SCEJ

$B2=3X9)3X2q(B $BBh(B44$B2s=)5(Bg2q(B

$B9V1i%W%m%0%i%`!J2q>l!&F|DxJL!K(B

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$B:G=*99?7F|;~!'(B2012-08-20 15:02:17

$BBh(B1$BF|(B
$B9V1i(B
$B;~9o(B		$B9V1i(B
$BHV9f(B		$B9V1iBjL\!?H/I=$B%-!<%o!<%I(B$BJ,N`(B
$BHV9f(B		$B$BHV9f(B
$B%7%s%]%8%&%`(B $B!c
(8:40$B!A(B9:40)$B!!(B($B:BD9(B $B?\F#(B $B2mIW(B)
8:40$B!A(B 9:00L100PEFC$BC1%;%k(Bin situ$B29EYLLJ,I[B,Dj%G!<%?$N:YJ,2=$K$h$kEAG.FC@-I>2A$HJ*
($B;0=EBg1!(B) $B!{(B($B3X(B)$B6aF#(B $B90=S(B $B!&(B ($B@5(B)$B@>B<(B $B82(B $B!&(B $B;3Fb(B $BBY2p(B $B!&(B $BHSHx(B $BOB42(B $B!&(B $BW"ED(B $B??;K(B
PEFC
In-plane temperature distribution
Impedance measurement
S-139
9:00$B!A(B 9:20L101$BM-5!(B-$BL55!3&LL9bB.%W%m%H%sEAF38=>]$rMxMQ$7$?8GBN9bJ,;R7AG3NAEECS$N3+H/(B
($BEl9)Bg;q8;8&(B) $B!{(B($B3X(B)$B>.@n(B $B7ILi(B $B!&(B ($B@5(B)$BED4,(B $B9'7I(B $B!&(B ($B@5(B)$BBg66(B $B=(Gl(B $B!&(B ($BElBg9)(B) $B5m;3(B $B9@(B $B!&(B ($B@5(B)$B;32<(B $B980l(B $B!&(B ($BEl9)Bg;q8;8&(B) ($B@5(B)$B;38}(B $BLT1{(B
Fuel Cell
Proton conduction
an initio
S-153
9:20$B!A(B 9:40L102$B>.7?5!4oMQ(BPEFC$B%9%?%C%/$N7ZNL2=5Z$SDc%3%9%H2=$N8!F$(B
($B90A0BgM}9)(B) $B!{(B($B3X(B)$BD%(B $BD6(B $B!&(B ($B@D?98)9)Am8&(B) ($B6&(B)$B3k@>(B $BM5(B $B!&(B ($B%S%C%H%F%C%/(B) $BLZB<(B $B1QM:(B $B!&(B ($B90A0Bg?7%(%M8&(B) ($B@5(B)$B41(B $B9q@6(B $B!&(B ($B90A0BgM}9)(B) ($B6&(B)$B0KF#(B $B> $B!&(B ($BElBg@88&(B) ($B@5(B)$BDi(B $BFX;J(B $B!&(B ($B90A0Bg?7%(%M8&(B) ($B@5(B)$B0$I[(B $BN$Ds(B

S-1110
(9:40$B!A(B11:00)$B!!(B($B:BD9(B $B@>B<(B $B82(B)
9:40$B!A(B 10:00L103$B8GBN9bJ,;R7AG3NAEECS1?E>;~$N2a;@2=?eAG@8@.$NI>2A(B
($B@EBg9)(B) $B!{(B($B3X(B)$B2,K\(B $BM4 $B!&(B ($B3X(B)$B>.Ln(B $B8-;VO:(B $B!&(B ($B@5(B)$B?\F#(B $B2mIW(B
hydrogen peroxide
PEMFC
degradation
S-1354
10:00$B!A(B 10:20L104$BJ#6K@-Kl$rMQ$$$kG3NAEECS$N1?E>FC@-(B
($B@EBg9)(B) $B!{(B($B3X(B)$B1J0f(B $B=(OB(B $B!&(B ($B3X(B)$B2<@n(B $BN<2p(B $B!&(B ($B@EBg(B) ($B@5(B)$B?\F#(B $B2mIW(B
Bipolar membrane
PEMFC
Plasma-Polymerization
S-1416
10:20$B!A(B 10:40L105The Catalytic Properties of Nanoparticled Tantalum-based Catalysts by Electrodeposition under a Nonaqueous Plating Bath for Non-platinum Cathodes of PEFCs
(U. Tokyo) $B!{(B($B3X(B)Seo J. $B!&(B (KAUST) ($B@5(B)Cha D. $B!&(B ($B@5(B)Takanabe K. $B!&(B (U. Tokyo) ($B@5(B)Kubota J. $B!&(B ($B@5(B)Domen K.
PEFC
Electrodeposition
Ta-based catalysts
S-1491
10:40$B!A(B 11:00L106$BJ.L84%AgK!$KCf6u%]!<%i%9%+!<%\%sN3;R$N9g@.$HG3NAEECS?(G^$X$N1~MQ(B
($B9-Bg1!9)(B) $B!{(B($B@5(B)$B2.(B $B?r(B $B!&(B Ratna Balgis $B!&(B ($B@5(B)$B1|;3(B $B4n5WIW(B $B!&(B ($B%N%j%?%1%+%s%Q%K!<%j%_%F%I3+H/5;=QK\It(B) G. M. Anilkumar $B!&(B $B:89g(B $B@!?M(B
Proton exchange membrane fuel cell
Electrocatalyst
spray drying
S-1638
(11:00$B!A(B12:00)$B!!(B($B;J2q(B $BED4,(B $B9'7I(B)
11:00$B!A(B 12:00L107[$B>7BT9V1i(B] $BF|;:<+F0u$HE8K>(B
($BF|;:<+F0
Polymer electrolyte fuel cell
S-1459
(13:00$B!A(B14:20)$B!!(B($B:BD9(B $BJ!D9(B $BGn(B)
13:00$B!A(B 13:20L113$BC:2=?eAG7OEE2r
($BEl5~;TBg(B) $B!{(B($B3X(B)$B6b;R(B $BBYN4(B $B!&(B $BD9C+@n(B $BK-(B $B!&(B $BFbCS(B $BAo;V(B $B!&(B ($B@5(B)$BIp(B $BE/IW(B
Polymer Electrolyte Fuel Cell (PEFC)
Silica
Hydrocarbon membrane
S-1661
13:20$B!A(B 13:40L114$B0[$J$k%7%j%+8;$K$h$jD4@=$7$?%7%j%+HoJ$(BCNT$BC4;}(BPt$B%+%=!<%I?(G^$N3h@-$HBQ5W@-(B
($B6eBg1!9)(B) $B!{(B($B3X(B)$B1'ET5\(B $BM5(B $B!&(B $B5\K\(B $BBsL@(B $B!&(B ($B@5(B)$BC]Cf(B $BAT(B $B!&(B ($B@5(B)$B>>:,(B $B1Q $B!&(B ($B@5(B)$B4_ED(B $B>;9@(B
Pt catalyst
fuel cell
silica
S-1667
13:40$B!A(B 14:00L115PEFC$BMQ%+!<%\%s%J%N%A%e!<%VC4;}(BPd$B%+%=!<%I?(G^$NA+0\6bB0E:2C$K$h$k?(G^3h@-8~>e(B
($B6eBg1!9)(B) $B!{(B($B3X(B)$BDMK\(B $BCR@2(B $B!&(B ($B@5(B)$BC]Cf(B $BAT(B $B!&(B ($B@5(B)$B>>:,(B $B1Q $B!&(B ($B@5(B)$B4_ED(B $B>;9@(B
PEFC
Pd alloy catalyst
oxygen reduction reaction
S-1685
14:00$B!A(B 14:20L116$B%W%m%H%sEAF3@-%j%s;@%,%i%9$N9g@.$HEE5$EAF3FC@-(B
($BElBg1!?7NN0h(B) $B!{(B($B3X(B)$B@nB<(B $BN $B!&(B ($B@5(B)$BBgM'(B $B=g0lO:(B $B!&(B ($B@5(B)$BBgEg(B $B5A?M(B
fuel cell
proton conducting glass material
sol-gel method
S-1765
(14:20$B!A(B15:40)$B!!(B($B:BD9(B $BC]Cf(B $BAT(B)
14:20$B!A(B 14:40L117Nafion$B%-%c%C%T%s%0BN$rMQ$$$?EE6K?(G^AX$N?(G^MxMQN(8~>e$K8~$1$?8!F$(B
($BEl9)Bg;q8;8&(B) $B!{(B($B3X(B)$BCfEg(B $BC#:H(B $B!&(B ($B@5(B)$BED4,(B $B9'7I(B $B!&(B ($B@5(B)$BBg66(B $B=(Gl(B $B!&(B ($B@5(B)$B;38}(B $BLT1{(B
PEFC
Catalyst layer
Nafion Capping
S-1820
14:40$B!A(B 15:00L118$B%"%s%b%K%"=hM}$7$?%7%k%/3h@-C:$r%+%=!<%I$KMQ$$$?(BPEFC$B$NH/EEFC@-(B
($B?.=#BgA!0](B) $B!{(B($B@5(B)$BJ!D9(B $BGn(B $B!&(B $BBg;3(B $B63J?(B $B!&(B ($B@5(B)$B9b66(B $B?-1Q(B $B!&(B ($B@5(B)$B9bDM(B $BF)(B $B!&(B ($BBgF|K\0u:~(B) ($B@5(B)$B4_K\(B $BHfO$;V(B
PEFC
non-precious metal catalysts
carbon
S-1956
15:00$B!A(B 15:20L119$B9g6bI=LL$KD>@\9g@.$7$?%+!<%\%s%J%N%A%e!<%V$N%0%k%3!<%9G3NAEECSEE6K$X$N1~MQ(B
($B5~Bg9)(B) $B!{(B($B3X(B)$B;y6L(B $B9dIp(B $B!&(B ($B@5(B)$B:4Ln(B $B5*>4(B $B!&(B ($B@5(B)$BEDLg(B $BH%(B
fuel cell
carbon nanotube
chemical vapor deposition
S-17
15:20$B!A(B 15:40L120A Facile Thermal Method for Producing Novel 3-D Graphite Oxide-Nanoribbon Supported Metal Electrocatalysts for DMFC
($BEl9)Bg;q8;8&(B) $B!{(B($B3X(B)$B]j(B $B3$NS(B $B!&(B ($B@5(B)Kakade B. A. $B!&(B ($B@5(B)$BED4,(B $B9'7I(B $B!&(B ($B@5(B)$BBg66(B $B=(Gl(B $B!&(B ($B@5(B)$B;38}(B $BLT1{(B
DMFC
methanol oxidation reaction
graphite oxide, nanoribbon
S-1298
(15:40$B!A(B17:00)$B!!(B($B:BD9(B $B;38}(B $BLT1{(B)
15:40$B!A(B 16:00L121$B9bG;EY%a%?%N!<%k$r;HMQ$9$kD>@\%a%?%N!<%k7?G3NAEECS$NH/EEFC@-(B
($B72Bg1!9)(B) $B!{(B($B3X(B)$B]/0f(B $B=!(B $B!&(B ($B@5(B)$BDT8}(B $BBsLi(B $B!&(B ($B@5(B)$BCf@n(B $B?B9%(B
direct methanol fuel cell (DMFC)
boiling point
air humidity
S-1302
16:00$B!A(B 16:20L122$B%O%$%Q!<%V%i%s%A%]%j%^!<$rMQ$$$?D>@\%.;@7?G3NAEECS$NEE6K:n@=J}K!$N8!F$(B
($B72Bg1!9)(B) $B!{(B($B@5(B)$BDT8}(B $BBsLi(B $B!&(B ($B3X(B)$B4d>e(B $BM@6k(B $B!&(B ($B3X(B)$B>.V:(B $BL((B $B!&(B ($B@5(B)$BCf@n(B $B?B9%(B $B!&(B ($BF|;:2=3X(B) $B>.Eg(B $B7=2p(B
DFAFC
Hyper branched-polymer
Stablizer
S-1458
16:20$B!A(B 16:40L123$BD>@\%.;@7?G3NAEECS$NFC0[$J%+%=!<%I2aEE05$NA}2C(B
($B72Bg1!9)(B) $B!{(B($B3X(B)$B4d>e(B $BM@6k(B $B!&(B ($B@5(B)$BDT8}(B $BBsLi(B $B!&(B ($B@5(B)$BCf@n(B $B?B9%(B
DFAFC
Cathode overvoltage
Low concentration
S-1561
16:40$B!A(B 17:00L124TiO2$B4^M-(BCNF$BC4;}(BPtRu$B?(G^$N%"%k%3!<%k;@2=FC@-(B
($B72Bg1!9)(B) $B!{(B($B3X(B)$B0KF#(B $BM:Bg(B $B!&(B ($B@5(B)Abdelkareem Mohammad Ali $B!&(B ($B@5(B)$BDT8}(B $BBsLi(B $B!&(B ($B@5(B)$BCf@n(B $B?B9%(B
DAFC
catalyst
TiO2
S-1679
(17:00$B!A(B18:20)$B!!(B($B:BD9(B $BCf@n(B $B?B9%(B)
17:00$B!A(B 17:20L125$BM}A[E*(BOH-$BEAF3%A%c%M%k$NC5:w$K8~$1$?J,;R%G%6%$%s7?5!G=@-:`NA$N3+H/(B
($BEl9)Bg;q8;8&(B) $B!{(B($B3X(B)$BD9C+@n(B $B00(B $B!&(B $B>1;R(B $BNI98(B $B!&(B $BJ!Eg(B $B9'E5(B $B!&(B ($B@5(B)$BBg66(B $B=(Gl(B $B!&(B ($B@5(B)$BED4,(B $B9'7I(B $B!&(B ($B@5(B)$B;38}(B $BLT1{(B
SAFC
micro phase separation
anion exchange membrane
S-1823
17:20$B!A(B 17:40L126$BA48GBN7?%"%k%+%jG3NAEECSMQEE2r
($BEl9)Bg;q8;8&(B) $B!{(B($B3X(B)$BCz(B $B9aH~(B $B!&(B ($B@5(B)$BBg66(B $B=(Gl(B $B!&(B ($B@5(B)$BED4,(B $B9'7I(B $B!&(B ($B@5(B)$B;38}(B $BLT1{(B
fuel cell
Layered double hydroxide
anion conductor
S-1836
17:40$B!A(B 18:00L127$B:Y9&%U%#%j%s%07?%"%K%*%s8r49Kl$NFC@-$HH/EE;~?e0\F0$N2r@O(B
($BEl9)Bg;q8;8&(B) $B!{(B($B3X(B)$BD%(B $B^>(B $B!&(B ($B@5(B)$BBg66(B $B=(Gl(B $B!&(B ($B@5(B)$BED4,(B $B9'7I(B $B!&(B ($B@5(B)$B;38}(B $BLT1{(B
Anion exchange membrane
Water movement
Pore filling membrane
S-1847
18:00$B!A(B 18:20L128$BCf29:nF0%W%m%H%sEAF37?G3NAEECS$K$*$1$k3F
($BElBg1!?7NN0h(B) $B!{(B($B3X(B)$BEhED(B $B8^I4N$(B $B!&(B ($B@5(B)$BBgEg(B $B5A?M(B $B!&(B ($B@5(B)$BBgM'(B $B=g0lO:(B
intermediate temperature fuel cell
proton conductor
anode reaction
S-1547

$BBh(B2$BF|(B
$B9V1i(B
$B;~9o(B		$B9V1i(B
$BHV9f(B		$B9V1iBjL\!?H/I=$B%-!<%o!<%I(B$BJ,N`(B
$BHV9f(B		$B$BHV9f(B
$B%7%s%]%8%&%`(B $B!c
(8:40$B!A(B9:40)$B!!(B($B:BD9(B $B5FCO(B $BN4;J(B)
8:40$B!A(B 9:00L200$B%j%A%c!<%8%c%V%k!&%=%j%C%I%+!<%\%sG3NAEECS$K$*$1$kH/EEFC@-$NG3NA0MB8$H%a%+%K%:%`(B
($BEl9)Bg2=3X(B) $B!{(B($B3X(B)$BDD(B $B1P(B $B!&(B ($B3X(B)$BLp?a(B $BL@K!(B $B!&(B ($B3X(B)$BEDCf(B $BM5 $B!&(B ($B@5(B)$B0K86(B $B3X(B
fuel cells
SOFC
direct carbon
S-1986
9:00$B!A(B 9:20L201$B%j%A%c(B-$B%8%c%V%k!&(BDCFC$B$K$*$1$kG3NA6KH?1~%5%$%/%k$X$N1F6AMW0x$N8!F$(B
($BEl9)Bg2=3X(B) $B!{(B($B3X(B)$BEDCf(B $BM5 $B!&(B ($B3X(B)$BLp?a(B $BL@K!(B $B!&(B ($B3X(B)$BM{(B $B?71'(B $B!&(B ($B3X(B)$BDD(B $B1P(B $B!&(B ($B@5(B)$B0K86(B $B3X(B
solid oxide
fuel cell
direct cabon
S-1988
9:20$B!A(B 9:40L202$B8GBN;@2=J*7AG3NAEECS$K$*$1$kC:2=?eAGMxMQ$K8~$1$?7W;;2=3X2r@O(B
($B6eBg0p@9%;(B/$B6eBg(BI2CNER/JST-CREST) $B!{(B($B@5(B)$B8E;3(B $BDL5W(B $B!&(B ($B6eBg1!9)(B) $BED86(B $B=S2p(B $B!&(B ($B6eBg1!9)(B/$B3X?6(B) $BCfHx(B $BOB1Q(B $B!&(B ($B6eBg0p@9%;(B/JST-CREST) Saha Leton $B!&(B ($B@5(B)$B@P85(B $B9'2B(B
Solid Oxide Fuel Cell
Hydrocarbon
Anode
S-1166
(9:40$B!A(B11:00)$B!!(B($B:BD9(B $BBgM'(B $B=g0lO:(B)
9:40$B!A(B 10:00L203$B%+!<%\%sE:2CJ.L8G.J,2rK!$K$h$k(BSOFC$B:`NA%J%NN3;R$N9g@.(B
($B:eI\Bg1!9)(B) $B!{(B($B3X(B)$B%"%i%9%H(B $B%"%_%k%l%6(B $B!&(B ($B@5(B)$BLZ2<(B $BBnLi(B $B!&(B ($B@5(B)$BB-N)(B $B85L@(B
spray pyrolysis
SOFC
electrolyte
S-1204
10:00$B!A(B 10:20L204$BFs
($B:eI\Bg9)(B) $B!{(B($B3X(B)$BH+;3(B $BNN(B $B!&(B ($B@5(B)$BG_:j(B $BM'Lp(B $B!&(B ($B3X(B)$B8~0f(B $B7r?M(B $B!&(B ($B@5(B)$BDE5W0f(B $BLP $B!&(B ($B@5(B)$BB-N)(B $B85L@(B $B!&(B ($B:eBg;:8&(B) ($B@5(B)$B0f $B!&(B ($B@5(B)$BB?:,(B $B@5OB(B $B!&(B ($B@5(B)$BCfEh(B $B1QM:(B
SOFC
SIMS
Diffusion
S-1249
10:20$B!A(B 10:40L205$BAX>u%Z%m%V%9%+%$%H;@2=J*(BPr1-xM1+xInO4(M=Ba, Sr)$B$rEE2r
($BEl9)Bg2=3X(B) $B!{(B($B3X(B)$BM{(B $B?71'(B $B!&(B ($B3X(B)$BEgED(B $B42G7(B $B!&(B ($B@5(B)$B0K86(B $B3X(B
Solid oxide fuel cell
electrolyte
ionic conductor
S-1309
10:40$B!A(B 11:00L206$B:.9gEAF3BN$rMQ$$$?(BSOFC$BG3NA6K$N8&5f(B
($BElBg1!9)(B) $B!{(B($B3X(B)$BFn(B $BC$;V(B $B!&(B ($B@5(B)$B5FCO(B $BN4;J(B $B!&(B ($B@5(B)$B9b3@(B $BFX(B $B!&(B ($B@5(B)$B?{86(B $B9'(B $B!&(B Oyama S. T.
SOFC
anode
mixed ionic and electronic conductor
S-1355
(11:00$B!A(B12:00)$B!!(B($B;J2q(B $BIZ=E(B $B7=0l(B)
11:00$B!A(B 12:00L207[$B>7BT9V1i(B]$B8GBN;@2=J*7AG3NAEECS(B(SOFC)$B$N3+H/F08~$HNt2=BP:v(B
($B5~Bg(B) $B!{9>8}(B $B9@0l(B
SOFC
S-1111
(13:00$B!A(B14:40)$B!!(B($B:BD9(B $B0K86(B $B3X(B)
13:00$B!A(B 13:20L213Suitable operational strategy to utilize wasted heat from micro-CHP systems
(Kyushu U.) $B!{(B($B3X(B)Taufiq B. N. $B!&(B ($B@5(B)Ishimoto T. $B!&(B ($B@5(B)Koyama M.
Micro-CHP
Heat pump
CO2 emission
S-1477
13:20$B!A(B 13:40L214Numerical Investigations of a Novel Type of Micro-tubular Solid Oxide Fuel Cell
(Inst. Industrial Sci., The U. Tokyo) $B!{(B($B3X(B)Panthi Dhruba $B!&(B ($B@5(B)Tsutsumi Atsushi
Solid Oxide Fuel Cell
Micro-tubular Design
Computational Fluid Dynamics
S-1689
13:40$B!A(B 14:00L215SOFC$B6u5$6K$K$*$1$k@=B$%W%m%;%9M3MhHyNL@.J,$NEE6KFC@-$KBP$9$k1F6AI>2A(B
($BElBg1!?7NN0h(B) $B!{(B($B3X(B)$BBg@P(B $B=_Lp(B $B!&(B ($B@5(B)$BBgEg(B $B5A?M(B $B!&(B ($B@5(B)$BBgM'(B $B=g0lO:(B
solid oxide fuel cell
minor components
electrode property
S-1764
14:00$B!A(B 14:20L216SOFC$BEE2r=@-$H=PNO$NAj4X(B
($B:eI\Bg9)(B) $B!{(B($B3X(B)$B8~0f(B $B7r?M(B $B!&(B ($B3X(B)$BH+;3(B $BNN(B $B!&(B ($B@5(B)$BDE5W0f(B $BLP $B!&(B ($BETN);:5;9b@l(B) ($B@5(B)$B5HED(B $B7r0l(B $B!&(B ($B:eI\Bg9)(B) $B@P66(B $B9-5-(B $B!&(B ($B@5(B)$BB-N)(B $B85L@(B $B!&(B ($B;:5;8&(B) $Bd*(B $BK'<#(B $B!&(B $B:4F#(B $BOBO:(B $B!&(B $BF|2<(B $BCi6=(B
SOFC
PLD
Electrolyte
S-1771
14:20$B!A(B 14:40L217$B:n@=K!$N0[$J$k(BSOFC$BMQ%Z%m%V%9%+%$%H7?;@2=J*%"%N!<%I$NH/EEFC@-(B
($B?.=#BgA!0](B) $B!{(B($B3X(B)$BEOn5(B $B85(B $B!&(B $B>>;3(B $BIp;V(B $B!&(B ($B@5(B)$B9b66(B $B?-1Q(B $B!&(B ($B@5(B)$B9bDM(B $BF)(B $B!&(B ($B@5(B)$BJ!D9(B $BGn(B
solid oxide fuel cell
anode
perovskite
S-1913
(14:40$B!A(B15:20)$B!!(B($B:BD9(B $BED4,(B $B9'7I(B)
14:40$B!A(B 15:00L218$B:F@8C:AGA!0]$N%j%5%$%/%k5;=Q(B
($B4tIlBg9)(B) $B!{(B($B3X(B)$B@>B<(B $B8-Bg(B $B!&(B ($B@5(B)$B $B!&(B ($B@5(B)$B7(It(B $BOB90(B
CFRP
calcination
pyrolysis
S-1656
15:00$B!A(B 15:20L219$B%j%5%$%/%kC:AGA!0]$N6/EYI>2AJ}K!(B
($B4tIlBg9)(B) $B!{(B($B3X(B)$B2CF#(B $B9,@8(B $B!&(B ($B@5(B)$B $B!&(B ($B@5(B)$B?@86(B $B?.;V(B $B!&(B ($B@5(B)$B7(It(B $BOB90(B
Carbon fiber
Tensile strength
Tensile modulus
S-1666

$BBh(B3$BF|(B
$B9V1i(B
$B;~9o(B		$B9V1i(B
$BHV9f(B		$B9V1iBjL\!?H/I=$B%-!<%o!<%I(B$BJ,N`(B
$BHV9f(B		$B$BHV9f(B
$B%7%s%]%8%&%`(B $B!c
(8:40$B!A(B10:00)$B!!(B($B:BD9(B $B2O@%(B $B85L@(B)
8:40$B!A(B 9:00L300$B%a%?%N!<%k%*!<%H%5!<%^%k2~CHq$K4X$9$k8&5f(B
($B7DXfBg(B) $B!{(B($B3X(B)$BBgC+(B $B=a(B $B!&(B $BOBED(B $B>;>M(B $B!&(B M. F. Hasan $B!&(B ($B@5(B)$B2#?9(B $B9d(B $B!&(B ($B@5(B)$B?"ED(B $BMx5W(B
Reforming
Hydrogen
Auto-Thermal
S-1224
9:00$B!A(B 9:20L301$B%*%U%,%9:F=[4D$rH<$&%*!<%H%5!<%^%k2~
($B7DXfBgM}9)(B) $B!{(B($B3X(B)$B;~G$(B $B:L(B $B!&(B ($B3X(B)$B@uLn(B $B;J(B $B!&(B ($B3X(B)Hasan M. F. $B!&(B ($B@5(B)$B2#?9(B $B9d(B $B!&(B ($B@5(B)$B?"ED(B $BMx5W(B
reformer
autothermal
off-gas recirculation
S-1237
9:20$B!A(B 9:40L302$BDLEE2CG.%"%k%^%$%H?(G^$rMQ$$$?%a%?%s?e>x5$2~
($BElG@9)Bg(B) $B!{(B($B3X(B)$B1|Ln(B $B@i1{(B $B!&(B ($B3X(B)$BD%(B $B7D51(B $B!&(B ($B@5(B)$B3T(B $B%f(B $B!&(B ($B@5(B)$B55;3(B $B=(M:(B $B!&(B ($B@5(B)$B:y0f(B $B@?(B
Steam reforming
Anodic alumina support
Nickel catalyst
S-1389
9:40$B!A(B 10:00L303$B%j%s;@7AG3NAEECS%7%9%F%`$N;@2=H?1~4o$H$7$F$N1~MQ(B
($BL>Bg1!9)(B) $B!{(B($B3X(B)$B2->e(B $B?? $B!&(B ($B@5(B)$B;3ED(B $BGn;K(B $B!&(B ($B@5(B)$BED@n(B $BCRI'(B $B!&(B ($BL>;T9)8&(B) ($B@5(B)$B5\ED(B $B9/;K(B
Fuel cell reactor
PAFC
Selecteve oxidation
S-1840
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $B8E;3(B $BDL5W(B)
10:00$B!A(B 10:20L304$BDX303L$r86NA$H$9$k%a%=9&C:AG$ND4@=$H%-%c%Q%7%?FC@-(B
($B:eI\Bg1!(B) $B!{(B($B3X(B)$BBgC+(B $B=S2p(B $B!&(B ($B@5(B)$BIpF#(B $BL@FA(B
capacitor
mesopore
carbon
S-1675
10:20$B!A(B 10:40L305$B%0%i%U%'%s$NMO1U9g@.!"%J%N9=B$@)8f$HBgMFNL%-%c%Q%7%?$X$N1~MQ(B
($BElKLBgB?858&(B) $B!{;0C+(B $BM!(B $B!&(B $B%^%i%Q%s(B $B%5%F%#%C%7%e(B $B!&(B $B1':,K\(B $BFF(B $B!&(B $Bcx5o(B $B9bL@(B $B!&(B ($B@5(B)$BK\4V(B $B3J(B
Graphene
Capacitor
Electrode
S-1466
10:40$B!A(B 11:00L306$B%^%$%/%m%A%c%M%k$r7A@.$7$?9=B$2=EE6K$K$h$kEE5$Fs=EAX%-%c%Q%7%?$NB.EY@-G=8~>e(B
($B5~Bg9)(B) $B!{(B($B3X(B)$BBgAR(B $B:M>:(B $B!&(B ($B3X(B)$B $B!&(B ($B@5(B)$B0f>e(B $B85(B $B!&(B ($B@5(B)$B2O@%(B $B85L@(B
Electrochemical double-layer capacitor
Structured electrode
High discharge rate
S-183
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B0f>e(B $B85(B)
11:00$B!A(B 11:20L307$BHyJ4%;%k%m!<%9!A%]%j%"%/%j%k%K%H%j%kJ#9gA!0]$NC:AG:`NA2=$H%j%A%&%`%$%*%s%-%c%Q%7%?$X$NE,MQ(B
($B:eI\Bg1!9)(B) $B!{(B($B3X(B)$B?eLn(B $B5.A1(B $B!&(B ($B@5(B)$BIpF#(B $BL@FA(B $B!&(B ($B2,;3Bg(B) $B2-86(B $B9*(B $B!&(B $BLZ2<(B $B72Kc(B $B!&(B ($BF|K\%(%/%9%i%s(B) $BBgOB(B $B2B5V(B
lithium ion capacitor
polyacrylonitrile
cellulose
S-1284
11:20$B!A(B 11:40L308$B%j%A%&%`%$%*%sEECS$K$*$1$k3hJ*
($B6bBtBg1!<+(B) $B!{(B($B3X(B)$BC#@n(B $B1Q<#(B $B!&(B $BCSED(B $BCR=((B $B!&(B ($B6bBtBgM}9)(B) ($B@5(B)$BEDB<(B $BOB90(B
Lithium-ion battery
Intercalation electrode
Diffusion process
S-1898
11:40$B!A(B 12:00L309$BL5MOG^H?1~$rMQ$$$??7$7$$%]%j%^!<9g@.$H%j%A%&%`Fs
($BJF;R9b@l(B) $B!{(B($B3X(B)$B%h%O%M%9(B $B%/%j%9%F%#(B $B!&(B ($B3X(B)$B@.ED(B $B5.8w(B $B!&(B ($BJF;R9b@l@l962J(B) $Bzp66(B $BBg $B!&(B ($BJF;R9b@l(B) $B>>0f(B $B0jLi(B $B!&(B $B@V0f(B $BBg5$(B $B!&(B $BC]Fb(B $BM4B@(B $B!&(B $BJ?2,(B $BBsMN(B $B!&(B ($B@5(B)$BC+F#(B $B>05.(B $B!&(B ($BL>Bg1!M}(B) $B5H@n(B $B9@;K(B
non solvent reaction
disulfide
lithium rechargable battery
S-1213
(13:00$B!A(B13:40)$B!!(B($B;J2q(B $BCf@n(B $B?B9%(B)
13:00$B!A(B 13:40L313[$BE8K>9V1i(B]$B%j%A%&%`%$%*%sFs
($BEl9)Bg(B) $B!{(B($B@5(B)$BC+8}(B $B@t(B
LIB
Cathode materials
Fine particles
S-1102
(13:40$B!A(B14:20)$B!!(B($B:BD9(B $B8E;3(B $BDL5W(B)
13:40$B!A(B 14:00L315$B%$%*%s1UBN4^M-5?;w8GBNEE2r2A(B
($BElKLBgB?858&(B) $B!{(B($B@5(B)$B1':,K\(B $BFF(B $B!&(B $B>>Hx(B $BN48<(B $B!&(B $B>.@n(B $B=(G7(B $B!&(B $B4gIt(B $B>M9T(B $B!&(B ($B@5(B)$BK\4V(B $B3J(B
All-solid-state battery
Ionic Liquid
Mass transport
S-1543
14:00$B!A(B 14:20L316$B%$%*%s1UBN4^M-5?;w8GBNEE2r
($BElKLBgB?858&(B) $B!{4gIt(B $B>M9T(B $B!&(B $B>.@n(B $B=(G7(B $B!&(B ($B@5(B)$B1':,K\(B $BFF(B $B!&(B ($B@5(B)$BK\4V(B $B3J(B
All-solid-state battery
Ionic Liquid
High capacity cathode
S-1545
(14:20$B!A(B16:00)$B!!(B($B:BD9(B $B1':,K\(B $BFF(B)
14:20$B!A(B 14:40L317($B9V1iCf;_(B)

100526
14:40$B!A(B 15:00L318$B%_%/%m!&%J%N%/%i%9%?!<9=B$2=$K$h$k6bB0%J%NN3;RKl$N:n@.$HB?@\9gGvKlB@M[EECS$X$N1~MQ(B
($BEl9)Bg2=3X(B) $B!{(B($B3X(B)$BFn(B $B41M4(B $B!&(B ($B3X(B)$B5H2,(B $BfFJ?(B $B!&(B ($B@5(B)$B0K86(B $B3X(B
Solar cells
Metal nanoparticles
Surface plasmon
S-1755
15:00$B!A(B 15:20L319Sb2S3$BA}46H>F3BNB@M[EECS$K$*$1$k8wA}46:`$N(Bpn$B@\9g3&LL$X$NC4;}>uBV$HH/EEFC@-$N4X78(B
($BEl9)Bg2=3X(B) $B!{(B($B3X(B)$B5H2,(B $BfFJ?(B $B!&(B $B;0Eg(B $B?rDw(B $B!&(B ($BIt(B)$B0K86(B $B3X(B
solar cell
Sb2S3
heterojunction
S-1942
15:20$B!A(B 15:40L320Interaction of Metal Nanoparticles and TiO2 during the Introduction into the Photoabsorbing Layer in Plasmonic Dye-Sensitized Solar Cells
($BEl9)Bg2=3X(B) $B!{(B($B@5(B)Loew Noya $B!&(B ($B@5(B)$B0K86(B $B3X(B
dye-sensitized solar cell
metal nanoparticle
localized surface plasmon
S-1944
15:40$B!A(B 16:00L321$BD>8rN.7?29EY:9H/EEAuCV$N@-G=I>2A(B
($BIY;39bEy@lLg3X9;(B) $B!{(B($B@5(B)$B5H@n(B $BJ87C(B $B!&(B ($B@5(B)$BCz;R(B $BE/<#(B $B!&(B $BEg(B $B@/;J(B $B!&(B $B>._7(B $BL/;R(B $B!&(B $B>e:d(B $B@](B
Thermoelectric Power Generation
Design Optimization
Heat Transfer
S-1218
$B9V1i%W%m%0%i%`(B
$B2=3X9)3X2q(B $BBh(B44$B2s=)5(Bg2q(B
(C) 2012 $B8x1W
Most recent update: 2012-08-20 15:02:17
For more information contact $B2=3X9)3X2qElKL;YIt(B $BBh(B44$B2s=)5(Bg2q(B $BLd$$9g$;78(B
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