37号(最新版) - 神奈川大学 工学研究所
Contents
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11. Professor Dept of Maternal and Life Chemnstry xx
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13. ls SA YY VY 7 PAV AVA AVK VMVV Smart Society and Machine Learning Masanori AKIYOSHI 1
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23. 3 2 1956 The Dartmouth Summer Research Project on Artficial Inteligencey
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28. 1 1 113 2013 25 I EE 2 3 4 5 2013 4 2014 3 2013 4 2014 3 2013 4 2014 3 2013 4 2014 3
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42. 1 Professor Dept of Material and Life Chemistry
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44. DNA 115 116 37 4 1 20138 10 26 14 00 16 00
45. 4 97 Memories of he Research and Education at Kanagawa University Tadamitsu SAKURAI 1 1979 4 36 4 2 42
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48. 2 3 Associate Professor Department of Chemstry 1 1 2 G
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61. CFRP S50C 22 8680N 1 1 2 MEV 105
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73. Figure 16 fi FC YS Ft no oH O K2CO3 CaCOa3 DMAc toluene OO OO nN CH3sOCH2Cl ZnCb CHCCHCb N CHs H2O Jl O N OO OO 1 Figure 15 Bisphenol A TMA PAES 1 Figure 15 Bisphenol A 7 68 000 4 47 1 7 THF DMF DMAc
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84. 1 52 2010 243 HHI MR 36 2013 77 3 64 2013 756 4 T Akashi J Nakazawa S Hikichi Mol Catal A Chem 371 2013 42 9 J Nakazawa T Hori T D P Stack S Hikichi Chem Asian J 8 2013 1191 6 T Nagataki Y Tachi and S Itoh Chem Commun 2006 4016 7 Y Doi J Nakazawa S Hikichi to be submitted 8 J Nakazawa A Yata T Hori T D P Stack Y Naruta S Hikichi Chem Lett 42 2013 1197 9 W N Oloo Y Feng S Iyer S Parmelee G Xue L Que Jr New J Chem 37 2013 3411 10 46 2004 262 1D3 29 2006 10 12 S Hikichi K Hanaue T Fujimura H Okuda J Nakazawa Y Ohzu C Kobayashi M Akita Dalton Trans 42 2013 3346 13 J Nakazawa S Terada M Yamada S Hikichi J Am Chem Soc 135 2013 6010 14 A Nakamizu T Kasai J Nakazawa S Hikichi to be submitted
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93. 443 260
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96. 3 3 1934 20 Kolmogorov Levy Ito 1
97. Dean of the Faculty of Engineering NSF MIT Media Lab 70 IDBM
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104. Q C Vol 76 No 763 2010 pp 696 703 2 Nakayasu H Miyoshi T Aoki H and Patterson P Analysis of Driver Perceptions and Behavior When Driving in an Unfamiliar Regulatior Journal of Advanced Computational Intelligence and Intelligent Informatics Vol 15 No 8 2011 pp 1039 1048 3 Seya Y Nakayasu H Patterson P Visual search of trained and untrained drivers in a driving simulator Japanese Psychological Research Vol 50 No 4 2011 pp 242 252 C Vol 79 Ne803 2013 pp 2408 2423 5 Card S K Moran T P and Newell A The Psychology of Human Computer Interactnon Lawrence Erlbaum Associates 1983 pp 23 97 Rasmussen
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106. OR SWCNT RSWCNT 7 oo SWCNT Fpelt Fe 2 expGO 2 2x Ro J OR 2 bi1 by 9Q SWCNT SWCNT 2RA A 2 amp SWCNT g 4 5 8S 4 1 Wi ww PO 5 55 26 5 l u
107. 020 5 Times New Roman Symbol 1 1 O 2 c 9 2 7 7exp 7 x 1 O a b 1 c d gt 2 Fa 2 6 References A
108. 2013 2012 11 A1 300 11 A2 210 2013 12 A1 150 12 A2 230 12 A3
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115. Thomas Jefferson 4 1826 7 4 50 OE KR L M Terman 1921 102 37 1 500 80 2
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120. 1969 4 2 Mulliken Muliiken Yr
121. 1 CPU 18 J J BBinney N J Dowrick A J Fisher and M E J New man The Theory of Critical Phenomena Chapter 4 Oxford Sclence Publications 1992 19 R H Swendse and J S Wang Phys Rev Lett 8 86 1987 20 U Wolff Phys Rev Lett 62 361 1989 21 g 2 22 P W Kasteleyn and C M Fortum J Phys Soc Japan Suppl 26s 11 1969 23 C M Fortuin and P W Kasteleyn Physica 7 536 1972 24 H G Evertz G Lana and M Marcu Phys Rev Lett 70 875 1993 25 N V Prokov ev B V Svistunov and 1 S Tupitsyn Sov Phys JETP 87 310 1998 26 N V Prokov ev B V Svistunov and 1 S Tupitsyn Phys Lett A 238 253 1998 27 J Liu and E Luijten Phys Rev E 71 066701 2005 28 1991 29 J Houdayer Eur Phys J B 22 479 2001 30 Jorg Prog Theor Phys Suppl 1S7 349 2005 31 J Machta C M Newman and D L Stein J Stat Phys 130 113 2008
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123. 1 C R Rao Statistics and Truth Putting Chance to Work 1993 2 S Friedman and L R Martin The Longevity Project Surprising Discoveries for Health and Long Life from the Landmark Fight Decade Study 2012 G O 2005 4 1980 5 2003 6 2004 2012 8 W Feller An Introduction to Probabihty Theory and Its Applications Vol L John Wiley amp Sons New York 1937 9 PS Laplace Theorie analytique des probabihtes 1812 1986 105 8 Eight Years at K
124. a 4 Pt TO ORR Bifunctional c MnO gt Bifunctional o MnO Bifunctonal Bifunctional
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134. University of Strasbourg Louis Aragon 1897 1982 9 Lecture Notes in Mathematics Sprnger 1943 1945
135. 2 L SBA COOH x FeD FeSBA_ COOHLr 1 0 2 0 L 1 L B Im MePh Fe FeL L Fe FeL Fe Fe SBA COOH L x 74 0 5 gt 2 0 gt 1 0 x 0 5 1 0 L L Fe 1
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138. oN ste ee Tp 4 2 b R Br ea 0 Tp Tp C H 2 3 2 ol gt 3 oD C H 3 Ni OH mCPBA 260 umol Mez2 others 3
139. 8 2 2 3 x y z GPIB 58 3 2 2 2 0
140. OL huMan Material Money amp Information Machine 1 3M amp I 2 2 3M amp i 3M amp I 3M amp I 37 2 2 3M amp I 3M amp I 3M
141. 4 ICT 1 ICT 133 2013 12 pp 796 799 2 D A Norman The Invisible Computer The MIT Press 1998 3 28 2013 2 pp 184 185 4
142. ee tt 9 2 7 Si S ij SIE EET 3 a i 30 1 fr 2 1 2 C D tav SeC SCO naive MC e 2 2 1 W 3
143. D Fe OAc Fe SBA COOH L x x 0 5 1 0 L x 2 0 L 2 EtO _OEt HO COONa Pluronic P123 template Si i 1 H O conc HCI EtO OEt HD ONa 2 Soxhlet extraction 100 x mol x mol 3 Me SiCI 1 Buli pn Fe _ N ER 7 77 BN HrHcl NF 4 7 YN 8 N BB N COOH N Vi op 7 psves EN go 2 OSiMe _Fe OAcz 2 OSiMes SC SYS de MecN de oo oO 90 0 NAM oodpbo SBA COOH r SBA COOH L x Fe SBA COOH L x 5 SBA COOH_L_x 2 Fe SBA COOH L x O OH O H2O2 aq 2 5 mmol OO J 1 Cat 50 mg MeCN 5 mL 2 5 mmol rt Ar 2 h E A K L Fe TON per Fe Cat Sr Cat E A K TON on reuse 15 4 6 7 a 022 017 6 4 9 5 0 0 19 020 9 3 5 8 A De 0 12 0 20 1 0 not tested Fe SBA COOH 2 0 3 6 not tested 0 10
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146. Web Web SOA Service Oriented Architecture SaaS Software as a Service MOT Managsement of Technology MOS Management of Service 2 4 3
147. Pro Pro Asp Resm Asp Pro Resin SBA Asp Pro SBA SBA Resm 20 Resi 65 ee S SBA 16 ee ee ne ee eee SBA Asp
148. 4 5 5 6 6 6 85
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153. 1 2 3 4 Intensity a u 402 400 398 396 394 Binding energy eV Figure 14 N XPS Ns 10 a 25 b 30 c 75 100 e
154. 1 2 2 D A Norman The Invisible Computer PC Personal Computer e Japan u Japan ICT
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159. Professor Dept of Electrical Electroncs and Information Engineering 30
160. Pt Et 87 Pt Pt Pt PtPb PtCu PtNi TO gt 0 0 MD a 5 1 0 b lt E 2 0 3 0 4 0 C 0 6 0 8 1 0 EIV rs RHE Figure 2 As prepared PtCu CB a PtCuCB 25 b 50 c 100 qd
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164. 3 D O 1 R G W Norish G Porter Nature 164 658 1949 2 A Baltuska T Fuji T Kobayashi Opt Lett 27 306 2002 3 I Iwakura A Yabushita T Kobayashi Chem Lett 39 374 2010 4 L Claisen Chem Ber 453 157 1912 5 C D Hurd M A Pollack 7 Am Chem Soc 60 1905 1938 6 R Hoffmann R B Woodward 4cc Chem Res 1 17 1968 7 1 Iwakura A
165. 50nm 25gum 4 GPIB General Purpose Interface Bus gt 3000A m 8000Am 2 4 2K Nb electrode AIOr oxide Nb electrode 1 Nb 7 4000 4000 b
166. 6 4 10 Hz 8 8 2 OFF ON i bo 1 1 1 E E 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 Hz Z CFRP 47 OFF ON Y t i i I TD 1 TEST 1 mn 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 Hz 2 Z i OFF ON Y t 2 SS ES J J 0 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 Hz O IE G 110 100
167. 93 Temperature C y1S om 9 Anion conductivit mh On IM PAES 2 2 8 3 0 3 2 3 4 1000 T 1 K Figure 17 TMA PAES 1 dEC 2 25 meq g IM PAES 2 EC 2 14 megg 5S 6 3 6 5
168. SBA Ns CH C CH Huisgen 3 21 SBA tz N Py Ni mCPBA 7 Ni mCPBA X tz N Py 1 b TPA 1 a 1
169. 10 1 20 2000 SIAM Society for Industrial and Applied Mathematics 10
170. 2 a AO A Josephson current mA 800 Magnetic Field H A m 2 B Vi 0 20 mV mA 800 Magnetic Field H A m 800 0 800 Magnetic Field A m 3 O A 7 3000Am 60A m 2 2 7 b 2 2 c 4000A m 4 4000A m 4000A m
171. 3 NiD zzCPBA 2 CH 1 4 NiD zCPBA O O NiD mCPBA 1 C_H NiQD 7CPBA mCPBA O O Ni NiO
172. 2 2018 11 9 14 00 16 00 3 2018 11 16 14 00 16 00 NTT 4 2018 12 7 14 00 16 00 5 2013 2012 12 6 12 00 17 00 1 804 2 1 1 804 2 MAF MAF
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175. 9 SWCNT SWCNT CR 11 14A SWCNT 1 ce NT Ice NT tm 1 4 Ice NT SWCNT Ice NT gt lt 20 A Ice NT 5 Ice NT 300 K 273 K
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180. Stochastic Potential Switching SPS 53D 2 H 2 Vi Si S 15 8S SPS VV 1 P Pi Sj exp B AVi S Sj AP 16 8 1 kg T AVi Si Vi Si Vij Si S 17 AV AVij Si Sj Vi Vi Pij Vij Si S Vij Si S B log l Pi 18 SPS 5 A
181. q 3 4 5 DS 10msec EyeLink II 4msec PC DS EyeLink IL
182. 910 MM E 2 MK MW PMMA 100
183. Asp OMe Pro Pro SBA 15 SBA_ Asp OMe Pro SBA Asp SBA_ Asp Pro Pro Pro D SBA L Asp D Pro Resin Resin Asp OMc Pro gt Resin AA SBA Asp
184. 1 1 0 21 3 2A 14 4A SWCNT 12 SWCNT 3 SWCNT Tube 200K 160K 100K Intensity a u Intensity a u 1 9 2 2 1 2 2 2 3 2 4 QU1 A 8 a 2A 13 5 A e DIPS 2R 24 0 A Q 2 2 AT 7 8 Ice NT A B F 27 pr 7 QRrdr T pp x 3 SWCNT Interstitial Channel IC zo COS 4 x27 pic r T OR rdr 81 0 1 2R 14 4A 180K 220K Y 2R 14 4 A metal
185. Tp x 0 5 1 0 SBA_ SHL_x allyLTp AIBN ene SBA SH_Tp x x 0 5 Tp SH 0 052 mmol g Tp 0 051 mmol g x 1 0 3 Tp SH 0 097 mmol g Tp 0 05 mmol g Tp CHsCGO CUD SBA_ SAc_ Tp 4 CoBp
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187. SBA Si OH SBA 177 Jones SBA_ NH SBA Jones 4 2012
188. BCA SCA G BCA IE
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190. 7 2 nbd4 1 VY eV W Associate Professor Dept of Mathematics e WV 1 Ve Vz e Ve Ve 9 G Ge Ce G 8 2 P FI EV Yd Cl AM
191. 1938 Pollack 255 Woodward Hoffmann 0 O O Or gt ME 500 1500 2500 fs
192. 1956 1961 196 3 1966 1 29 klein kleiner 3 1970
193. Bifunctional OH O Fig 11 12 0 04 0 04 mAcm E OyH2O 1 23 V 0 059 V x pH ys NHE 1 E OyOH 0 463 V vs NHE 0 265 V vs Ag AgCI NaCl sat at 0 1 M KOH aqueous solution 2 0 4 0 3 0 2 0 1 0 Y vs Ag7AgCI NaCl sat Figure 9 ORR 0 1 M KOH 10 mV s 2000 rpm Mn RuO n 0 0 8 n 0 a 0 2 b 0 4 c 0 6 d 0 8 e 90 37 0 02 0 3 0 4 0 5 0 6 0 7 EIY vs Ag AgCl NaCl sat Figure 10 0 1 M KO
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195. 2 Mersenne Twister 3 4 Metropolis 6 9 8 9 10 2 Mersenne Twister
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211. 77 47 9 X J 1 X J X J 2 X J X J 3 X J 9 0 XX 4 30 37 11 M 4 J E ML 7 12 x 4 x Bd 7
212. Research assocate Dept of Industrnal Engineering and IManagement xx Professor Dept of Industrial Engmeermg and Management xy Professor Hannan Unnversty Haruki MATSUURA Tetsuya MIYOSHI 3 2018 PC
213. X 6 CoD Co allyLTp Co D allyLTp DD Co OAc gt 4FLO CoD OAc Co Gally1 Tp OAo UV vis Co D CoQ D 72 37 SBA N TEOS Si OE0 MPTMS HS CH5 Si OMe TEOS MPTMS 100 x gt
214. AQ E 6 E E 13 P E P E Aad E Ee C 14 Q E Wang Landau QA E Wang Landau Wang Landau b simulated annealing G63 09 2 1 37
215. 0 1 M HCIO4 PtCu CB PtCu TiO THF CB TiO Pt PCCODCL Cu C H CuO Hithium triethylborohydride 0 1 M HbSO 0 2 1 2 V vs RHE NPs CB NPs TiO Fig 2 23 50 100 PtCu CB ORR 2 Current density mA cm 0 6 0 8 1 0 EIV vs RHE Figure 3 PtCuCB a PtPb CB b PINi CB c and PVCB d 0 1 M HCIO4 0 0 2 1 0 Current density mA cm Uo 0 6 0 8 1 0 EIV vs RHE Figure 4 Pt CB a Pt TiO2 b PtCu CB ec PtCu Ti02 d
216. 2 000 2 000 1 500 0 3 200 Er 14 000 3 25 2 2 2 CFRP KU WI PF
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218. Binaphthol 6 M 25 000 Figure 17 IM PAES 2 TMA PAES1 1 2 TMA PAES 1 oz 47X 1010 cm3 STP cm cm sec cmHg TMA PAES 1 IM PAES 2 TMA PAES 1 2 7
219. Tp Co D Tp 4 Co D Co SBA_ SH_Tp 0 5 420 nm Co allyLTp 6 Co D x 1 0 CoSBA SAc Tp 10 Co allyLTp OAc 5 Co D CoSBA SH Tpc 1I0 Co allyLTp OAc Co allyLTp
220. N_O 1 2 98 37
221. PtPb TiOyCB TG ICP Intensity a u 2 theta Figure 5 a HOyCB b TO powder c PUTiOYCB d PtPb TiOyCB XRD ea Intensity a u baseline Raw Calc Binding energy eV Figure6 PUTiOyCB XPS Fig 5 X CB TO TiOz b TiOyCB c 40 PVTiOyCB PtPb Pt PtPb TO PtPb Fig 6 PwTiOyCB XPS 47 PVTiOyCB XPS Pt 0
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287. 42 27 Column Research Commttee of Japan Edited by Handbook of Structural Stability Corona Publishing Company Tokyo 1971 Part 3 D 73 28 Ehshakoff I Probabihstc resoluton of the twentieth century conundrum in elastic stability Thm Walled Structures Vol 59 2012 DD 35 57 29 2009 11 17263 30 Takano A Statistical Knockdown Factors of Bucklmg Anisotropic Cylinders under Axial Compression ASME Journal of Applied Mechanics Vol 79 2012 051004 31 Takano A Simple Closed Form Solution for the Buckling of Moderately Thick Anisotropic Cylinders Aerospace Technology of Japan Vol 10 2012 pp 17 26 32 Takano A Improvement of Fliigge s Equations for Buckling of Moderately Thick Anisotropic Cylindrical Shells 4744 Journal Vol 46 No 4 2008 pp 903 911 33 Takano A Buckling of thin and moderately thick anisotropic cylinders under combined torsion and axial compression Thin Walled Structures Vol 49 Issue 2 February 2011 Pages 304 316 34 Love A E H 4 Treatise on the Mathematical Theory of Elasticity 4th ed Dover Publications New York 1944 Chaps XXIV and XXIV 35 Timoshenko S and Gere J M Theory of Elastic Stability 2nd ed McGrow Hill Book Company 1961 Chap 11 36 Sanders J L
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323. LT 82 862 1984 10 Wong K F W and Weaver P M Approximate Soluton for the Compression Buckling of Fully Anisotropic Cyhndncal Shells 4744 Journal Vol 43 No 12 2005 pp 2639 2645 11 Donnell L H Stabihty of Thm Walled Tube under Torsion NACA Report 479 1933 pp 95 116 12 Cheng S and Ho B P C Stabihity of Heterogeneous Aeolotropic Cylindrical Shells under Combmed Loading 4744 Journal Vol 1 No 4 1963 pp 892 898 13 Ho B P C and Cheng S Some Problems in Stabihty Heterogeneous Aeolotropic Cylindrical Shells under Combmed Loading 4744 Journal Vol 1 No 7 1963 pp 1603 1607 14 FIGgge W Stresses in Shells 2nd ed Sprmger Verlag New York 1973 Chap 8 15 Bert C W and Kim C D Analysis of Buckhng of Hollow Lammated Composite Drrve Shafts Technology No 53 1995 pp 343 351 16 Lei M M and Cheng S Buckling of Composrte and Composites Science and Homogeneous Isotropic Cylindrical Shells under Axial and Radial Loading Journal of Applied Mechanics Transactions of the ASME 1969 pp 791 798 17 Wu C H Buckling of Anisotropic Circular cylindrical Shells Ph D Thesis Case Western Reserve University June 1971 18 Stein M and Mayers J Compressive Buckling of Simply Supported Curved Plates and Cylind
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354. 32 B Berg and T Neuhaus Phys Lett B 267 249 1991 33 B Berg and T Neuhaus Phys Rev Lett 68 9 1992 34 F Wang and D P Landau Phys Rev Lett 86 2050 2001 35 F Wang and D P Landau Phys Rev E 64 056101 2001 36 W Kerler and P Rehberg Phys Rev E 50 4220 1994 37 B Coluzzi J Phys A 28 747 1995 38 K Hukushima and K Nemoto J Phys Soc Jpn 65 1604 1996 39 H G Katzgraber S Trebst D A Huse and M Troyer J Stat Mech P03018 2006 40 A W Appel SIAM J Sci Comput 6 85 1985 41 J Barnes and P Hut Nature 324 446 1986 42 L Greengard The Rapid Evolution of Potential Fields in Particle Systems MIT Press 1988 43 J Carrier L Greengard and V Rokhlin SIAM J Sci Com put 9 669 1988 44 M Saito Mol Simulation 8 321 1992 45 H Q Ding N Karasawa and W A Goddard III J Chem Phys 97 4309 1992 46 J Sasaki and F Matsubara J Phys Soc Jpn 66 2138 1997 47 E Luijten and H W J Blote Int J Mod Phys C 6 359 1995 48 M Sasaki and F Matsubara J Phys Soc Jpn 77 024004 2008 49 K Fukui and S Todo J Comput Phys 228 2629 2009 50 C H Mak J Chem Phys 122 214110 2005 51 C H Mak and A K Sharma Phys Rev Lett 98 180602 2007 52 1
355. Assocate Professor Institute of Physics Assocate Professor Institute of Physics Research Assistant Tokyo Metropolitan University Professor Tokyo Metropolitan University X NMR 2R 13 24 A SWCNT 3 BD 0 6 0 amp 6 2 NE A a VO MA 1 SWCNT lce NT Ice NT 2 MEIO Arc SO SWCNT SWCNT SWCNT
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358. Q 1 A Barone and G Paterno Physics and Apphcatons of the Josephson Effect Wiley Intersclence New York 1982 2 R L Peterson Cryogenics Vol 31 Pages 132 1991 3 J G Grsbertsen E P Houwman B B G Klopman J Flokstra H Rogalla D Quenter S Lemke Physica Vol C249 Pages 12 1995 K Kikuchi H Myoren T lizuka S Takada Appl Phys Lett VO1 77 Pages 3660 2000 S Akiyoshi Nakayama Susumu Abe Tatsuyuki Morita Makoto Iwata and Yusuke Yamamoto IEEE Trans Mag Vol 36 Pages 3511 2000 6 A Nakayama S Abe T Shoji R Aoki and N Watanabe Physica Vol B329 333 Pages 1493 2003 7 Norimichi Watanabe Akiyoshi Nakayama Susumu Abe Kunimori Aizawa J Appl Phys Vol 97 Pages 10B116 1 May 2005 8 N Watanabe A Nakayama S Abe K Aizawa J Appl Phys Vol 97 Pages 10B116 2005 9 Akiyoshi NAKAYAMA Susumu ABE Tetsuya SHIMOYAMA Norimichi WATANABE Hsu Jui Pang and Yoichi OKABE J Phys Conf Ser Vol 43 Pages 1092 2006 10 N Watanabe A Nakayama S Abe Appl Phys Vol 101 Pages 09G105 2007 2 6
359. SWCNT 10 3 4 5 6 2R 13 5 A SWCNT Q 2 2 AT Ice NT 1 Ice NT 9 2A 144 A Ice NT 2R 24 0 A SWCNT Ice NT 2R 24 0A SWCNT 100 K 2 2A Ice NT 7 8 5 6 X
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362. 1 14 0 Times New 5 Roman Roman So 8 MS 7 1 27 2004 11 p 126 27 124 2004 p 126 1 1 2 3 4 5 6 Research Insttute for Engineermg Sclence Reports of Research Insttute for Engineermg Faculty of Engineering Department Dept of Mechanical Engineering Electrcal and Electronic Information Engineermg Material and Life Chemistry Information Systems Creation Industrial Engineering and Management Architecture
363. 9 10 8 9 Ge g Ge ae 7g4 2 Rag 1 1 z gt Ng Aw_ 8 lt hp_jya 4 1 4 zz 7 9 9 3 3 Ir Z 9 2 zg 3
364. An Improved First Approximation Theory for Thm Shells NASA TR R 24 June 1959 37 Green A E and Zerna W Theoretical Elasticity 2nd ed Dover Pubhcations New York 1992 Chap 2 38 Washizu K Variational Methods in Elasticity amp Plasticity 3rd ed Pergamon Press New York 1982 Chaps 3 and 4 27 39 Flngge W Tensor Analysis and Continuum Mechanics Springer 41 Fung Y C and Tong P Classical and Computational Solid Verlag 1972 Mechanics World Scientific Singapore 2007 1979 42 1995 40 Palazotto A N and Denns S T Nonlinear Analysis of Shell 43 Pai P F Highly Flexible Structures Modeling Computation and Structures AIAA Reston VA 1992 Experimentations AIAA Reston VA 2007 28 VAAN OANA SN 4 A paracompactness and Neighborhood Properties Yasushi HIRATA 1 J
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370. B A No p x 52 192 1977 8 p 1125 x E W Euller and R F Stoessel Mech Engng 90 3 1968 3 p 42 B No p x 1976 p 1223 7 Windows MS Word 97 Word 1 1
371. Buckhng and Static Strength of Anisotropc Cylinders Atsushi TAKANO 20 A paracompactness and Neighborhood Properties Yasushi HIRATA 28 The 3M amp I Variety Body approach Enterprise Particle and Balancing Tssues A EG I EE EE EEE EE NE RE EE Masayuki MATSUI 2 36 Joint Research Development of Vehicle Control and CFRP Chassis for Micro Electric Vehicles Hun Ok LIM Kenichi TAKEMURA Toru YAMAZAKI RN EE ES Hiroki NAKAMURA Hideaki KATOGI Eiichi TAKAYAMA 44 Experimental Study of the Cooperative Relation between Driver s Psychophysiological Function and Vehicle Behavior Aiming for Application to Next Generation Transportation System Midori MORI Hidetoshi NAKAYASU SN CS EE SEN Haruki MATSUURA Tetsuya MIYOSHI ee bl Two dimensional Magnetic Field Modulation of Current voltage Characteristics of Superconducting Josephson Junctions and Superconducting Quantum Interference Devises 22 Akiyoshi NAKAYAMA SusumuABE Tetsuo ANADA 57 Development of Nano scale Fine Structure Catalysts for Green Chemistry and INovel Energy Processes Shiro HIKICHI Shuichi NAITO Akihniro YOSHIDA Jun NAKAZAWA 66 Structural properties of Water Encapsulated in Carbon Nanotubes Kazuyuki MIATSUDA Hitomi YAHIRO Hirohito AIZAWA Yutaka MANILIWA 76 Synthesis and Battery Performance of Electrocatalysts and Polymer Electrolyte Membrane for Next eneraton Air Battery Futoshi MATSUMOTO Manabu TANAKA Noritosnhi NANBU Shin ya KISHIOKA i SE I NE RE ER EE LD EI EE RE
372. Ice NT 2R 14 4 13 5 24 0 A 220 240 240 KK 2R 79 2R 14 4 260K 240K 200K 180K 160K 120K 100K Intensity a u 260K 240K 10 Peak 200K 180K 160K 120K Intensity a u 1 5 2 2 5 QQ A 1 a Arc SO Arc SO X 3 5 A 14 4 A QO 2 2A 2 A B 2 Ice NT 2 9 Ice NT 2A 14 4 A A B B 2R 13 5 A A
373. Professor Emeritus Assistant Professor Dept of Material and Life Chemistry Akihiro YOSHIDA Jun NAKAZAWA 2012 2013 2
374. Ry 5 2 A Ri 3 5A Rp 4 1A QO 0 7 AT 1 1 X 2R 13 5 A 2R 14 4 A SWCNT SWCNT 2 B 16 83 84 37 1A Rm Rm Ra RI 1 Rr R13 R CNT r A 16 SWCNT B 8 Observed Simulated Intensity a u Observed Simulated Intensity a u 0 5 0 6 0 0 9 1 7 0 8 Q 1 A 17 a Arc SO CR 14 4 A B b 220 K 100 K SWCNT
375. 19 IP o A x 1 J Smger J Arbocz T Weller Buckling Experiments Experimental Methods in Buckling of Thin Walled Structures Volume 2 Shells Built up Structures Composites and Additional Topics John Wiley amp Sons August 2002 2 Hedgepeth J M and Hall D B Stability of Stiffened Cylinders AIAA Journal Vol 3 No 12 1965 pp 2275 2287 3 Tasi J Effect of Heterogeneity on the Stability of Composite Cylindrical Shells under Axial Compression AIAA Journal Vol 4 No 6 1966 pp 1058 1062 4 Jones R M Buckling of Circular Cylindrical Shells with Multiple Orthotropic Layers and Eccentric Stiffeners AIAA Journal Vol 6 No 12 1968 pp 2301 2305 9 Soong T C Buckling of Cylindrical Shells with Eccentric Spiral Type Stiffeners 4744 Journal Vol 7 No 1 1969 pp 5 72 26 6 Onoda J Optmal Lammate Configuratons of Cyhndrical Shells for Axial Buckling AIAA Joumal Vol 23 No 7 1985 pp 1093 1098 7 Weaver P M Amisotropy Induced Spiral Buckling in Compression Loaded Cylindrical Shells 4744 Journal Vol 40 No 5 2002 pp 1001 1007 8 Buckling of Thm_ Walled Circular Cylinders NASA SP 8007 Revised August 1968 9 CFRP
376. 2 mA 800 Magnetic Field H A m 800 Magnetic Field H A m 2 b2 Vi 020 mV 800 Magnetic Field H A m 800 0 800 Magnetic Field A m 61 62 37 el Josephson current mA 800 1 0 c1 Josephson current mA 8S00 lt lt 0 0 5 0 2 3 9 2 gt 800 00 800 e2 Vi 0 20 mV mA 800 c2 Vi 0 20 mV 800 lt 3 Ne x 2 0 LL 0 3 9 2 800 800 800 d Josephson current 800 gt gt a 0 0 on gt 800 800 f2 Vi 0 20 mV 800 0 800 800 Magnetic Field H A m gt 5 c 4000Am 0 Q d 4000A m 4000A m 8 800 800 0 800 Magnetic Field A m 2 63 3
377. 2008 8 1 1 SUM AUT pp 102 114 2000 12Matsui M Manufacturing and Service Enterprise wth Risks A Stochastic Management Approach Springer 2008 13 Matsun Enterprise with Risks JI The Physics and M Manufactummg and Service Economncs of Management Springer 2014 4 2MGM 2008 15 ERP SCM 2010 16 OR pp 142 143 2010 1 3M amp I No 36 pp 40 45 2013 18 pp 16 21 2014 19
378. 240 K SWCNT wet dry 240 K wetdry 2R 13 5 14 4 A SWCNT SWCNT NMR SWCNT lt 240 K NMR SWCNT 240K 6 3 SWCNT 2 13 5 14 4 24 0 A X NMR SWCNT 2R 13 5 14 4A SWCNT
379. J Skills Rules and Knowledgei Signal and Symbols and Other Distinctions in Human Performance Models IEEE Transaction on Systems Man and Cybernetics Vol SMC 13 No 3 1983 pp 257 266 HONDA 2010 8 SR Research EyeLink TI User Manual 1 Version 2 11 SR Research Ltd 2005 2000 pp 98 94 0 1994 pp 859 868 1 2002 57 A A 2 Two dimensional Magnetic Field Modulation of Current voltage Characteristics of Superconducting Josephson Junctions and Superconducting Quantum Interference Devises Akiyoshi NAKAYAMA 1 1911 4 2K G
380. Josephson current 3000 mA Magnetic Field H A m 3000 c Josephson current 3000 Magnetic Field H A m 3000 3000 0 3000 Magnetic Field H A m 2 3 c 4000A m 60 37 d Josephson current 3000 mA Magnetic Field Hy A m 3000 e Josephson current 3000 mA Magnetic Field Hy A m 3000 Josephson current 3000 Magnetic Field Hy A m ew 3000 3000 0 3000 Magnetic Field H A m 2 d 4000A m e 4000A m f 4000A m 0 0 0 5 0 0 HU FV TV 0V Vr Vr 0 02mV
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382. T Nishimura ACM Trans on Modehng and Computer Simulation 8 3 1998 6 http www math soi hiroshima u ac p m mat MT mt htm1 7 1982 8 E P Bernard W Krauth and D B Wilson Phys Rev E 80 056704 2009 9 H Suwa and S Todo Phys Rev Lett 10S 120603 2010 10 66 370 2011 11 K S Turitsyn M Chertkov and M Vucelja Physica D 240 410 2011 12 Y Sakai and K Hukushima J Phys Soc Jpn 82 064003 2013 13 K Hukushima and Y Sakai J Phys Cont Ser 473 012012 2013 14 S G Itoh and H Okumura J Chem Theory Comput 9 570 2013 15 N Metropolis A W Rosenbluth M N Rosenbluth A H Teller and E Teller J Chem Phys 21 1087 1953 16 17 CPU
383. Yabushita J Liu K Okamura T Kobayashi Phys Chem Chem Phys 14 9696 2012 8 M S Kharasch G Stampa W Nudenberg Science 116 309 1952 9 L Iwakura A Yabushita T Kobayashi Chem Phys Lett S01 567 2011 10 L Iwakura Phys Chem Chem Phys 13 5546 2011 1 Iwakura A Yabushita J Liu K Okamura S Kezuka T Kobayashi Pure and appl Chem 8S 1991 2004 2013 10 ss NG 5 A7 YI YN SN Monte Carlo Methods In Statistical Physics Munetaka SASAKIF 1 1940 1960 13 2 2 1946 ENIAC 3 000 10
384. for OER at 0 04 mAcm 2 V SS ST STS SC EC EE 8S CT CT CTT CJ ES CS 8 gg 3 3 3 3 9 9 3 tt 3 SE sr mr ae ea z zz FF F 3 3 3 FF 3 3 LC CE Figure 12 0 04 and 0 04 mAcm RuO2 NiO2 IrO2 NirnRuizO and IrRurO n 0 1 0 6 1 0 m 0 1 0 0 1 M KOH 10 mV s 2000 rpm 3 3 1 LiPON
385. wu 1 Sh G 2WS X KO 7 x exp AC L O 2 A og 2 AR Xx AR gt dR he BG SWCNT exp A 7 4 Bi B B O BG B DT B 2 3 2 14 4 A 1 0 A 266 82 A 5 88 94 A 3 44 47 A 20 52 A wu 40 w 5 409 415 A 0 05 0 5 10 Peak Vacuum a Observed Simulated SWCNT Bundle Intensity a u 0 2 0 4 0 6 0 8 1 1 2 1 4 O 1 A 10 Peak Vacuum b Observed a Sim
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387. 1 1 Vol 7 2012 2 p 29 2 Vol 30 2004 3 p 120 3 2007 p 21 http www jsae or jp formula jp 2014 10 16 0 51 2 Experimental Study of the Cooperative Relation between Drivers Psychophysiological Function and Vehicle Behavior Aiming for Application to Next Generation Transportation System Midori MORI Hidetoshi NAKAYASU 1
388. 15 T Nagataki K Ishii Y Tachi S Itoh Dalton Trans 2007 1120 16 M M Diaz Requejo T R Belderrain M C Nicasio P J P rez Organometallics 19 2000 285 17 S Hikichi M Kaneko Y Miyoshi N Mizuno K Fujita M Akita Top Catal 2 2009 845 18 K Fujita M Akita S Hikichi Inorg Chim Acta 362 2009 4472 19 112 2J05 2013 9 20 114 2D01 2014 9 21 N A Brunelli K Venkatasubbaiah C W Jones Chem Mater 24 2012 2433 J A Structural properties of Water Encapsulated in Carbon Nanotubes Kazuyuki MATSUDA Hitomi YAHIRO Hirohito AIZAWA Yutaka MANIWA 1 SWCNT Smgle Walled Carbon Nanotube SWCNT 1
389. 17 T Tsnr 0 04J NNI b T T 0 04J FaW 2 1 5 1 0 5 4 2 F mi ml 2 Tsgr 0 33 7 J 7 lt 7skr 7 gt 7ssr jm am Fmin min 7 Fuif lt 7 25 L 256 L 1 1 256 1 65 535 NG WAR S539 4 2 m
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391. 5 11 N Watanabe A Nakayama S Abe etal Appl Phys Vol 103 13 A Nakayama S Abe N Watanabe J Appl Phys Vol lll Pages Pages 07C707 2008 113907 1 2012 12 N Watanabe A Nakayama S Abe et al J Appl Phys Vol 105 14 A Nakayama S Abe N Watanabe Microelectronic Engineering Pages 07E312 2009 Vol 108 Pages 93 98 2013 Development of Nano scale Fine Structure Catalysts for Green Chemistry and Novel Energy Processes Shiro HIKICHI Shuichi NAITO 1
392. 6H2O CoSBA SH or SAc Tp r Co D UV vis 4 5 6 MeO Si a Meo OoMe ee si OMe 6 uronic O MM mol pn sh 1 HO conc HCI 2 Soxhlet extraction O si oMe 1 Eto oEt 3 MesSD2NH 0 Y vsH TEOS 100 x mol S AIBN i radical initiator KGaly Tp oO SK o SC CF CF gt s OMe C si oMe O c BN N K Se O ci BvN N K eg O 3 N cr 09 _OM gt 09 _OM S Si Ne Scr CI SI 5 cr O S O Ok MY GE O 7 SBA SAc TpCF3 x CoBr2 6H20 MeCN SBA SH TpCF3_y CoBr 6H2O MeCN Co SBA SAc TpCF3 x Co SBA SH TpCF3 x 4 Tp Co Co allyLTp CBr Co allyLTp OAc 1 Co allyLTp x 0 5 Co allyLTp Br
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394. 76 ENO EN1 1571 1583 1594 1605 1645 1624 1634 1642 16 5 1857 1887 ENO EN11051 90946 0 12 7 89444 ENO EN1 11556 55 159 1589 9 08 1618 1626 1634 164 ENO EN1 3 4015 1001 0988 0975 0964 0953 0 944 0 gar 0 13 7 7118 ENO EN1 1537 43 156 157 531 15 9 0599 16 0 ENO EN1 OO ESS 0 942 0 014 7 50481 ENO EN1 1517 1528 1539 155 154 ENO EN1 0 15 7 27222 ENO EN1 EN0 EN1 DE EN1 8 521562 8 78547338 9 119624 8 1683 98 7 0949 0343 0 9833 0833 0993 0928 0927 0927 09 0 01 7 32796 ENO EN1 1400 1R1 1591 1529 1542 1552 1521 569 15 77 15 84 1591 1597 380 EE 8 16 1 16 11 r16 1 1 1 LO Le ENO EN1 ns 0876 0868 086 0854 0848 0 844 0 02 8 14475 ENO EN1 1531 1592 1603 1614 9 1666 1673 167 1708 1712 1715 1717 17 18 1718 1716 1713 1708 3 0 906 0 962 0 95 0 956 10955 0956 0958 0381 Ua gr 097 0968 0 967 0 967 or 7661 7 776 7 887 7 993 8 094 8 191 8 281 8 366 8 444 8 516 8 581 8 637 8 686 8 726 8 756 8 776 8 785 8 782 8 766 8 734 8 8 615 8 52 8 396 8 234 8 025 7 757 A il si TS 1585 1 TIN NI YS 169 1692 1693 1693 16 1688 1883 1676 EE r r r 2 0933 0938 034 1689 1673 16 52 16 25 16 25 159 P r r 2 58 1095 1095 1 1 1704 1692 1676 16 55 16 28 16 28 15 93 Li AP ee pe 993 1062 1099 1099 1 15 712 1703 169 1674 16 53 16 27 Fr r r ne ne pd 1 05 1 097 1037 5 1708 1699 1686 167 16 49 16 r r
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397. I ER GE ED EE SE TS SEED EE SEE I 3 ES EE 86 Essay Let s on Catalytic Principleg re nn on na te men Wataru UEDA 94 Memories of the Research and Education at Kanagawa University SE Se ER NS CN eS Tadamitsu SAKURAI Sr 97 To tell the truth ee ee CN Ce i ee pe de ie Kiyomasa NARITA 101 ight Years at Kanagawa University Yasushi WATANABE 105 Life in a Wonderland oiooo Yoshio WATANABE 109 Annual Reports of the Ingstitute 113 Manuscrnpt Submission Instruction ee 121 Letters from the Editors RE A RN Ts 125 Integrated Engineering Education and Research Capable of Coping with Changes of the Global Society Hum ok Lim 21
398. Laplace 1749 1827 5 r 1 826 213 3 1 2 3 The law of succession ofLaplace 1812 8 9 6 43 3
399. N 57 NN ES ES Cs 66 RE ER ES EGE EE 76 DR i NN 86 LL a ga EE 94 ee 2 OY i 97 ee ee Fe ee 101 i ee a EE 105 TO ed i a SE EE EEN ES 109 ER NN ES is 113 121 ER EE EN eS ES RDNS SE Pe 125 CONTENTS Preface Integrated Engineering Educatnon and Research Capable of Coping with Changes of the Global SOclety Hun Ok LIM a et Review Smart Society and Machine Learning i Masanor1iAKIYOSHI 2 Direct Observation of Transition State using Ultrafast Spectroscopy A SE EC Ei i i i 1zurm1 IWAKURA ee 6 Monte Carlo Methods in Statnstical Physics Munetaka SASAKI 10
400. NiTp 2 un OH 2 2 6 pmol 6 13 0 mmol CHzCl 1 00 mL 313 K Ar 1 h 4p 4 Tp Tp Tp Tp r Ni II OH NiTp W OH 2 mCPBA UV vis in situ ITR Ni D NiYY OOCO C HLCDTp Tp iPr Ni Tp 40C ee Tp
401. T 0 04 0 02 80 100 120 140 160 180 200 220 240 Temperature K 11 1 IL II 10 CR 13 5 A Ice NT 0 MEIJO Arc SO 2R 14 4A T G 12 SWCNT 3 1 A3 13 SWCNT A A Rr Renr r A a Observed Simulated In tensity a u 0 3 2R 13 S A smmmm Observed Simulated I Intensity a u 0 9 1 0 7 0 8 Q 1 A 14 a CR 13 5 A A b 240 K 100 K 2 13 5 A SWCNT A 14 SWCNT Rew 6 7 A 240 K Rr 47A 100K Ri 2 8 A
402. anagawa University Yasushi WATANABE 1 2015 3 8 60 55 2 65 63 65 65 2
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404. istant Professor Dept of Apphed Chemstry Tokyo Metropohtan University Assocnate Professor Dept of Life Sclence and Sustainable Chemnstry Tokyo Polytechnmc Unnversty Assoclate Professor Dept of Chemistry Faculty of Education Gunma Umnversity 1 PD 2 OO Li 2013 Cathode Anode 0 Zn Zn 2e H O EH 4OH gt Figure1 2 2 1
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406. oducts with a cardinal factor Topology and Appl 49 1993 141 148 8 R Telgarsky Spaces defined by topological games Fund Math 88 1975 193 223 9 Y Yajima Products of monotonically normal spaces with fac tors defined by topological games Topology and Appl 1S9 2012 1223 1235 36 ZN Ea YA Y 4 MC NY WW Win 51 A VN VY 3M amp I The 3M amp I Variety Body approach Enterprnse Particle and Balancing lssues Masayuki MATSUT 1 CSPS 0 3M amp I ERP SCM
407. onal a MnO Mn CHiCOO KMnOs 350 10 h Mn Mn CHsCOO KMnO XRD SEM BET 10 mVs 2000 pm BET Fig 9 Mn Ru MnO oc MnO Ru n 0 6 Mn Ru O gt RuNiyO Hig 10
408. rical Shells of Sandwich Construction NACA TN 2601 Jan 1952 19 Geier B and Singh G Some Simple Solutions for Buckling Loads of Thin and Moderately Thick Cylindrical Shells and Panels Made of Laminated Composite Material Aerospace Science and Technology 1997 No 1 pp 47 63 20 Resse C D and Bert C W Buckling of Orthotropic Sandwich Cylinders Under Axial Compression and Bending Journal of Aircrajft Vol 11 No 4 1974 pp 207 212 21 Kardomateas G A and Philobos M S Buckling of Thick Orthotropic Cylindrical Shells Under Combined External Pressure and 37 Axial Compression 4744 Journal Vol 33 No 10 1995 pp 1946 1953 22 Bisagni C Numerical analysis and experimental correlation of composite shell buckling and post buckling Composites Part B Engineering Vol 31 No 8 2000 pp 655 667 23 Hilburger M W Nemeth M P and Starnes J H Jr Shell Buckling Design Criteria Based on Manufacturing Imperfection Signatures AIAA Journal Vol 44 No 3 2006 pp 654 663 24 Bruhn E F Analysis and Design of Flight Vehicle Structures Jacobs Pub Indianapolis IN 1973 Chap 8 25 Weingarten V 1 Morgan E J and Seide P Elastic Stability of Thin Walled Cylindrical and Conical Shells under Axial Compression 4744 Journal Vol 3 No 3 1965 pp 300 305 26
409. rst Order Second_Momentmethods vY lt 9 2 9 5 kmockdown factor 9 knockdown fctor A NE ES knockdown factor 1 Elishakof
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412. ulated SWCNT Bundle Intensity a u 3 SWCNT X a b 4 SWCNT 2R 13 5 A e DIPS 2R 24 0 A 10 10 Peak 2R 24 A 2R 14 4 2R 13 5 A yD 20 21 IntensitY a u 0 5 1 1 5 2 Q 1 A ty tn 4 MEIJO Arc SO 2R 14 4 A 2R 13 5 A e DIPS 2R 24 0 A 2A 24 0 A
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