡪ࠖ
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㸦㸱㸱㸧 ᒣ⏣㍤᫂ࠊࠕ3=7 ࢺࣛࣥࢫࢹ࣮ࣗࢧࡢᅽ㟁≉ᛶཬࡰࡍᚤどⓗᦆയࡢᙳ㡪ࠖ
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㸦㸱㸳㸧 ྜྷ⏣ᶞࠊࠕ&)53 ᶵᲔ᥋ྜ⥅ᡭࡢᙉᗘ≉ᛶཬࡰࡍ⧄⥔㓄ྥࡢᙳ㡪ࠖ
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◊✲ࡢᴫせ ᙜヱ㢧ᚤ㙾ࡣ㸪ձ᪥❧ࣁࢸࢡࣀࣟࢪ࣮ࢬ〇ప┿✵ศᯒ㉮ᰝ㟁Ꮚ㢧ᚤ 㙾 SU6600㸪ղ࢜ࢵࢡࢫࣇ࢛࣮ࢻ࣭ࣥࢫࢺ࣓ࣝࣥࢶ〇࢚ࢿࣝࢠ࣮ศᩓᆺ㹖⥺ඖ
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◊✲ᡂᯝࡢᴫせࢆ௨ୗ♧ࡍ㸬 Ϩ㸬SU6600ࢆ⏝࠸ࡓ◊✲ᡂᯝ㸸 ࣭ྛ✀◚㠃ࡢほᐹ㸪ࡁᑍἲࡢ ᐃ ࣭◚㠃พฝࡢ㸱ḟඖ㸪FRASTAゎᯒ ࣭ヨᩱ⾲㠃ᛶ≧ࡢほᐹ ࡞
ϩ㸬EDSࢆ⏝࠸ࡓ◊✲ᡂᯝ㸸 ࣭ྛ✀ᮦᩱࡢᏛᡂศศᯒ ࣭ᮦᩱ୰ࡢඖ⣲ศᕸศᯒ ࡞
Ϫ㸬EBSDࢆ⏝࠸ࡓ◊✲ᡂᯝ㸸 ࣭⤖ᬗ᪉ゎᯒ
࣭㞟ྜ⤌⧊⏕ᡂ≧ែศᯒ ࣭⤖ᬗ⢏ᚄゎᯒ
࣭ෆ㒊ࡦࡎࡳゎᯒ ࡞
−109−
◊✲ᐊࡢᙜヱ⨨ࢆ⏝࠸ࡓ⤖ᯝࢆྵࡴ◊✲ᡂᯝࢆ௨ୗ♧ࡍ㸬 䛆ㄽᩥ䛇㻌
1. Benjamin Guennec, Akira Ueno, Tatsuo Sakai, Masahiro Takanashi, Yu Itabashi and Mie Ota, "Dislocation-based Interpretation on the Effect of the Loading Frequency on the Fatigue Properties of JIS S15C Low Carbon Steel", International Journal of Fatigue, Vol.70, pp.328-341, 2015.
2. Shoichi Kikuchi, Yuta Nakamura, Akira Ueno and Kei Ameyama, "Development of Low Temperature Nitriding Process and Its Effects on the 4-points Bending Fatigue Properties of Commercially Pure Titanium", Advanced Materials Research, No.891-892, pp.656-661, 2014.
3. Benjamin Guennec, Akira Ueno, Tatsuo Sakai, Masahiro Takanashi and Yu
Itabashi, "Effect of the Loading Frequency on Fatigue Properties of JIS S15C Low Carbon Steel and Some Discussions Based on Micro-plasticity Behavior",
International Journal of Fatigue, Vol.66, pp.29-38, 2014.
4. Masahiro Nawa, Naoki Kurizoe, Yasunori Okamoto and Akira Ueno,
"Transformation-induced Plastic Deformation in Ce-TZP/alumina Nanocomposite Generated During Fatigue Tests at Room Temperature", Journal of the European Ceramic Society, Vol.34, pp.4337-4345, 2014.
5. ୖ㔝 ᫂㸪す⏣⚽㸪ᐑᕝ㐍㸪ᒣ⏣⪔㸪⳥ụᑗ୍㸪ࠕ¥area ἲࢆ⏝࠸ࡓ
࣑ࣝࢲ࢝ࢫࢺྜ㔠ࡢ⑂ປ㝈ᗘண ࠖ㸪ᮦᩱ㸪Vol.63, No.12, pp.844-849, 2014.
6. ྥᒣᏕ㸪ⰼᮌᏹಟ㸪ᒸ⏣᠇ྖ㸪ቃ⏣ᙲⰾ㸪୰ᮧ⿱⣖㸪Ⳣ⏣ ῟㸪すᕝ ฟ㸪
ୖ㔝 ᫂㸪㓇㐩㞝㸪ࠕ㟼ⓗᙉᗘ≉ᛶ್ࡼࡿᶵᲔᵓ㐀⏝Ⅳ⣲㗰ࡢS-N ᭤⥺
㛵ࡍࡿ⤫ィⓗ᥎ᐃࠖ㸪ᮦᩱ㸪ᥖ㍕ྍ.
7. ୕ᾆᣅ㸪䬟ཎ㝯அ㸪୕ᮧ┿࿃㸪ஂ㔝㝯⣖㸪⳥ụᑗ୍㸪ୖ㔝᫂㸪㓇㐩㞝㸪ࠕࣇ
ࣛࢡࢺࢢࣛࣇࡼࡿ⇕㛫ᡂᙧࡤࡡ⏝㗰SUP7 ࡢෆ㒊㉳Ⅼᆺ⑂ປ◚ቯ࣓࢝
ࢽࢬ࣒ࡢ᳨ウࠖ㸪ᮦᩱ㸪ᥖ㍕ྍ.
8. Sanjay Kumar Vajpai, Mie Ota, Tomoyuki Watanabe, Ryo Maeda, Tatsuya Sekiguchi, Takayuki Kusaka and Kei Ameyama, "The Development of High Performance Ti-6Al-4V Alloy via a Unique Microstructural Design with Bimodal Grain Size Distribution", Metallurgical and Materials Transactions A, Vol.64, No.2, pp.903-914, 2015.
9. Mie Ota, Sanjay Kumar Vajpa, Ryota Imao, Kazuaki Kurokawa and Kei Ameyama,
"Application of High Pressure Gas Jet Mill Process to Fabricate High Performance Pure Titanium", J. Materials Transactions, Vol.56, No.1, pp.154-159, 2015.
10. Nurul Nadia MEHMUD, Sanjay Kumar Vaipai and Kei Ameyama, "Fabrication of
Yttria Stabilized Zirconia-Silicon Carbide Composites with High Strength and High Toughness by Spark Plasma Sintering of Mechanically Milled Powders", J.
Materials Transactions, Vol.55, No.12, pp.1827-1833, 2014.
11. Z. Zhang, D. Orlov, S. K. Vajpai, B. Tong and K. Ameyama, "Importance of Bimodal Structure Topology in the Control of Mechanical Properties of a Stainless Steel", J. Advanced Engineering Materials, DOI: 10.1002/adem.201400358, 2014.
12. R. Yoshida, T. Tsuda, H. Fujiwara, H. Miyamoto and K. Ameyama, "Annealing Effect on Mechanical Properties of Ti-Al Alloy/Pure Ti Harmonic-Structured Composite by MM/SPS Process", Materials Science and Engineering, 63, doi:10.1088/1757-899X/63/1/012031, 2014.
13. Y. Tsuzuki, H. Fujiwara, H. Miyamoto and K. Ameyama, "Deformation behavior of high speed steel/low Carbon steel composite with harmonic structure by MM/SPS process", Materials Science and Engineering, 63,
doi:10.1088/1757-899X/63/1/012029, 2014.
14. Sanjay Kumar Vajpai, Kei Ameyama, Mie Ota, Tomoyuki Watanabe, Ryo Maeda, Tatsuya Sekiguchi, Guy Dirras and David Tingaud, "High performance Ti-6Al-4V alloy by creation of harmonic structure design", Materials Science and
Engineering, 63, doi:10.1088/1757-899X/63/1/012030, 2014.
15. M. Ota, K. Sawai, M. Kawakubo, S. K. Vajpai and K. Ameyama, "Harmonic structure formation and deformation behavior in a (Į + Ȗ) two phase stainless steel", Materials Science and Engineering, Vol.63, No.1, pp.12-27, 2014.
16. Yasuhiro Kanoko, Kei Ameyama, Shigeo Tanaka and Benjamin Hefler, "Production of ultra-thin porous metal paper by applying the fibre space holder method", Powder Metallurgy, Vol.57, No.3, pp.1-5, 2014.
17. Mie Ota, Keisuke Shimojo, Shun Okada, Sanjay Kumar Vajpai and Kei Ameyama,
"Harmonic Structure Design and Mechanical Properties of Pure Ni Compact", Journal of Powder Metallurgy & Mining, Vol.3, No.1, Doi:0.4172/2168-9806.
1000122, 2014.
18. Ruixiao Zheng, Yanbo Sun, Wenlong Xiao, Kei Ameyama and Chaoli Ma,
"Nanostructured Al87Ni8.5Ce3Fe1Cu0.5 alloy prepared by mechanical milling spark plasma sintering and hot extrusion", Materials Science & Engineering A, Vol.606, No.3, pp.426-433, 2014.
19. Dmitry Orlov, Daniele Pelliccia, Xiya Fang, Laure Bourgeois, Nigel Kirby, Andrei Y Nikulin, Kei Ameyama and Yuri Estrin, "Particle evolution in Mg-Zn-Zr alloy processed by integrated extrusion and equal channel angular pressing: Evaluation by electron microscopy and synchrotron small-angle X-Ray scattering", Acta Materiala, Vol.3, No.1, Doi:0.4172/2168-9806. 1000122, 2014.
−111−
Journal of Powder Metallurgy & Mining, Vol.72, pp.110-124, 2014.
21. Choncharoen Sawangrat, Shota Kato, Dmitry Orlov and Kei Ameyama,
"Harmonic-structured copper: performance and proof of fabrication concept based on severe plastic deformation of powders", Journal of Materials Science, Vol.3, No.1, Doi:0.4172/2168-9806. 1000122, 2014.
22. Mie Ota, Keisuke Shimojo, Shun Okada, Sanjay Kumar Vajpai and Kei Ameyama,
"Harmonic Structure Design and Mechanical Properties of Pure Ni Compact", Journal of Powder Metallurgy & Mining, Vol.5, 2014.
23. Choncharoen Sawangrat, Osamu Yamaguchi, Sanjay Vajpai and Kei Ameyama,
"Harmonic structure design of Co-Cr-Mo alloy with outstanding mechanical properties", Advanced Materials Research, No.939, pp.60-67, 2014.
䛆ᅜ㝿㆟ 㻼㼞㼛㼏㼑㼑㼐㼕㼚㼓㼟䛇㻌
1. Yiwen Yang, Nobuyuki Fujitsuna, Ryota Yakura, Mariko Matsuda, Taku Miura, Akira Ueno, Shoichi Kikuchi and Tatsuo Sakai, " Effects of Cleanliness and Induction Hardening on Very High Cycle Fatigue Properties of Low Alloy Forged Steel", Proc. of the 6th International Conference on VHCF, USB, No.INS06, October 15–18, 2014, Chengdu, China.
2. Tatsuo Sakai, Noriyasu Oguma, Akinari Morikawa and Akira UENO, "Micro scopic and Nanoscopic Observations of Metallographic Structures around
Inclusions at Interior Crack Initiation Site in Very High Cycle Fatigue", Proc. of the 6th International Conference on VHCF, USB, No.MIM02, October 15–18, 2014, Chengdu, China.
3. Taku Miura, Takayuki Sakakibara, Takanori Kuno, Akira Ueno, Shoichi Kikuchi and Tatsuo Sakai, "Interior-induced Fracture Mechanism of Valve Spring Steel (JIS SWOSC-V) with High Cleanliness in Very High Cycle Regime", Proc. of the 6th International Conference on VHCF, USB, No.MIM09, October 15–18, 2014, Chengdu, China.
4. Tatsuo Sakai, Koushu Hanaki, Akiyoshi Sakaida, Kenji Okada, Yuki Nakamura, Kazutaka Mukoyama, Noriyasu Oguma, Takashi Matsumura, Yoshinobu Shimamura and Akira Ueno, "Construction of Electronic Database on Very High Cycle Fatigue Properties for Metallic Materials", Proc. of the 6th International Conference on VHCF, USB, No.MIM10, October 15–18, 2014, Chengdu, China.
5. Akiyoshi Sakaida, Yanbin Zhang, Shoichi Kikuchi, Yoshihiko Yokoyama, Akira Ueno and Tatsuo Sakai, "A Study on Very High Cycle Fatigue Properties of Bulk Amorphous Alloy in Rotating Bending", Proc. of the 6th International Conference
on VHCF, USB, No.PSM14, October 15–18, 2014, Chengdu, China.
6. Shoichi Kikuchi, Stefan Heinz, Dietmar Eifler, Yuta Nakamura and Akira Ueno,
"Effects of Low Temperature Nitriding Process on the Very High Cycle Fatigue Properties of Ti-6Al-4V Alloy", Proc. of the 6th International Conference on VHCF, USB, No.PSM04, October 15–18, 2014, Chengdu, China.
7. Shoichi Kikuchi, Kotaro Takemura, Yosuke Hayami, Akira Ueno and Kei Ameyama, "Evaluation of the 4-points Bending Fatigue Properties of Ti-6Al-4V Alloy with Harmonic Structure Created by Mechanical Milling and Spark Plasma Sintering", Proc. of the 3rd Japan-Chine Fatigue Symposium, November 6–8, 2014, Takayama, Japan.
8. Akira Ueno, Masahide Nishida, Susumu Miyakawa, Koji Yamada, Shoichi Kikuchi, "ǻKth estimation of aluminum die-casting alloy by means of ¥area method ", Proc. of the APCFS/SIF-2014 International Congress, December 9-12, 2014, Sydney, Australia.
9. Microstructure And Mechanical Properties Of Sic Compacts Produced By Mechanical Milling And Spark Plasma Sintering, N. Z. B. Khalil, S. K. Vajpai, K.
Ameyama, 9th International Materials Technology Conference & Exhibition (IMTCE2014), Kuala Lumpur (Malaisia), May 13-16, 2014.
䛆ཱྀ㢌Ⓨ⾲䛇㻌
1. ๓ᮧᝆ㍤㸪ୖ㔝 ᫂㸪ᮧᒣ⩧ဢ㸪ຍ⸨ྑஓ㸪㺀ෆᅽᘧ㧗ᅽỈ⣲ἲࢆ⏝࠸ࡓ
࣑ࣝࢽ࣒࢘ྜ㔠A7075-T6511ࡢ ⑂ປ≉ᛶཬࡰࡍ㧗ᅽỈ⣲࢞ࢫࡢᙳ㡪ホ ౯㺁㸪᪥ᮏᶵᲔᏛ㛵すᨭ㒊➨90ᮇᐃ⥲࣭ㅮ₇࣭Ⓨ⾲ணᐃ, 2015.
2. Ᏻ⏣࿘ᖹ㸪ୖ㔝 ᫂㸪ᑠᯘ⠜ྐ㸪௰ ⫕㸪ᶓᒣᙪ㸪㓇㐩㞝㸪ቃ⏣ᙲ ⰾ㸪⳥ụᑗ୍㸪㺀Zrᇶࣂࣝࢡ㔠ᒓ࢞ࣛࢫࡢ4Ⅼ᭤ࡆ⑂ປ≉ᛶཬࡰࡍỈศࡢ ᙳ㡪ホ౯㺁㸪᪥ᮏᶵᲔᏛ㛵すᨭ㒊㛵すᏛ⏕ᖹᡂ26ᖺᗘᏛ⏕ဨ༞ᴗ◊✲
Ⓨ⾲ㅮ₇࣭Ⓨ⾲ணᐃ, 2015.
3. ᗮ ᮏᑀ㸪ୖ㔝 ᫂㸪㺀ᅇ㌿᭤ࡆ⑂ປヨ㦂ᶵ⏝⑂ປࡁ㐃⥆ほᐹࢩࢫࢸ࣒ࡢ 㛤Ⓨ㺁㸪᪥ᮏᮦᩱᏛ➨32ᅇ⑂ປࢩ࣏ࣥࢪ࣒࢘ㅮ₇ㄽᩥ㞟㸪2014.
4. ✄ᇉᰆ㤶㸪ᇼᕝᩍୡ㸪ᐑᓥᩄ㑻㸪ⳫᏊ㈗ᬕ㸪ୖ㔝 ᫂㸪ቃ⏣ᙲⰾ㸪ᒾၿ 㑻㸪ᕝ㔝ඃᕼ㸪㺀AIP ἲ UBMS ἲࡼࡾ TiAlN ⭷ࢆ⿕そࡋࡓ㧗㏿ᗘᕤ ල㗰ࡢ⑂ປᙉᗘẚ㍑㺁㸪᪥ᮏᶵᲔᏛM&M2014 ᮦᩱຊᏛ࢝ࣥࣇࣞࣥࢫ,
⚟ᓥᏛ㸪USB, 2014.
5. ᇼᕝᩍୡ㸪ᕝ㔝ඃᕼ㸪ୖ㔝 ᫂㸪ቃ⏣ᙲⰾ㸪ᐑᓥᩄ㑻㸪㺀࢟ࣥࢡᦆയࢆ࠼
ࡓPBO⧄⥔ࡢᘬᙇᙉᗘࡢ☜⋡ศᕸ㺁㸪᪥ᮏᶵᲔᏛ M&M2014 ᮦᩱຊᏛ࢝
ࣥࣇࣞࣥࢫ㸪⚟ᓥᏛ㸪USB, 2014.
6. ୖ㔝 ᫂㸪㧗᰿ ┿㸪ୖ㔝ᩥᘯ㸪㺀ᅛయ㧗ศᏊᙧ⇞ᩱ㟁ụ⏝㟁ゎ㉁⭷ࡢຎ
ホ౯㺁㸪᪥ᮏᶵᲔᏛ M&M2014 ᮦᩱຊᏛ࢝ࣥࣇࣞࣥࢫ㸪⚟ᓥᏛ㸪USB,
−113−
ࢆࡋࡓᕤᴗ⏝⣧ࢳࢱࣥࡢ4Ⅼ᭤ࡆ⑂ປ≉ᛶཬࡰࡍ⤖ᬗ⢏ᚄࡢᙳ㡪ホ ౯㺁㸪
8. ᒸ⏣ᝋ㑻㸪ᇼᕝᩍୡ㸪ᐑᓥᩄ㑻㸪ⳫᏊ㈗ᬕ㸪ୖ㔝 ᫂㸪ቃ⏣ᙲⰾ㸪ᒾၿ 㑻㸪ᕝ㔝ඃᕼ㸪㺀⭷ཌࡢ␗࡞ࡿTiCrAlSiN/CrN⿕そ㧗㏿ᗘᕤල㗰ࡢ⑂ປ≉ᛶ㺁㸪
᪥ᮏᶵᲔᏛ M&M2014 ᮦᩱຊᏛ࢝ࣥࣇࣞࣥࢫ㸪⚟ᓥᏛ㸪USB, 2014.
9. ▮ுኴ㸪᳃ ၨஅ㸪すཱྀඞⱱ㸪ᯇ⏣┿⌮Ꮚ㸪㓇㐩㞝㸪ୖ㔝 ᫂㸪⳥ụ ᑗ୍㸪୕ᾆ ᣅ㸪㺀⯪⯧⏝ࢡࣛࣥࢡ㍈ᮦᩱࡢࢠ࢞ࢧࢡࣝ⑂ປ≉ᛶᅾ≀
ࢧࢬࡢ㛵ಀࡘ࠸࡚㺁㸪᪥ᮏᮦᩱᏛ➨63ᮇᏛ⾡ㅮ₇㸪⚟ᒸᏛ㸪USB, 2014.
10. ቃ⏣ᙲⰾ㸪ᙇ Ⰿᩩ㸪⳥ụᑗ୍㸪ᶓᒣᙪ㸪ୖ㔝 ᫂㸪㓇㐩㞝㸪㺀ࣔࣝ
ࣇࢫ࣭ࣂࣝࢡᮦࡢ㉸㧗ࢧࢡࣝᇦ࠾ࡅࡿ☜⋡⑂ປ≉ᛶࡢゎᯒ㺁㸪᪥ᮏᮦ
ᩱᏛ➨63ᮇᏛ⾡ㅮ₇㸪⚟ᒸᏛ㸪USB, 2014.
11. ྥᒣᏕ㸪ⰼᮌᏹಟ㸪ᒸ⏣᠇ྖ㸪ቃ⏣ᙲⰾ㸪Ⳣ⏣ ῟㸪すᕝ ฟ㸪ୖ㔝 ᫂㸪 㓇㐩㞝㸪㺀㟼ⓗᙉᗘ≉ᛶ್ࡼࡿ㕲㗰ᮦᩱࡢS-N᭤⥺㛵ࡍࡿ⤫ィⓗ᥎ ᐃ㺁㸪᪥ᮏᮦᩱᏛ➨63ᮇᏛ⾡ㅮ₇㸪⚟ᒸᏛ㸪USB, 2014.
12. ྥᒣᏕ㸪୰ᮧ⿱⣖㸪ⰼᮌᏹಟ㸪ᒸ⏣᠇ྖ㸪ቃ⏣ᙲⰾ㸪㓇㐩㞝㸪Ⳣ⏣ ῟㸪 すᕝ ฟ㸪ୖ㔝 ᫂㸪㺀㟼ⓗᙉᗘ≉ᛶ್ࡼࡿ㠀㕲㔠ᒓᮦᩱࡢS-N᭤⥺㛵 ࡍࡿ⤫ィⓗ᥎ᐃ㺁㸪᪥ᮏᮦᩱᏛ➨63ᮇᏛ⾡ㅮ₇㸪⚟ᒸᏛ㸪USB, 2014.
13. ⳥ụᑗ୍㸪୰ᮧᝆኴ㸪ྜྷ⏣ ⩧㸪ୖ㔝 ᫂㸪༡㒊⣫୍㑻㸪୰ᮧ⿱⣖㸪㺀ᚤ⢏
Ꮚࣆ࣮ࢽࣥࢢࢆ⏝ࡋࡓᕤᴗ⏝⣧ࢳࢱࣥ⾲㠃ࡢࣁࢻࣟ࢟ࢩࣃࢱࢺ ᒙࡢ〇㺁㸪᪥ᮏᮦᩱᏛ➨63ᮇᏛ⾡ㅮ₇㸪⚟ᒸᏛ㸪USB, 2014.
14. ୖ㔝 ᫂㸪௰ ⫕㸪ᑠᯘ⠜ྐ㸪㺀ࢭࣜᏳᐃṇ᪉ᬗࢪࣝࢥࢽࢼࣀ」ྜ
ࢭ࣑ࣛࢵࢡࢫࡢ⑂ປᙉᗘಙ㢗ᛶホ౯㸦➨㸯ሗ㸸Ẽ୰㸧㺁㸪᪥ᮏᮦᩱᏛ➨
63ᮇᏛ⾡ㅮ₇㸪⚟ᒸᏛ㸪USB, 2014.
15. ୖ㔝 ᫂㸪ᑠᯘ⠜ྐ㸪௰ ⫕㸪㺀ࢭࣜᏳᐃṇ᪉ᬗࢪࣝࢥࢽࢼࣀ」ྜ
ࢭ࣑ࣛࢵࢡࢫࡢ⑂ປᙉᗘಙ㢗ᛶホ౯㸦➨㸰ሗ㸸Ỉ୰㸧㺁㸪᪥ᮏᮦᩱᏛ➨63 ᮇᏛ⾡ㅮ₇㸪⚟ᒸᏛ㸪USB, 2014.
16. ⳥ụᑗ୍㸪S. Heinz㸪E. Dietmar㸪୰ᮧᝆኴ㸪ྜྷ⏣ ⩧㸪ୖ㔝 ᫂㸪㺀ప ❅
ࣉࣛࢬ࣐ࢆࡋࡓTi-6Al-4Vྜ㔠ࡢ㉸㡢Ἴ⑂ປ≉ᛶ㺁㸪᪥ᮏᮦᩱᏛ➨63 ᮇᏛ⾡ㅮ₇㸪⚟ᒸᏛ㸪USB, 2014.
17. ྜྷ⏣ ⩧㸪⳥ụᑗ୍㸪୰ᮧᝆኴ㸪ୖ㔝 ᫂㸪㺀Ti-6Al-4Vྜ㔠ࡢ4Ⅼ᭤ࡆ⑂
ປ≉ᛶཬࡰࡍప ࣉࣛࢬ࣐❅ࡢᙳ㡪ホ౯㺁㸪᪥ᮏᮦᩱᏛ➨63ᮇᏛ⾡
ㅮ₇㸪⚟ᒸᏛ㸪USB, 2014.
䛆ᣍᚅㅮ₇䛇㻌
1. ࢫࢬ࢟㈈ᅋᣍᚅㅮ₇㸪ୖ㔝 ᫂㸪㺀¥area ἲࢆ⏝࠸ࡓ࣑ࣝࢲ࢝ࢫࢺྜ㔠 ࡢ⑂ປ㝈ᗘண 㸪ᅇ㌿᭤ࡆ⑂ປヨ㦂ᶵ⏝⑂ປࡁ㐃⥆ほᐹࢩࢫࢸ࣒ࡢ㛤
Ⓨ㺁㸪2014ᖺ10᭶8᪥.
௨ୖ
−115−
⨨ྡ ☢Ẽศᯒ⨨㸦NMR㸧
◊✲㈐௵⪅
㸦ᡤᒓ࣭ᙺ⫋࣭Ặྡ㸧 ⏕⛉Ꮫ㒊࣭ᩍᤵ࣭ሐ
◊✲ࢸ࣮࣐ ࢯࣇࢺ࣭ࣁ࣮ࢻ⼥ྜᮦᩱࡢ㝵ᒙⓗᵓ㐀ไᚚࡼࡿ᪂ᮦᩱࡢⓎ
◊✲ࡢᴫせ ࠸ࢁ࠸ࢁ࡞ࢯࣇࢺᮦᩱ㸦᭷ᶵ࣭㧗ศᏊᮦᩱ㸧ࣁ࣮ࢻᮦᩱ㸦㔠ᒓ㸪㔠ᒓ㓟≀࡞
㸧ࢆ⼥ྜࡉࡏ㸪ศᏊࣞ࣋ࣝࡽᕧどⓗࣞ࣋ࣝ࠾ࡅࡿྛ㝵ᒙ࠾࠸࡚⢭ᐦᵓ㐀 ไᚚࢆ⾜࠺ࡇ࡛㠉᪂ⓗ࡞ᛶ⬟࣭ᶵ⬟ࢆ♧ࡍᮦᩱࡢⓎࢆ┠ᣦࡋࡓ◊✲ࢆ⾜ࡗࡓࠋ
≉ᮏ⨨ࢆศᏊᵓ㐀ࡢỴᐃࡶࡕ࠸࡚㸪ศᏊ࡛ࣞ࣋ࣝࡢ⢭ᐦᵓ㐀ࡀᮦᩱ≀ᛶ
࠼ࡿᙳ㡪ࡘ࠸᳨࡚ウࡋ㸪ୗグ♧ࡍࡼ࠺࡞ᡂᯝࢆⓎ⾲ࡋࡓࠋ
⏝ᡂᯝ ㄽᩥ
1) Photoluminescent Gold(I) Complex with Biphenyl Acetylene Ligand Showing Stable Nematic Liquid-Crystalline Phase, N. Sugimoto, S. Tamai, K. Fujisawa, O. Tsutsumi, Mol. Cryst. Liq. Cryst., 601, 97–106 (2014).
2) Synthesis, liquid–crystalline behavior, and photoluminescence properties of novel Au(I) complex with naphthalene ring in a mesogenic core, Y. Rokusha, N. Sugimoto, S. Yamada, O. Tsutsumi, Proc. SPIE, 9182, 918206, DOI: 10.1117/12.2060334 (2014).
3) Reversible thermal-mode control of luminescence from liquid-crystalline gold(I) complexes, K. Fujisawa, Y. Okuda, Y. Izumi, A. Nagamatsu, Y. Rokusha, Y. Sadaike, O. Tsutsumi, J. Mater. Chem. C, 2, 3549–3555 (2014).
4) Tuning the photoluminescence of condensed-phase cyclic trinuclear Au(I) complexes through control of their aggregated structures by external stimuli, K. Fujisawa, S.
Yamada, Y. Yanagi, Y. Yoshioka, A. Kiyohara, O. Tsutsumi, Sci. Rep., in press.
ᅜ㝿Ꮫ
1) Full-Color Luminescence from a Single Liquid-Crystalline Gold Complex, O.
Tsutsumi, O.M. Younis, M. Tamaru, S. Tamai, N. Sugimoto, K. Fujisawa, 2014 Organic Photonics + Electronics (SPIE Optics + Photonics), San Diego, USA, August 17, 2014.
ᅜෆᏛ
1) ࣆࣛࢰ࣮ࣝ㓄Ꮚࢆ᭷ࡍࡿᾮᬗᛶ୕᰾㔠㘒యࡢ㟁Ẽఏᑟ≉ᛶ㸪ᓥಙ࿃㸪⏣
㞞୍㸪ሐ㸪➨ 63 ᅇ㧗ศᏊᏛᖺḟ㸪ྡྂᒇᅜ㝿㆟ሙ㸪2014 ᖺ 5
᭶28᪥ࠥ5᭶30᪥
2) ᾮᬗᛶ୕᰾㔠㘒యࡢࢼࣀ✵㛫࠾ࡅࡿⓎග≉ᛶ㸪୰ᮧᜤ㍜㸪⏣㞞୍㸪⋢
⩧㸪ሐ㸪➨63ᅇ㧗ศᏊᏛᖺḟ㸪ྡྂᒇᅜ㝿㆟ሙ㸪2014ᖺ5᭶28
᪥ࠥ5᭶30᪥
3) White-Color Emission from Polymer Liquid Crystals Containing Rod-Like Gold Complexes in Side-Chain, O. Younis㸪S. Tamai㸪O. Tsutsumi㸪➨63ᅇ㧗ศᏊᏛ
ᖺḟ㸪ྡྂᒇᅜ㝿㆟ሙ㸪2014ᖺ5᭶28᪥ࠥ5᭶30᪥
4) ᾮᬗᛶᲬ≧㔠㘒యࡢ࢟ࣛࣝࢿ࣐ࢳࢵࢡ┦࠾ࡅࡿⓎග≉ᛶ㸪ᮡᮏ⳯ࠎ㸪ሐ㸪
➨63ᅇ㧗ศᏊᏛᖺḟ㸪ྡྂᒇᅜ㝿㆟ሙ㸪2014ᖺ5᭶28᪥ࠥ5᭶30
᪥
5) ᾮᬗᛶ᭷ᶵ࣭↓ᶵࢼࣀࣁࣈࣜࢵࢻᮦᩱࡢ㟁ẼᏛ≉ᛶ㸪す⏣ử㸪ሐ㸪
➨63ᅇ㧗ศᏊᏛᖺḟ㸪ྡྂᒇᅜ㝿㆟ሙ㸪2014ᖺ5᭶28᪥ࠥ5᭶30
᪥
6) ⎔≧࣏ࣜ࢜࢟ࢯࣔࣜࣈࢹ࣮ࢺࢹࣥࢻ࣐࣮ࣜ」ྜయࡢᾮᬗᣲື㸪Ώ㑓ுᖹ㸪 ὠᏲ㐩ၨ㸪ሐ㸪➨63ᅇ㧗ศᏊᏛᖺḟ㸪ྡྂᒇᅜ㝿㆟ሙ㸪2014ᖺ5
᭶28᪥ࠥ5᭶30᪥
ᆺ◊✲⨨ᡂᯝሗ࿌᭩
⨨ྡ ᙉຊX⥺⨨
◊✲㈐௵⪅
㸦ᡤᒓ࣭ᙺ⫋࣭Ặྡ㸧 ⏕⛉Ꮫ㒊࣭ᩍᤵ࣭ሐ
◊✲ࢸ࣮࣐ ࢯࣇࢺ࣭ࣁ࣮ࢻ⼥ྜᮦᩱࡢ㝵ᒙⓗᵓ㐀ไᚚࡼࡿ᪂ᮦᩱࡢⓎ
◊✲ࡢᴫせ ࠸ࢁ࠸ࢁ࡞ࢯࣇࢺᮦᩱ㸦᭷ᶵ࣭㧗ศᏊᮦᩱ㸧ࣁ࣮ࢻᮦᩱ㸦㔠ᒓ㸪㔠ᒓ㓟≀࡞
㸧ࢆ⼥ྜࡉࡏ㸪ศᏊࣞ࣋ࣝࡽᕧどⓗࣞ࣋ࣝ࠾ࡅࡿྛ㝵ᒙ࠾࠸࡚⢭ᐦᵓ㐀 ไᚚࢆ⾜࠺ࡇ࡛㠉᪂ⓗ࡞ᛶ⬟࣭ᶵ⬟ࢆ♧ࡍᮦᩱࡢⓎࢆ┠ᣦࡋࡓ◊✲ࢆ⾜ࡗࡓࠋ
≉ᮏ⨨࡛ࡣ㸪⤖ᬗ୰࠾ࡅࡿศᏊࡢࣃࢵ࢟ࣥࢢᵓ㐀ࢆࢼࣀ࣓࣮ࢱ࣮࡛ࣞ࣋ࣝゎ
᫂ࡋ㸪ศᏊจ㞟ᵓ㐀ࡀᮦᩱ≀ᛶ࠼ࡿᙳ㡪ࡘ࠸᳨࡚ウࡋࡓࠋ
⏝ᡂᯝ ㄽᩥ
1) Photoluminescent Gold(I) Complex with Biphenyl Acetylene Ligand Showing Stable Nematic Liquid-Crystalline Phase, N. Sugimoto, S. Tamai, K. Fujisawa, O. Tsutsumi, Mol. Cryst. Liq. Cryst., 601, 97–106 (2014).
2) Synthesis, liquid–crystalline behavior, and photoluminescence properties of novel Au(I) complex with naphthalene ring in a mesogenic core, Y. Rokusha, N. Sugimoto, S. Yamada, O. Tsutsumi, Proc. SPIE, 9182, 918206, DOI: 10.1117/12.2060334 (2014).
3) Reversible thermal-mode control of luminescence from liquid-crystalline gold(I) complexes, K. Fujisawa, Y. Okuda, Y. Izumi, A. Nagamatsu, Y. Rokusha, Y. Sadaike, O. Tsutsumi, J. Mater. Chem. C, 2, 3549–3555 (2014).
4) Tuning the photoluminescence of condensed-phase cyclic trinuclear Au(I) complexes through control of their aggregated structures by external stimuli, K. Fujisawa, S.
Yamada, Y. Yanagi, Y. Yoshioka, A. Kiyohara, O. Tsutsumi, Sci. Rep., in press.
ᅜ㝿Ꮫ
1) Full-Color Luminescence from a Single Liquid-Crystalline Gold Complex, O.
Tsutsumi, O.M. Younis, M. Tamaru, S. Tamai, N. Sugimoto, K. Fujisawa, 2014 Organic Photonics + Electronics (SPIE Optics + Photonics), San Diego, USA, August 17, 2014.
ᅜෆᏛ
1) ࣆࣛࢰ࣮ࣝ㓄Ꮚࢆ᭷ࡍࡿᾮᬗᛶ୕᰾㔠㘒యࡢ㟁Ẽఏᑟ≉ᛶ㸪ᓥಙ࿃㸪⏣
㞞୍㸪ሐ㸪➨ 63 ᅇ㧗ศᏊᏛᖺḟ㸪ྡྂᒇᅜ㝿㆟ሙ㸪2014 ᖺ 5
᭶28᪥ࠥ5᭶30᪥
2) ᾮᬗᛶ୕᰾㔠㘒యࡢࢼࣀ✵㛫࠾ࡅࡿⓎග≉ᛶ㸪୰ᮧᜤ㍜㸪⏣㞞୍㸪⋢
⩧㸪ሐ㸪➨63ᅇ㧗ศᏊᏛᖺḟ㸪ྡྂᒇᅜ㝿㆟ሙ㸪2014ᖺ5᭶28
᪥ࠥ5᭶30᪥
3) White-Color Emission from Polymer Liquid Crystals Containing Rod-Like Gold Complexes in Side-Chain, O. Younis㸪S. Tamai㸪O. Tsutsumi㸪➨63ᅇ㧗ศᏊᏛ
ᖺḟ㸪ྡྂᒇᅜ㝿㆟ሙ㸪2014ᖺ5᭶28᪥ࠥ5᭶30᪥
4) ᾮᬗᛶᲬ≧㔠㘒యࡢ࢟ࣛࣝࢿ࣐ࢳࢵࢡ┦࠾ࡅࡿⓎග≉ᛶ㸪ᮡᮏ⳯ࠎ㸪ሐ㸪
➨63ᅇ㧗ศᏊᏛᖺḟ㸪ྡྂᒇᅜ㝿㆟ሙ㸪2014ᖺ5᭶28᪥ࠥ5᭶30
᪥
5) ᾮᬗᛶ᭷ᶵ࣭↓ᶵࢼࣀࣁࣈࣜࢵࢻᮦᩱࡢ㟁ẼᏛ≉ᛶ㸪す⏣ử㸪ሐ㸪
➨63ᅇ㧗ศᏊᏛᖺḟ㸪ྡྂᒇᅜ㝿㆟ሙ㸪2014ᖺ5᭶28᪥ࠥ5᭶30
᪥
6) ⎔≧࣏ࣜ࢜࢟ࢯࣔࣜࣈࢹ࣮ࢺࢹࣥࢻ࣐࣮ࣜ」ྜయࡢᾮᬗᣲື㸪Ώ㑓ுᖹ㸪 ὠᏲ㐩ၨ㸪ሐ㸪➨63ᅇ㧗ศᏊᏛᖺḟ㸪ྡྂᒇᅜ㝿㆟ሙ㸪2014ᖺ5
᭶28᪥ࠥ5᭶30᪥
−117−
◊✲㈐௵⪅
㒊㛛ྡ
◊✲ࢸ࣮࣐
㹖⥺ᅇᢡ⨨ࡼࡿ㓟≀ᢸᣢ㔠ᒓゐ፹ᮦᩱḟ㟁ụṇᴟᮦᩱࡢ≧ែゎᯒ
◊✲ࡢᴫせ
ᆒ୍⣔ゐ፹ᮦᩱࡋ࡚⏝࠸ࡽࢀࡿྛ✀㓟≀ᢸయୖࠊ1Lࠊ&Rࠊ0Q ࡞ࡢ 㔠ᒓࢼࣀ⢏Ꮚ࠾ࡼࡧ 3G&X ࡞ࡢྜ㔠ࢼࣀ⢏Ꮚࢆᢸᣢࡋࡓ⢊ᮎゐ፹ᮦᩱࢆྜᡂ ࡋࠊ㹖⥺ᅇᢡ⨨ࢆ⏝࠸࡚ࡑࡢ⤖ᬗ≧ែࡢゎᯒࢆ⾜ࡗࡓࠋ᪤▱ᵓ㐀ࡢᶆ‽ヨ
ᩱࡢẚ㍑࡞ࡽྜᡂࡋࡓヨᩱࡢ⤌ᡂࡸ⤖ᬗᵓ㐀ࢆỴᐃࡋࡓࠋࡲࡓࠊᨺᑕ ගࢆ⏝࠸ࡓࡑࡢሙᏛ≧ែゎᯒࡢ⤖ᯝྜࢃࡏࠊᢸᣢ㔠ᒓゐ፹ࡢᛂάᛶ
㔠ᒓᏛ✀ࡢᏛ≧ែࡢ┦㛵ࢆ᫂ࡽࡋࡓࠋࡲࡓࠊࣜࢳ࣒࢘࢜ࣥḟ 㟁ụࡢṇᴟά≀㉁࡛࠶ࡿ /L1L2ࡸ /L)H32࡞ࢆྜᡂࡋࠊࡑࡢ㟁ụ≉ᛶࢆホ౯ ࡍࡿྠࠊࡑࢀࡽࡢ⢊ᮎᮦᩱࡢ≧ែゎᯒࢆ⾜ࡗࡓࠋࡇࢀࡣࠊ㟁ụ≉ᛶࢆ
ホ౯ࡍࡿୖ࡛ᚲせྍḞ࡞ሗ࡛࠶ࡿࠋ
⏝ᡂᯝ
࠙ཎⴭㄽᩥ㸦ᰝㄞࡁ㸧ࠚ
Misaki Katayama, Koichi Sumiwaka, Ryota Miyahara, Hisao Yamashige, Hajime Arai, Yoshiharu Uchimoto, Toshiaki Ohta, Yasuhiro Inada, Zempachi Ogumi, “X-ray absorption fine structure imaging of inhomogeneous electrode reaction in LiFePO4 lithium-ion battery cathode”, J. Power Sources, 2014, 269, 994-999.
Takayasu Moroki, Hiroyuki Yasui, Yusuke Adachi, Katsuhiko Yoshizawa, Airo Tsubura, Kazuhiko Ozutsumi, Misaki Katayama, and Yutaka Yoshikawa, “New Insulin-Mimetic and Hypoglycemic Hetero-Binuclear Zinc(II)/Oxovanadium(IV) Complex”, Curr. Inorg. Chem., 2014, 4(1), 54-58.
Satoshi Asaoka, Hideo Okamura, Yusuke Akita, Katsuyoshi Nakano, Kenji Nakamoto, Kazutoshi Hino, Tadashi Saito, Shinjiro Hayakawa, Misaki Katayama, Yasuhiro Inada, “Regeneration of manganese oxide as adsorption sites for hydrogen sulfide on granulated coal ash”, Chem. Eng. J., 2014, 254, 531-537.
∦ᒣ┿⚈, ✄⏣ᗣᏹ, “DXAFSࡼࡿ㛫ศゎX⥺྾ศග”, ⾲㠃⛉Ꮫ, 2014, 35(3), 141-145.
࠙ⴭ᭩ࠚ
✄⏣ᗣᏹ࣭∦ᒣ┿⚈ࠊࠕXAFS/EELSᒁᡤᵓ㐀ゎᯒࠖࠊሗᶵᵓࠊ59-66 (2014).
࠙ᅜෆᏛⓎ⾲ࠚ
∦ᒣ┿⚈, ᐑཎⰋኴ, Ώ㑔⛱ᶞ, ᒣୗ⩧ᖹ, ✄⏣ᗣᏹ, ࠕ㖄┤᪉ྥἼ㛗ศᩓᆺ XAFS ἲࡢ㛤Ⓨ
㛫-✵㛫ศゎゎᯒࡢᛂ⏝ࠖ, ➨17ᅇXAFSウㄽ, ᚨᓥ, 2014ᖺ9᭶.
ᐑ⏣ఙᘯ, ㇏⏣, ᪥㔝ୖ㯇Ꮚ, Ώ㑔⛱ᶞ, ∦ᒣ┿⚈, ✄⏣ᗣᏹ, ࠕࢹࣛࣇ࢛ࢧࢺᆺ㓟≀
࠾ࡅࡿd㟁Ꮚࢫࣆࣥ≧ែࠖ, ➨17ᅇXAFSウㄽ, ᚨᓥ, 2014ᖺ9᭶.
ᒣୗ⩧ᖹ, ᒣᮏᝆ⟇, ∦ᒣ┿⚈, ✄⏣ᗣᏹ, ࠕᢸᣢࢽࢵࢣࣝ⢏Ꮚࡢ⾲㠃㓟ᛂ㛵ࡍࡿ㏿ᗘ ㄽⓗゎᯒࠖ, ➨17ᅇXAFSウㄽ, ᚨᓥ, 2014ᖺ9᭶.
ᒣᮏᝆ⟇, ᒣୗ⩧ᖹ, ∦ᒣ┿⚈, ✄⏣ᗣᏹ, ࠕIn situ XAFSἲࡼࡿࢰࣝ-ࢤࣝἲ࡛ࡢᢸᣢNiゐ
፹ㄪ〇㐣⛬ࡢゎᯒࠖ, ➨17ᅇXAFSウㄽ, ᚨᓥ, 2014ᖺ9᭶.
∦ᒣ┿⚈, ✄⏣ᗣᏹ, ࠕ✵㛫ศゎ࢜࣌ࣛࣥࢻほ ᡭἲࡢ㛤Ⓨ㟁ᴟᛂゎᯒࡢᛂ⏝ࠖ, ᨺᑕ ගᏛ➨7ᅇⱝᡭ◊✲͆᭱ඛ➃࢜࣌ࣛࣥࢻほ ࡛᫂ࡽ࡞ࡿ≀ᛶ⛉Ꮫ͇, ᯽, 2014ᖺ9᭶.
ᓥ⏣ెዉ, ∦ᒣ┿⚈, ✄⏣ᗣᏹ, ࠕ࣑ࣝࢼᢸᣢࡋࡓPdCuࡢᅛ┦ྜ㔠࣓࢝ࢽࢬ࣒ࠖ, ➨ 4ᅇCSJᏛࣇ࢙ࢫࢱ2014, ᮾி, 2014ᖺ10᭶.
㈏㞝ᘺ, ᐑཎⰋኴ, ∦ᒣ┿⚈, ✄⏣ᗣᏹ, ࠕX ⥺྾ศගἲࡼࡿࣜࣥ㓟ࣂࢼࢪ࣒࢘ࣜࢳ࢘
࣒ṇᴟࡢ㟁ᴟᛂゎᯒࠖ, ➨4ᅇCSJᏛࣇ࢙ࢫࢱ2014, ᮾி, 2014ᖺ10᭶.
ᯇᒸဴஓ, ᒣୗ⩧ᖹ, ∦ᒣ┿⚈, ✄⏣ᗣᏹ, ࠕin-situ XAFSἲࡼࡿࢩࣜ࢝ᢸᣢNiゐ፹ࡢCO
ࡼࡿ㑏ඖᛂࡢゎᯒࠖ, ➨4ᅇCSJᏛࣇ࢙ࢫࢱ2014, ᮾி, 2014ᖺ10᭶.
ᐑཎⰋኴ, ∦ᒣ┿⚈, ✄⏣ᗣᏹ, ࠕ✵㛫ศゎྍ⬟࡞᪂つἼ㛗ศᩓᆺXAFSἲࡢ㛤Ⓨࠖ, ➨50 ᅇX⥺ศᯒウㄽ, ྎ, 2014ᖺ10᭶.
∦ᒣ┿⚈, ✄⏣ᗣᏹ, ࠕ❧㤋SRࢭࣥࢱ࣮XAFSࣅ࣮࣒ࣛࣥࢆ⏝࠸ࡓゐ፹㟁ụࡢᛂゎ ᯒࠖ, ྜྠࢩ࣏ࣥࢪ࣒࢘ 2014㹼ᨺᑕග࣮ࣞࢨ࣮ࡢ༠ാࡼࡿ᪂⏘ᴗᡂ㹼, ⚄ᡞ, 2014 ᖺ 11᭶.
ᐑཎⰋኴ, ∦ᒣ┿⚈, ✄⏣ᗣᏹ, ࠕṇᴟᛂࡢ✵㛫ศゎゎᯒྥࡅࡓ᪂ࡋ࠸Ἴ㛗ศᩓᆺ XAFSἲࡢ㛤Ⓨࠖ, ➨55ᅇ㟁ụウㄽ, ி㒔, 2014ᖺ11᭶.
ᒣᮏᝆ⟇, ᒣୗ⩧ᖹ, ∦ᒣ┿⚈, ✄⏣ᗣᏹ, ࠕᢸᣢNi⢏Ꮚࡢ㓟㑏ඖ≉ᛶཬࡰࡍ⢏Ꮚࢧࢬ
ຠᯝࠖ, ➨28ᅇ᪥ᮏᨺᑕගᏛᖺ࣭ᨺᑕග⛉Ꮫྜྠࢩ࣏ࣥࢪ࣒࢘, ⲡὠ, 2015ᖺ1᭶.
Ώ㑔⛱ᶞ, ∦ᒣ┿⚈, ✄⏣ᗣᏹ, ࠕ㌿㟁Ꮚ㔞 XAFS ࡼࡿᙧ≧ไᚚࡋࡓᢸᣢCu2O⢏Ꮚࡢ
⾲㠃㑏ඖᛂࠖ, ➨28ᅇ᪥ᮏᨺᑕගᏛᖺ࣭ᨺᑕග⛉Ꮫྜྠࢩ࣏ࣥࢪ࣒࢘, ⲡὠ, 2015ᖺ1
᭶.
ᓥ⏣ెዉ, ∦ᒣ┿⚈, ✄⏣ᗣᏹ, ࠕࣃࣛࢪ࣒࢘㖡ྜ㔠ゐ፹ࡢ⏕ᡂᑐࡍࡿ๓㥑య⤌ᡂࡢຠᯝࠖ,
➨28ᅇ᪥ᮏᨺᑕගᏛᖺ࣭ᨺᑕග⛉Ꮫྜྠࢩ࣏ࣥࢪ࣒࢘, ⲡὠ, 2015ᖺ1᭶.
⏣᠇ᖾ, ∦ᒣ┿⚈, ┾⏣ᬛ⾨, ᑠሐᙪ, ᑠᓥ୍⏨, ✄⏣ᗣᏹ, ࠕ㓟≀࢞ࣛࢫ୰࠾ࡅࡿ
Mn ࢜ࣥࡢᒁᡤᵓ㐀ࠖ, ➨ 28ᅇ᪥ᮏᨺᑕගᏛᖺ࣭ᨺᑕග⛉Ꮫྜྠࢩ࣏ࣥࢪ࣒࢘, ⲡὠ, 2015ᖺ1᭶.
ᆤᐶኴ, ∦ᒣ┿⚈, ✄⏣ᗣᏹ, ࠕࢮ࢜ࣛࢺᢸᣢࡋࡓ Ni(II)࢜ࣥࡢ྾╔≧ែࡢゎᯒࠖ, ➨ 28ᅇ᪥ᮏᨺᑕගᏛᖺ࣭ᨺᑕග⛉Ꮫྜྠࢩ࣏ࣥࢪ࣒࢘, ⲡὠ, 2015ᖺ1᭶.
Siwaruk Chotiwan, Hiroki Tomiga, Misaki Katayama, Yasuhiro Inada, “Thermodynamic and kinetic study on redox reaction of silica supported cobalt catalysts”, ➨28ᅇ᪥ᮏᨺᑕගᏛᖺ࣭ᨺᑕග
⛉Ꮫྜྠࢩ࣏ࣥࢪ࣒࢘, ⲡὠ, 2015ᖺ1᭶.
䭜Ꮥ♸, ༓ᑜ, ∦ᒣ┿⚈, ✄⏣ᗣᏹ, ⸨ᒸẎ, ኴ⏣ಇ᫂, ᑠᓥ୍⏨, ࠕṇᴟά≀㉁
−119−
ᮏᏛ➨95Ꮨᖺ, ⯪ᶫ, 2015ᖺ3᭶.
▼㥴ᖹ, ∦ᒣ┿⚈, ✄⏣ᗣᏹ, ࠕ࣓ࢯ࣏࣮ࣛࢫࢩࣜ࢝ᢸᣢࡋࡓCoゐ፹ࡢ㓟㑏ඖ≉ᛶࠖ,
᪥ᮏᏛ➨95Ꮨᖺ, ⯪ᶫ, 2015ᖺ3᭶.
࠙ಟኈᏛㄽᩥࠚ
ᆤᐶኴࠊࠕ✀ࠎࡢࢮ࢜ࣛࢺᑐࡍࡿࢽࢵࢣࣝ(II)࢜ࣥࡢ࢜ࣥ≧ែࡢゎ᫂ࠖ
ᓥ⏣ెዉࠊࠕ⤌ᡂࡢ␗࡞ࡿࣃࣛࢪ࣒࢘㖡ྜ㔠ゐ፹ࡢ⏕ᡂ࣓࢝ࢽࢬ࣒ࠖ
ᆺ◊✲⨨ᡂᯝሗ࿌᭩
⨨ྡ NMR JEOL ECS-400
◊✲㈐௵⪅
㸦ᡤᒓ࣭ᙺ⫋࣭Ặྡ㸧
ᑠᓥ୍⏨ 㸦⏕⛉Ꮫ㒊࣭ᛂ⏝Ꮫ⛉࣭ᩍᤵ㸧
◊✲ࢸ࣮࣐ ⺯ගᛶᾮᬗᇶࢆ⾲㠃ಟ㣭ࡉࡏࡓࢩࣜ࢝ࢼࣀ⢏Ꮚࡢྜᡂ≀ᛶࡢホ౯
◊✲ࡢᴫせ ࢩࣜ࢝ࢼࣀ⢏Ꮚࡣ㟁ሙ༳ຍୗ࡛≉␗࡞ᣲືࢆ♧ࡍࡇࡀ▱ࡽࢀ࡚࠸ࡿࡀࠊࡑࡢ ᣲືࡣゎ᫂ࡉࢀ࡚࠸࡞࠸ࠋࢩࣜ࢝ࢼࣀ⢏Ꮚ⾲㠃ࢆ⺯ගᛶᾮᬗᇶ࡛ಟ㣭ࡍࡿࡇ
࡛㸦࠼ࡤࠊ
Silica:11-(Ethoxydimethylsilyl)undecyl-2,5-bis
((4-(octyloxy)phenyl)ethynyl)benzoate
㸧 ࡸ 㛵 㐃 ྜ ≀ ࡛ ࠶ ࡿSilica:Undecylethoxydimethylsilane㸧
ࠊ㟁ሙ༳ຍୗ࠾ࡅࡿࢩࣜ࢝ࢼࣀ⢏Ꮚࢆྍどࡋࠊࡑࡢᣲືࢆどぬⓗゎ᫂ࡍࡿࡇࢆ┠ⓗࡍࡿࠋ
⺯ගᛶᾮᬗᇶࡢᵓ㐀ࢆゎᯒࡍࡿࡓࡵᐊ (20Υ)ࠊ400 MHz᮲௳ୗࡢ⁐ᾮ1H NMRࢫ࣌ࢡࢺࣝࡼࡿ ᐃࢆ⾜ࡗࡓࠋලయⓗ ᐃࡋࡓྜ≀5✀ࢆ௨ୗ
♧ࡍࠋ࡞࠾ඹྠ◊✲ᩍဨࡣࠊᑠᓥ୍⏨ࠊ┾⏣ᬛ⾨ࠊⰼᓮ▱๎ࠊ㔠Ꮚගభ࡛࠶ࡿࠋ
(1) 1-(Octyloxy)-4-(2-(trimethylsilyl)ethynyl)benzene (2) 1-Ethynyl-4-(octyloxy)benzene
(3) 10-Undecen-1-yl-2,5-dibromobenzoate
(4) 10-Undecen-1-yl 2,5-bis((4-(octyloxy)phenyl)ethynyl)benzoate (5) Undecylethoxydimethylsilane
⏝ᡂᯝ ᖺᗘᮍᥖ㍕ศࡢᅜෆᏛⓎ⾲
㸦1㸧Ώ㑔ಟᖹࠊⰼᓮ▱๎ࠊᑠᓥ୍⏨ࠊࠕࢩࣜ࢝ࢼࣀ⢏ᏊᾮᬗศᏊࢆ⤖ྜࡉࡏ ࡓ↓ᶵ࣮᭷ᶵࣁࣈࣜࢵࢻᆺྜ≀ࡢྜᡂ≀ᛶࠖࠊ᪥ᮏᏛ➨94Ꮨᖺ
㸸4E4-11ࠊ㸦ྡྂᒇᏛࠊ2014ᖺ3᭶30᪥㸧
−121−
⨨ྡ ࣞࢡࢭࣝ
◊✲㈐௵⪅
㸦ᡤᒓ࣭ᙺ⫋࣭Ặྡ㸧 ⏕⛉Ꮫ㒊࣭ᩍᤵ㸦ࣞࢡࢭࣝタ㛗㸧࣭᪩㔝ಇဢ
◊✲ࢸ࣮࣐ ࣑ࢻࣜࢰ࣒࢘ࣜࢩ⣽⬊ෆඹ⏕⸴㛵ࡍࡿ◊✲㸦ᢸᙜ㸸⸆Ꮫ㒊࣭ᩍᤵ࣭ᮧ
ಙᏕ㸧
࣌ࣉࢳࢻࢺࣛࣥࢫ࣏࣮ࢱ࣮ (PEPT1) ࢆࢱ࣮ࢤࢵࢺࡋࡓ5㸫࣑ࣀࢧࣜࢳ
ࣝ㓟 (5-ASA) ࣉࣟࢻࣛࢵࢢࡢྜᡂCaco-2⣽⬊ᑐࡍࡿ㍺㏦≉ᛶ◊✲㸦ᢸ ᙜ㸸⸆Ꮫ㒊࣭ᩍᤵ࣭⸨⏣༟ஓ㸧
◊✲ࡢᴫせ ࣑ࢻࣜࢰ࣒࢘ࣜࢩඹ⏕⸴ࡣࠊ㓟ᛶ᮲௳ୗ࡛ගྜᡂ⏘≀ࡢ࣐ࣝࢺ࣮ࢫࢆᨺฟࡍࡿ
ࡇࡀ≉ᚩ࡛࠶ࡾࠊࡇࡢᨺฟ⤒㊰ࡘ࠸࡚ࡣ᫂࡞Ⅼࡀከࡃ᳨ウࢆ⾜ࡗࡓࠋᨺ ฟ᮲௳ୗ࡛Ⅳ㓟ࡢྲྀࡾ㎸ࡳࡽᨺฟࡲ࡛ࡣࠊᩘศ࠸ࡗࡓ▷࠸ᛂ࡛㉳ࡇࡿࡇ
ࡀศࡗࡓࠋࡲࡓࠊᨺฟࡉࢀࡿ࣐ࣝࢺ࣮ࢫࡢ㒊ศࡀ✚ࡉࢀࡓࢹࣥࣉࣥ
ࡽ࡛ࡣ࡞ࡃࠊᅛᐃࡋࡓⅣ⣲ࡽ᪂ࡓྜᡂࡋ࡚࠸ࡿࡇࡀศࡗࡓࠋ
₽⒆ᛶ⭠⅖ࡣཌ⏕ປാ┬ࡼࡾ㞴ᣦᐃࡉࢀ࡚࠸ࡿᝈ࡛࠶ࡿࠋ₽⒆ᛶ⭠
⅖ࡢ⒪⸆ࡋ࡚ࡣ㸫࣑ࣀࢧࣜࢳࣝ㓟$6$ࡀỗ⏝ࡉࢀ࡚࠸ࡿࡀࠊ⅖
㒊ࡢ㏦㐩ᛶࡀஈࡋࡃࠊ༑ศ࡞⒪ຠᯝࡀᚓࡽࢀ࡞࠸ࡇࡶከ࠸ࠋ⤒ཱྀȕ 㸫ࣛࢡࢱ࣒ᢠ⏕≀㉁ࡢᑠ⭠ࡽࡢ྾㛵ࡋ࡚࠸ࡿROLJRSHSWLGH
WUDQVSRUWHU3(37ࡣࠊᖖே࡛ࡣ⭠࡛ࡢⓎ⌧ࡣࢇㄆࡵࡽࢀ࡞࠸ࡢ
ᑐࡋࠊ₽⒆ᛶ⭠⅖ࡢᝈ⪅࡛ࡣ⭠⅖㒊ࡶ㧗Ⓨ⌧ࡋ࡚࠸ࡿࡇࡀሗ࿌
ࡉࢀ࡚࠸ࡿࠋᮏ◊✲࡛ࡣࠊ$6$ࡢ1+ᇶ࠶ࡿ࠸ࡣ&22+ᇶ࣑ࣀ㓟ࢆᑟධ ࡋࡓࢪ࣌ࣉࢳࢻᆺࣉࣟࢻࣛࢵࢢࢆྜᡂࡋࠊࡇࢀࡽྜ≀ࡢ3(37ࢆࡋࡓ㍺
㏦࣭௦ㅰ≉ᛶࢆ&DFR⣽⬊ࢆ⏝࠸᳨࡚ウࡋࡓࠋ&DFR⣽⬊࠾ࡅࡿ3(37
ࢆࡋࡓ*O\6DUࡢྲྀࡾ㎸ࡳࡣࠊ᳨ウࡋࡓ$6$ࣉࣟࢻࣛࢵࢢ࡚ࡀ⃰ᗘ౫ Ꮡⓗ㜼ᐖࡉࢀࡓࠋ*OXࢆ$6$ࡢ1+ᇶ࠶ࡿ࠸ࡣ&22+ᇶᑟධࡋࡓࣉࣟ
ࢻࣛࢵࢢ࡛ࡣࠊ>+@*O\6DUྲྀࡾ㎸ࡳᑐࡍࡿ,&್㢧ⴭ࡞ᕪࡀㄆࡵࡽࢀࡓ ࡇࡽࠊ࣑ࣀ㓟ࡢᑟධ㒊ࡼࡾࣉࣟࢻࣛࢵࢢ3(37ࡢぶᛶᕪ␗
ࡀ⏕ࡌࡿࡇࡀ♧၀ࡉࢀࡓࠋࡲࡓࠊ$6$ࡢ1+ᇶ࣑ࣀ㓟9DOࠊ7\Uࠊ/\V
ࢆᑟධࡋࡓࣉࣟࢻࣛࢵࢢࡣࠊ&DFR࣍ࣔࢪࢿ࣮ࢺ୰࡛ศゎࡉࢀࡓࡀࠊ&22+ᇶ
࣑ࣀ㓟ࢆᑟධࡋࡓࣉࣟࢻࣛࢵࢢ࡛ࡣࡃศゎࡀㄆࡵࡽࢀ࡞ࡗࡓࠋࡇࡢ⤖
ᯝࡣࠊぶ⸆≀࡛࠶ࡿ$6$ኚࡏࡎ⭠㒊Ⓨ⌧ࡍࡿ3(37㏦㐩ࡉ ࡏࡿࡇࡀ࡛ࡁࢀࡤࠊࡼࡾຠ⋡ⓗ࡞⒪ࢆ⾜࠺ࡇࡀ࡛ࡁࡿྍ⬟ᛶࢆ♧၀ࡍࡿ
ࡶࡢ࡛࠶ࡾࠊᚋࡣࠊᐇ㝿$6$ࡢࣉࣟࢻࣛࢵࢢࡢྲྀࡾ㎸ࡳᐇ㦂ࠊ,%'ࣔࢹ
ࣝື≀ࢆ⏝࠸ࡓ⒪ᐇ㦂ࢆ⾜࠺ࡇ࡛,%'ᑐࡍࡿ᪂つ⒪⸆ࡋ࡚ࡢྍ⬟
ᛶࢆ㏣ồࡋ࡚࠸ࡃணᐃ࡛࠶ࡿࠋ
⏝ᡂᯝ 㸺ᅜෆᏛ㸼
ᰘ⏣࠶࠸ࠊ㧗ᶫᩥ㞝ࠊ➟ཎ㈼ὒࠊᮧಙᏕ ࣑ࢻࣜࢰ࣒࢘ࣜࢩඹ⏕
ࢡࣟࣞࣛ࠾ࡅࡿ࣐ࣝࢺ࣮ࢫᨺฟࡢไᚚᶵᵓࡘ࠸࡚ ཎ⏕⏕≀Ꮫ➨
ᅇࠊ㸦ྎ㸧ࠊ ᖺ ᭶
⏤㱟Ⴙࠊす ㈗ᘯࠊἙ㔝⿱ඔࠊᑎ⏣ᬛ♸ࠊ⸨⏣༟ஓ 3(37ࢆᶆⓗࡋ ࡓ࣑ࣀࢧࣜࢳࣝ㓟ࣉࣟࢻࣛࢵࢢࡢ &DFR⣽⬊࠾ࡅࡿ㍺㏦≉ᛶࡢ᳨
ウ᪥ᮏ⸆Ꮫ➨ ᖺ㸦㛗ᓮ㸧ࠊ ᖺ ᭶㸦Ⓨ⾲ணᐃ㸧 㸺ㄽᩥ㸼
࡞ࡋ 㸺ࡑࡢ㸼
⸨⏣༟ஓ㸬 ᾘ⟶ࢺࣛࣥࢫ࣏࣮ࢱ࣮ࡢ྾㞀ቨࡋ࡚ࡢᙺᾘ⟶௦ㅰ
࠾ࡅࡿ✀ᕪ㸬 ᣢ⏣〇⸆ㅮ₇㸦㟼ᒸ㸧ࠊ2014ᖺ12᭶
−123−
⨨ྡ SRග㟁Ꮚศග࣭࢜ࣥᩓ」ྜศᯒ⨨
◊✲㈐௵⪅
㸦ᡤᒓ࣭ᙺ⫋࣭Ặྡ㸧 ⌮ᕤᏛ㒊≀⌮⛉Ꮫ⛉࣭ᩍᤵ࣭㞴Ἴ⚽
◊✲ࢸ࣮࣐ 㧗ศゎ⬟୰࢚ࢿࣝࢠ࣮࢜ࣥᩓ 65 ග㟁Ꮚศගࡼࡿᅛయ⾲㠃ࡢᵓ㐀ࠊ㟁Ꮚ
≧ែゐ፹ᶵ⬟ࡢゎᯒ
◊✲ࡢᴫせ ᖺᗘࡢࡓࡿࢸ࣮࣐
㸧 651(;$)6 ࡼࡿᾮᬗࡢୗᆅ㓄ྥ⭷ࡢゎᯒ 㸧 ཎᏊ≧㓟⣲ࡼࡿࢢࣛࣇࢺࡢ⾲㠃㓟
㸧 ᩥ㒊⛉Ꮫ┬ඛ➃◊✲ᇶ┙ඹ⏝࣭ࣉࣛࢵࢺࣇ࢛࣮࣒ᙧᡂᴗ࠾ࡅࡿඹྠ
⏝
⏝ᡂᯝ ᮏ⨨ࡢ⏝ࡣ⾲㠃≀⌮࣭⾲㠃⛉Ꮫ࡛ࡢ◊✲ᡂᯝࢆୖࡆࡿࡓࡵࡔࡅ࡛࡞ࡃࠊ
ᩘᖺ๓ࡽ⌮ᕤᏛ㒊≀⌮⛉Ꮫ⛉3ᅇ⏕ࡢṇㄢᤵᴗ࡛࠶ࡿࠕ≀⌮Ꮫ≉ูᐇ㦂㸯ࠖ
ࡢ୍ࡘࡢࣃ࣮ࢺࡋ࡚౪⏝ࡉࢀࠊᏛ⏕ᨺᑕගࢆᐇ㝿⏝ࡋ࡚ࡶࡽ࠸ࠊࡑࡢ
࣏ࢸࣥࢩࣕࣝࡢ㧗ࡉࢆయ㦂ࡋ࡚ࡶࡽࡗ࡚ࡁࡓࠋ ᮏ⨨ࡣ㏻ᖖࡢᐇ㦂ᐊࡣ࡞
࠸ᆺᐇ㦂⨨࡛ࡶ࠶ࡾࠊࡑࢀ័ࢀࡿࡇࡶ㈗㔜࡞⤒㦂࡞ࡗ࡚࠸ࡿࠋ
◊◊✲ᡂᯝሗ࿌᭩
M. Takizawa, K. Kondo and H. Namba,“Oxidation states of graphite studied by near edge x-ray absorption fine structure measurements”, Memories of the SR Center Ritsumeikan University, No.16, 2014,pp.145-146.
ᅜෆ㆟
ἑඃࠊ㏆⸨ㅬసࠊ㞴Ἴ⚽ࠕ྾➃㏆ഐ ; ⥺྾ᚤ⣽ᵓ㐀 ᐃࡼࡿࢢࣛࣇ
ࢺ⾲㠃ࡢ㓟≧ែࠖࠊ➨ ᅇ᪥ᮏᨺᑕගᏛᖺ࣭ᨺᑕග⛉Ꮫྜྠࢩ࣏ࣥ
ࢪ࣒࢘㸦❧㤋Ꮫࠊ ᖺ ᭶㸧ࠋ
⌮ ᕤ Ꮫ ◊ ✲ ᡤ グ
−125−
௦⾲⪅
(ᡤᒓ࣭⫋ྡ࣭Ặྡ) ⸆Ꮫ㒊⸆Ꮫ⛉࣭ᩍᤵ࣭Ẹ⛅ ᆒ
㞟ྡ ᅜ㝿◊✲㞟㻌 ➨ 㻝㻜 ᅇ䛂Ꮫⓗ䛻䝥䝻䜾䝷䝮䛥䜜䛯ྜᡂⰍ⣲㢮䛾㉸ศᏊ䝘䝜⛉Ꮫ䛃㻌 Tenth International Workshop on Supramolecular Nanoscience of Chemically
Programmed Pigments (SNCPP14) 㛤ദ᪥⛬ 㸰㸮㸯㸲ᖺ㸳᭶㸱㸮᪥㹼㸰㸮㸯㸲ᖺ㸴᭶㸯᪥
ሙ ࢚࣏ࢵࢡ❧㸰㸯
ሗ࿌ෆᐜ
ணࡵᵝࠎ࡞ሗࢆࣉࣟࢢ࣒ࣛࡋࡓศᏊࢆタィࡍࡿࡇ࡛ࠊ࢚ࢿࣝࢠ࣮ᢞධࡍ
ࡿࡇ࡞ࡃࠊ⮬ᕫ㞟✚⬟ࢆ⏝ࡋ࡚ࠊෆ㒊ᵓ㐀ࡀ⦓ᐦ࡛యᵓ㐀ࡶ᫂☜࡞ࢼࣀ
㉸ศᏊᵓ㐀యࢆᵓ⠏ࡍࡿࡇࡣࠊࢼࣀ⛉Ꮫࡢ᥎㐍ࡁ࡞ᙳ㡪ࢆ࠼ࡿࠋࡑࡇ
࡛ࠊᗈ࠸ព࡛ࡢࠕᏛⓗࣉࣟࢢ࣒ࣛࡉࢀࡓྜᡂⰍ⣲㢮ࡢ㉸ศᏊࢼࣀ⛉Ꮫࠖ
㛵ࢃࡿ◊✲ᡂᯝࢆⓎ⾲ࡍࡿᅜ㝿◊✲㞟SNCC2014ࢆࠊ❧㤋Ꮫࡧࢃࡇ࣭
ࡃࡉࡘ࢟ࣕࣥࣃࢫ࡛ୖグᮇ㛫⾜ࡗࡓࠋ
ᇶㄪㅮ₇1௳ࠊᣍᚅㅮ₇8௳ࠊ㑅ᢤㅮ₇2௳ࠊ࣏ࢫࢱ࣮Ⓨ⾲36௳ࡀ⾜ࢃࢀࠊ
⣙100ྡࡢཧຍ⪅ࡀ࠶ࡾࠊኚ┒ἣ࡛࠶ࡗࡓࠋ≉ࠊⱝᡭ࡛㉸ศᏊࢼࣀ⛉Ꮫࡢ ศ㔝࡛◊✲ࢆ⾜ࡗ࡚࠸ࡿ◊✲⪅ࢆᅜෆእࡽᣍᚅࡋ࡚ࠊάⓎ㆟ㄽࢆ⾜࠸ࠊࡇ ࡢศ㔝ࡢⓎᒎࡗ࡚ࡁ࡞ព⩏ࡀ࠶ࡗࡓࠋ
ᅇࡢSNCC2014ࡢBKC࡛ࡢ㛤ദࡣࠊᮏᏛࡢ◊✲⪅ࠊ≉Ꮫ㝔⏕ࢆྵࡴ
ⱝᡭࡢ◊✲⪅ࡗ࡚ࡁ࡞่⃭ࢆ࠼࡚ࡃࢀࡓࠋࡇࡢࡼ࠺࡞ὶࡼࡗ࡚ࠊ
❧㤋Ꮫࡢᅜ㝿㈨ࡍࡿࡇࡀ࡛ࡁࡓࠋࡲࡓࠊ༤ኈ◊✲ဨࡸᏛ㝔⏕࡞
ࡢⱝᡭ◊✲⪅ࢆྵࡴᮏᏛࡢ◊✲⪅ࡀࠊࠕᏛⓗࣉࣟࢢ࣒ࣛࡉࢀࡓྜᡂⰍ⣲㢮 ࡢ㉸ศᏊࢼࣀ⛉Ꮫࠖࡢ◊✲Ⓨ⾲ࢆⱥㄒ࡛⾜࠺ࡇ࡛ࠊ❧㤋Ꮫࡽࡢ◊✲Ⓨ
ಙࡔࡅ࡛ࡣ࡞ࡃࠊᅜ㝿ࡶ᥎㐍࡛ࡁࡓࠋ
ཱྀ㢌ㅮ₇⪅ࡣࠊJishan Wu㸦ࢩ࣏࣮ࣥ࢞ࣝᅜ❧㸧ࠊ⏣୰㝯⾜㸦ி⌮㸧ࠊ
ᕝ⿱୍㸦ᕤ㸧ࠊᑎᮧ⨾㔛㸦❧㤋㸧ࠊᒣཱྀኴ㸦❧㤋㸧ࠊJeongho Kim 㸦㡑ᅜ㺃Inha Univ.㸧ࠊᲚ ㈗༤㸦ᮍ᮶ICT◊㸧ࠊᯘ ᏹᬸ㸦ዉⰋඛ➃⛉ᢏ㸧ࠊ 㰺⸨ᑦᖹ㸦ྡ⌮㸧ࠊ⋤ ᬡᓠ㸦ᶓ᱒ⶱ㸧ࠊᆏᮏⰋኴ㸦ᮾ⌮㸧ࡢ 11ྡ 㸦ᩗ⛠␎࣭Ⓨ⾲㡰㸧࡛࠶ࡾࠊࡑࡢࡢヲ⣽ࡣࠊබᘧHPࢆཧ↷ࡋ࡚ୗࡉ࠸ࠋ
http://www.ritsumei.ac.jp/se/rc/staff/tamiaki/sncpp14/
ࢩ࣏ࣥࢪ࣒࣭࣮࢘࣡ࢡࢩࣙࢵࣉ㛤ദຓᡂ ሗ࿌᭩
௦⾲⪅
(ᡤᒓ࣭⫋ྡ࣭Ặྡ)
⏕⛉Ꮫ㒊࣭ᩍᤵ࣭ୗጔ 㑻
㞟ྡ ➨2ᅇ⏕་⛉Ꮫࢥ࣒ࣟ࢟࢘
㛤ദ᪥⛬ 2014ᖺ6᭶27᪥
ሙ ࢧ࢚ࣥࢫࢥ㸯F Sㅮ⩏ᐊ
ሗ࿌ෆᐜ ⏕་⛉Ꮫ⛉࡛ࡣࠊᖺ1ᅇ⛬ᗘࠊᡤᒓᩍဨࡢ◊✲ᡂᯝࢆ㡰⤂ࡍࡿࡶ
ࠊᏛእࡽࡑࡢ௦ࡢࢺࣆࢵࢡࢫヲࡋ࠸₇⪅ࢆᣍ⪸ࡋࠊ⏕་⛉Ꮫࢥࣟ࢟
࣒࢘ࢆ㛤ദࡋ࡚࠸ࡿࠋ
ᅇࡢࣉࣟࢢ࣒࡛ࣛࡣࠊ⏕་⛉Ꮫ⛉ࡢᩍᤵ2ྡࠊ≉ูㅮ₇ࡋ࡚ࠊி㒔
Ꮫࡼࡾጒᑿㅮᖌࡢㅮ₇ࢆ⾜ࡗࡓࠋ ᴫせࡣୗグ࡛࠶ࡿࠋ
յ࣮࢜ࣉࢽࣥࢢ࣐࣮ࣜࢡ Ꮫ⛉㛗㸦ࢥ࣮ࢫ㛗㸧࣭ྖ 17:00-17:05
յㅮ₇
㸯㸬 ୗጔ 㑻㸦⏕་⛉Ꮫ⛉࣭ᩍᤵ㸧 ࠕຠ⋡ⓗࡘබᖹ࡞་⒪㈨※㓄ศ ᪉ἲ☜❧ࡢࢳࣕࣞࣥࢪࠖ 17:05-17:40
㸰㸬ᇼ ⾜㸦⏕་⛉Ꮫ⛉࣭ᩍᤵ㸧 ࠕࡀࢇ⣽⬊ࡢ⣽⬊ෆࢩࢢࢼࣝఏ㐩ࠥHippo
⤒㊰ࢆᡭࡀࡾ ࡋ࡚ࠥࠖ 17:40-18:15
㸱㸬 ጒᑿ ᾈ㸦ி㒔ᏛᏛ㝔་Ꮫ◊✲⛉࣭ᾘჾෆ⛉Ꮫ࣭ㅮᖌ㸧 ࠕࡀࢇᖿ
⣽⬊ࢆᶆⓗࡋࡓ᪂ࡋ࠸ࡀࢇ⒪ࡢྍ⬟ᛶࠖ 18:15-19:00
ᮏ◊✲ࡢㅮ₇⪅ࡢᣍ⪸ㅰ♩ࠊ◊✲㈝ࢆࢃࡏ࡚࠸ࡓࡔ࠸ࡓࠋ
−127−
௦⾲⪅
(ᡤᒓ࣭⫋ྡ࣭Ặྡ)
⌮ᕤᏛ㒊 ᩍᤵ ⸨ ᐙ 㞷 ᮁ
㞟ྡ
㻡 㻡㻙㼠㼔㻌㻸㼑㼏㼠㼡㼞㼑㼟㻌㼛㼚㻌㻿㼑㼙㼕㻙㻯㼘㼍㼟㼟㼕㼏㼍㼘㻌㻭㼚㼍㼘㼥㼟㼕㼟㻌 㻌 㻔㻌 ‽ྂゎᯒධ㛛ㅮ⩏㻌 㻕
㛤ദ᪥⛬
䠎䠌䠍䠐㻌 ᖺ㻌 䠓㻌 ᭶㻌 䠏㻌 ᪥㻌 䡚㻌 㻌 䠎䠌䠍䠐㻌 ᖺ㻌 㻌 䠓㻌 ᭶㻌 䠑㻌 ᪥
ሙ
❧㤋Ꮫ䜃䜟䛣䛟䛥䛴䜻䝱䞁䝟䝇㻌 䝁䝷䞊䝙䞁䜾䠥䠥㻌 㻌
䝥䝺䝊䞁䝔䞊䝅䝵䞁䝹䞊䝮
ሗ࿌ෆᐜ
ᩘᏛࡢᚤศ᪉⛬ᘧࡢ⌮ㄽࡢ୰࡛ࡶࠊ≉‽ྂゎᯒࡢศ㔝⤠ࡗࡓࢧ࣐࣮ࢫ ࢡ࣮ࣝࢆࠊ❧㤋ᏛࡢBKC࢟ࣕࣥࣃࢫ࠾࠸࡚㛤ദࡋࡓࠋࡇࡢศ㔝ࡢୡ⏺
ࡢ➨㸯ே⪅࡛࠶ࡿ Nicolas Burqᩍᤵ㸦ࣃࣜ㸯㸯Ꮫ㸧ࠊMichael Hitrikᩍᤵ
㸦UCLA㸧ࢆㅮᖌࡋ࡚ᣍࡁࠊ᭱ඛ➃ࡢヰ㢟ࡢ୰ࡽࡑࢀࡒࢀࢺ࣮ࣛࢫୖࡢࢩ
ࣗࣞࢹ࣮ࣥ࢞᪉⛬ᘧࡢไᚚ⌮ㄽࠊ‽ྂ㠀⮬ᕫඹᙺస⏝⣲ࡢࢫ࣌ࢡࢺࣝ⌮ㄽ
ࡘ࠸࡚ࠊᏛ㝔⏕ࡶ⌮ゎ࡛ࡁࡿධ㛛ࣞ࣋ࣝࡽ᭱᪂ࡢ◊✲ᡂᯝࡲ࡛ࠊ㸱
㛫࡙ࡘ㐃⥆ㅮ⩏ࢆ⾜ࡗ࡚ࡶࡽࡗࡓࠋࡑࡢࠊᾏእࠊᅜෆ࡛ά㌍ࡍࡿ㸳ேࡢⱝᡭ ࡢ◊✲⪅ࡢㅮ₇ࡶࣉࣟࢢ࣒ࣛධࢀࡓࠋ㸳㸮ே㏆࠸ཧຍ⪅ࡀࡇࡢ◊✲ศ㔝ࡢⓎ
ᒎᐤࡍࡃ⇕ᚰຮᙉࡋࠊ㆟ㄽࢆ῝ࡵࡓࠋ
ㅮᖌࡽࡢᣍ⪸ࡣࡶࡕࢁࢇࠊᾏ㐨Ꮫ࣭⟃ἼᏛ࣭ᮾிᏛ࣭㜰Ꮫ࣭⚄
ᡞᏛ࣭ᗈᓥᏛ࡞ࡢ࣏ࢫࢻࢡࡸᏛ㝔⏕࠸ࡗࡓⱝᡭ◊✲⪅ࡢ᪑㈝ࡢຓ
ᮏຓᡂ㔠ࢆά⏝࡛ࡁࡓࠋ
୍㒊ࡢㅮ₇ࡘ࠸࡚ࡣࠊ࣮࣒࣮࣍࣌ࢪ
http://www.math.ritsumei.ac.jp/takuwatanabe/LSCA/LSCA2014.html
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