$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B $BHV9f(B | $B$BHV9f(B | |
N$B2q>l(B $BBh(B1$BF|(B |
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $BC]NS(B $BNI9@(B) |
9:00$B!A(B 9:20 | N101 | $B4JJX$JG4EYB,DjAuCV$rMxMQ$7$?%,%9KDD%1UBN$NG4EYDc2<8=>]$N<+F0B,Dj(B
($B;:Am8&%3%s%Q%/%H(B) $B!{(B($B@5(B)$BAj_7(B $B?r;K(B $B!&(B ($B@5(B)$B6b5WJ](B $B8w1{(B $B!&(B ($B@5(B)$BKRLn(B $B5.;j(B $B!&(B ($B@5(B)$BNkLZ(B $BL@(B | viscosity gas expanded liquid carbon dioxide
| 8-b | 169 |
9:20$B!A(B 9:40 | N102 | $BD6NW3&N.BN%/%m%^%H%0%i%U%#!<$rMQ$$$?ItJ,%b%kBN@Q$d3H;678?t$NB,Dj(B
($B@EBg9)(B) $B!{(B($B@5(B)$B9&(B $B>;0l(B $B!&(B $BEOJU(B $BZe(B $B!&(B ($BCf1{BgM}9)(B) ($B@5(B)$BA%B$(B $B=S9'(B | supercritical fluid chromatography partial molar volume diffusion coefficient
| 8-b | 506 |
9:40$B!A(B 10:00 | N103 | $B2a>j<+M3%(%M%k%.!<7?:.9gB'(B+NRTL$B%b%G%k$K$h$kD6NW3&Fs;@2=C:AG(B+$BMO:^7O$N9b05F0G4EY$N?d;;(B
($BF|BgM}9)(B) $B!{(B($B@5(B)$BFJLZ(B $B>!8J(B $B!&(B $B2,B<(B $BCRI'(B $B!&(B ($B@5(B)$B>>ED(B $B909,(B $B!&(B ($B@5(B)$B7*86(B $B@6J8(B $B!&(B ($BCf1{BgM}9)(B) ($B@5(B)$BA%B$(B $B=S9'(B | HIgh-Pressure Kinematic Viscosity Excess Free Energy Mixing Rule NRTL Model
| 8-b | 260 |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $BAj_7(B $B?r;K(B) |
10:00$B!A(B 10:20 | N104 | $B>o29>o05$+$iD6NW3&NN0h$K$*$1$k%a%?%N!<%k?eMO1U$NM"AwJ*@-$NJ,;RF0NO3XE*8!F$(B
($BElKLBg1!9)(B) $B!{(B($B3X(B)$BA0ED(B $BM*4u(B $B!&(B ($B@5(B)$B>.Ln(B $B9*(B $B!&(B ($B@5(B)$BBgED(B $B>; $B!&(B ($B@5(B)$B:4F#(B $BA1G7(B $B!&(B ($B@5(B)$BCv8T(B $B9((B | dynamics properties simulation water+methanol
| 8-b | 361 |
10:20$B!A(B 10:40 | N105 | $BFs;@2=C:AG2C052<$G$N%J%U%?%l%sM;1UAH@.$N6a@V30J,8w2r@O(B
($B;:Am8&%J%N%7%9%F%`(B) $B!{(B($B@5(B)$BC]NS(B $BNI9@(B $B!&(B ($B@5(B)$BF+(B $B5f(B $B!&(B ($B@5(B)$BGlED(B $B9,Li(B $B!&(B ($B@5(B)$B8E20(B $BIp(B $B!&(B ($B@5(B)$B0MED(B $BCR(B | carbon dioxide solubility near infrared spectroscopy
| 8-b | 292 |
10:40$B!A(B 11:00 | N106 | $BD6NW3&(BCO2$BCf$K$*$1$kCF@-I=LLGH6&?6;R$N6&?6FC@-(B
($B;3M|Bg1!0e9)(B) $B!{(B($B@5(B)$B3@Hx(B $B>J;J(B $B!&(B $BNS(B $B9nMN(B $B!&(B ($B@5(B)$B6aF#(B $B1Q0l(B | supercritical CO2 density fluctuation surface acoustic wave
| 8-g | 105 |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B9&(B $B>;0l(B) |
11:00$B!A(B 11:20 | N107 | $B%(%M%k%.!<<};Y$r%W%i%9$K$9$k0!NW3&(BDME$B$K$h$kHy:YAtN`%*%$%k$N<>=aCj=P
($BL>Bg1!9)(B) $B!{(B($B@5(B)$B?@ED(B $B1Q51(B $B!&(B ($BEECf8&(B) $BM{(B $BK2(B $B!&(B ($BL>Bg1!9)(B) ($B@5(B)$B8eF#(B $B85?.(B $B!&(B ($BEECf8&(B) ($B@5(B)$BKRLn(B $B>0IW(B | Subcritical dimethyl ether Microalgae Wet extraction
| 8-c | 157 |
11:20$B!A(B 11:40 | N108 | Supercritical CO2-Modified Hydrothermal Extraction of Bioactive Compounds from Garcinia mangostana Pericarp
(De La Salle U.) $B!{(B($B3X(B)Kimthet Chhouk $B!&(B (Kumamoto U.) ($B@5(B)Quitain Armando T. $B!&(B (De La Salle U.) Gaspillo Pag-asa D. $B!&(B Maridable Julius B. $B!&(B (Tokyo Tech) ($B@5(B)Shimoyama Yusuke $B!&(B (Kumamoto U.) ($B@5(B)Sasaki Mitsuru $B!&(B (Nagoya U.) ($B@5(B)Goto Motonobu | Supercritical Carbon Dioxide Hydrothermal Mangosteen
| 8-c | 479 |
11:40$B!A(B 12:00 | N109 | $BD6NW3&Fs;@2=C:AG$rMQ$$$?OB4;5L$+$i$NM-2AJ*$NCj=P(B
($BL>Bg1!9)(B) $B!{(B($B3X(B)$B@nK\(B $B=g90(B $B!&(B Machmudah Siti $B!&(B ($B%"%9%-!<(B) ($B@5(B)$BEDCf(B $B2mM5(B $B!&(B ($B%^%k%\%7?](B) $B@1Ln(B $B=!9-(B $B!&(B ($BL>Bg1!9)(B) ($B@5(B)$B8eF#(B $B85?.(B | Supercritical carbon dioxide Japanese citrus bioactive compound
| 8-c | 710 |
|
(13:00$B!A(B14:00)$B!!(B($B:BD9(B $B:48E(B $BLT(B) |
13:00$B!A(B 13:20 | N113 | $BD6NW3&0h$r4^$`9b299b05$G$N%"%j%k%U%'%K%k%(!<%F%k$N%/%i%$%<%sE>0LH?1~$N<}N($X$N29EY$H05NO$N1F6A(B
($BL>>kBgG@(B) $B!{(B($B3X(B)$B>.NS(B $B9/M4(B $B!&(B ($B@5(B)$BA0NS(B $B@590(B $B!&(B ($B@5(B)$BBg>l(B $B@5=U(B | Supercritical Fluid Allyl phenyl ether Claisen Rearrangement
| 8-d | 787 |
13:20$B!A(B 13:40 | N114 | $B9b299b05?eCf$N%.;@$NJ,2rH?1~$KBP$9$k?e$N?(G^:nMQ$HMOG^OB8z2L(B
($BElBg1!?7NN0h(B) $B!{(B($B3X(B)$BF#0f(B $BC#Li(B $B!&(B ($BElBg4D0BK\(B) ($B@5(B)$BNS(B $BN\H~;R(B $B!&(B ($BH,8M9b@l(B) ($B@5(B)$BK\4V(B $BE/M:(B $B!&(B ($B;:Am8&%3%s%Q%/%H(B) ($B@5(B)$B@nyu(B $B?50lO/(B $B!&(B ($B@5(B)$BNkLZ(B $BL@(B $B!&(B ($BElBg1!?7NN0h(B) ($B@5(B)$BBgEg(B $B5A?M(B | formic acid hot-compressed water solvation effect
| 8-d | 77 |
13:40$B!A(B 14:00 | N115 | $B8GBN;@?(G^$rMxMQ$7$?9b299b05?eCf$N%T%M%s$N?eOBH?1~(B
($BElBg1!?7NN0h(B) $B!{(B($B3X(B)$B=)7n(B $B?.(B $B!&(B ($B@5(B)$BBgEg(B $B5A?M(B | Hot and compressed water Pinene Solid acid catalyst
| 8-d | 285 |
(14:00$B!A(B15:20)$B!!(B($B:BD9(B $BA0NS(B $B@590(B) |
14:00$B!A(B 14:20 | N116 | Hydrogenation of Diphenyl Ether in Supercritical Carbon Dioxide using Rh/C catalyst
(AIST Tohoku) $B!{(B($B@5(B)Chatterjee M. $B!&(B ($B@5(B)Kawanami H. $B!&(B ($B@5(B)Ishizaka T. $B!&(B ($B@5(B)Suzuki A. | Supercritical carbon dioxide Hydrogenation diphenyl ether
| 8-d | 111 |
14:20$B!A(B 14:40 | N117 | $B:xBN?(G^$rMQ$$$?D6NW3&Fs;@2=C:AGCf$K$*$1$kFs;@2=C:AG$N8w4T85(B
($B;:Am8&%3%s%Q%/%H(B) $B!{(B($B@5(B)$B@nGH(B $BH%(B $B!&(B ($B%V%k%C%/%X%V%s9qN)8&(B) Grills David C. $B!&(B ($B;:Am8&%3%s%Q%/%H(B) ($B@5(B)$B@P:d(B $B9'G7(B $B!&(B ($B@5(B)$BNkLZ(B $BL@(B | photoreduction supercritical CO2
| 8-d | 318 |
14:40$B!A(B 15:00 | N118 | $B9b299b05?e$K$*$1$k%j%0%K%s@.J,$N4T85(B
($B;:Am8&%3%s%Q%/%H(B) $B!{(B($B@5(B)$B@nGH(B $BH%(B $B!&(B $B>.@n(B $B2BBe;R(B $B!&(B ($B@5(B)$B@nyu(B $B?50lO/(B $B!&(B ($B@5(B)$B@P:d(B $B9'G7(B $B!&(B ($B@5(B)$BNkLZ(B $BL@(B | microreactor high-pressure and high-temperature lignin
| 8-d | 317 |
15:00$B!A(B 15:20 | N119 | Coupling Microwave Irradiation and Hydrothermal Treatment for Degradation and Extraction of More Bioactive Low-Molecular-Weight Fucoidan
(Kumamoto U.) $B!{(B($B@5(B)Quitain Armando $B!&(B ($B@5(B)Kai Takahisa $B!&(B ($B@5(B)Sasaki Mitsuru $B!&(B (Nagoya U.) ($B@5(B)Goto Motonobu | microwave hydrothermal fucoidan
| 8-d | 514 |
(15:20$B!A(B16:40)$B!!(B($B:BD9(B $BBgEg(B $B5A?M(B) |
15:20$B!A(B 15:40 | N120 | $B2C05G.?e$K$h$k$*$+$i$N2DMO2=(B
($B1'ET5\Bg1!9)(B) $B!{(B($B@5(B)$B:4F#(B $B9d;K(B $B!&(B $B=;ED(B $BK-OB(B $B!&(B ($B@5(B)$B0KF#(B $BD> | Bean curd refuse hot compressed water biomass
| 8-d | 338 |
15:40$B!A(B 16:00 | N121 | $BG.?e>r7o2<$K$*$1$k4uGv;@?eMO1U$rMQ$$$?%;%k%m!<%9$N2C?eJ,2r(B
($BCf1{BgM}9)(B) $B!{(B($B3X(B)$BJ?Eg(B $B7r8c(B $B!&(B ($B3X(B)$B>._7(B $B?58c(B $B!&(B ($B@5(B)$BED8}(B $B $B!&(B ($B@5(B)$BA%B$(B $B=S9'(B | cellulose hydrothermal oligomer
| 8-d | 161 |
16:00$B!A(B 16:20 | N122 | $BG.?e>r7o2<$N%a%A%k%"%_%s?eMO1U$rMQ$$$?%]%j%+!<%\%M!<%H$N2r=E9g(B
($BCf1{BgM}9)(B) $B!{(B($B3X(B)$BBg2<(B $B=U:Z(B $B!&(B ($B3X(B)$B $B!&(B ($B@5(B)$BED8}(B $B $B!&(B ($B@5(B)$BA%B$(B $B=S9'(B | hydrothermal polycarbonate product depolymerization
| 8-d | 164 |
16:20$B!A(B 16:40 | N123 | $B@wNAGS?e$N?eG.;@2=J,2r(B
($B@EBg1!9)(B) $B!{(B($B3X(B)$BD%(B $B8w0N(B $B!&(B ($B3X(B)$BD;0f(B $B><8c(B $B!&(B ($B@5(B)$B2,Eg(B $B$$$E$_(B $B!&(B ($B@5(B)$B:48E(B $BLT(B | Subcritical water Dying wastewater decomposition
| 8-f | 556 |
N$B2q>l(B $BBh(B2$BF|(B |
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $BFbED(B $BGn5W(B) |
9:00$B!A(B 9:20 | N201 | $BD6NW3&?eG.9g@.K!$K$h$k%P%j%&%`%8%k%3%M!<%H%J%NN3;R$N9g@.(B
($BElBg1!?7NN0h(B) $B!{(B($B3X(B)$B2#(B $BE/(B $B!&(B ($B@5(B)$BBgEg(B $B5A?M(B | Supercritical water Hydrothermal synthesis Barium zirconate
| 8-e | 51 |
9:20$B!A(B 9:40 | N202 | $BD6NW3&%(%?%N!<%kMOG^$rMQ$$$?F
($B:e;TBg9)(B) $B!{(B($B3X(B)$BH,LZ(B $BNIB@(B $B!&(B ($B:e;TBg1!9)(B) ($B@5(B)$BJFC+(B $B5*;L(B | supercritical ethanol nanoparticle copper
| 8-e | 127 |
9:40$B!A(B 10:00 | N203 | $BD6NW3&N.BN$rMQ$$$?9bIJ
($BElKLBgB?858&(B) $B!{(B($B@5(B)$Bcx5o(B $B9bL@(B $B!&(B $BEDB<(B $BD>5.(B $B!&(B ($B@5(B)$BK\4V(B $B3J(B | Supercritical fluid Graphene Mass production
| 8-e | 98 |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $BBlV:(B $BHK |
10:00$B!A(B 10:20 | N204 | $BD6NW3&IOMOG^$K$h$k%j%3%T%s!?&B(B-$B%7%/%m%G%-%9%H%j%sJ#9gBN$N%J%NN3;R2=(B
($BL>Bg1!9)(B) $B!{(B($B3X(B)$B:,O)LC(B $BMU7n(B $B!&(B ($B@5(B)Machmudah Siti $B!&(B ($B@5(B)Wahyudiono $B!&(B ($B%=%&%k9qN)Bg(B) Youn Yong-Suk $B!&(B Lee Youn-Woo $B!&(B (SCF$B%F%/%N%j%s%/(B) ($B@5(B)$BJ!N$(B $BN40l(B $B!&(B ($B%+%4%a(B) ($B@5(B)$BEl1:(B $BBvKa(B $B!&(B ($BL>Bg1!9)(B) ($B@5(B)$B?@ED(B $B1Q51(B $B!&(B ($B@5(B)$B8eF#(B $B85?.(B | supercritical antisolvent carotenoid cyclodextrin
| 8-e | 508 |
10:20$B!A(B 10:40 | N205 | $B%^%$%/%m6u4VFb$ND6NW3&IOMOG^>=@O$K$h$k%F%*%U%#%j%sN3;RAO@=$KBP$9$kMO1UG;EY$N1F6A(B
($B?.=#Bg9)(B) $B!{(B($B3X(B)$BW"ED(B $B>"(B $B!&(B ($B?.=#Bg1!9)(B) ($B3X(B)$BCf_7(B $BNIB@(B $B!&(B ($B?.=#Bg9)(B) ($B@5(B)$BFbED(B $BGn5W(B | Supercritical antisolvent crystallization Micro-space Theophylline microparticles
| 8-e | 716 |
10:40$B!A(B 11:00 | N206 | $BD6NW3&MOBN5^B.KDD%K!$rMxMQ$7$?%+%U%'%$%sHyN3;RAO@=$K$*$1$kN3;R2s<}It>r7o$N1F6A(B
($B?.=#Bg9)(B) $B!{(B($B3X(B)$B:4Ln(B $B63J?(B $B!&(B ($B?.=#Bg1!9)(B) ($B3X(B)$B=PK\(B $B8xJ?(B $B!&(B ($B?.=#Bg1!M}9)(B) ($B3X(B)$B6aF#(B $BBg2p(B $B!&(B ($BEl9)Bg1!M}9)(B) ($B3X(B)$B:dIt(B $B=_0l(B $B!&(B ($B@5(B)$B2<;3(B $BM52p(B $B!&(B ($BBQ05>K;R9)6H(B) $BJR2,(B $BJb(B $B!&(B $B9qJ,(B $BN4(B $B!&(B $B0KF#(B $BbC5A(B $B!&(B $B?yK\(B $B@kM5(B $B!&(B ($B?.=#Bg9)(B) ($B@5(B)$BFbED(B $BGn5W(B | Rapid expansion of supercritical solutions Technique Caffeine microparticles Experimental conditions effects of particle collection section
| 8-e | 728 |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B8eF#(B $B85?.(B) |
11:00$B!A(B 11:20 | N207 | Preparation of superhydrophobic poly methyl methacrylate surface by rapid expansion of supercritical carbon dioxide-paraffin wax solution spray coatings
(KMITL) $B!{(B($B3$(B)Muanchan Paritat $B!&(B ($B3$(B)Veerachayapron Apisara $B!&(B ($B3$(B)Sanburan Suchawadee $B!&(B ($B@5(B)Areerat Surat | Supercritical Carbon Dioxide Superhydrophoic Spray Coatings
| 8-e | 205 |
11:20$B!A(B 11:40 | N208 | $BD6NW3&Fs;@2=C:AG$rMxMQ$7$?%]%j%$%_%I$NHy:Y2C9)$K4X$9$k4pACE*8!F$(B
($B9-Bg1!9)(B) $B!{(B($B3X(B)$BD9C+@n(B $BM%H~(B $B!&(B ($B3X(B)$BJ!0f(B $BD>Li(B $B!&(B ($B@5(B)$B=ULZ(B $B>-;J(B $B!&(B ($B@5(B)$BLZ86(B $B?-0l(B $B!&(B ($B@5(B)$BBlV:(B $BHK | supercritical carbon dioxide polyimide microfabrication
| 8-e | 428 |
11:40$B!A(B 12:00 | N209 | $B9b05(BCO2$B$K$h$kAjJ,N%$rMxMQ$7$?%]%j%$%_%I(B-$B%7%j%+J#9gB?9&
($B%f%K%A%+(B) $B!{(B($B@5(B)$BJ!NS(B $BL4?M(B $B!&(B ($B;:Am8&%J%N%F%/(B) ($B@5(B)$B0MED(B $BCR(B | high pressure carbone dioxide phase separation sol-gel process
| 8-e | 60 |
N$B2q>l(B $BBh(B3$BF|(B |
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $BI4@%(B $B7r(B) |
9:00$B!A(B 9:20 | N301 | $BD6NW3&N.BN=hM}$K$h$k(BPET$B%*%j%4%^!<$N9=B$JQ2=(B
($B7'Bg1!<+(B) $B!{(B($B@5(B)$B:4!9LZ(B $BK~(B $B!&(B ($BElMNKB(B) ($B@5(B)$B0p3@(B $B=a(B $B!&(B ($B7'Bg1!<+(B) ($B3X(B)$B@n@%(B $BJ8M:(B $B!&(B ($BElMNKB(B) $BgU;3(B $B$^$9$_(B $B!&(B ($B7'Bg1!<+(B) ($B@5(B)$B%"%k%^%s%I(B $B%-%?%$%s(B $B!&(B ($BElMNKB(B) $B0KF#(B $B>!Li(B | PET oligomer supercritical fluid
| 8-e | 637 |
9:20$B!A(B 9:40 | N302 | $BD6NW3&4^?;K!$rMQ$$$?D>@\%a%?%N!<%kG3NAEECS$N$?$a$N%Q%i%8%&%`(B+Nafion$BJ#9gKl$N:n@=$*$h$SI>2A(B
($B6eBg9)(B) $B!{(B($B3X(B)$BCS85(B $B=S(B $B!&(B ($B@5(B)$B4d0f(B $BK'IW(B | supercritical carbon dioxide direct methanol fuel cell composite membrane
| 8-e | 121 |
9:40$B!A(B 10:00 | N303 | $B%(%l%/%H%m%9%T%K%s%0K!$rMQ$$$?9b05(BCO2$B>r7o2<$K$*$1$k%J%N!&%^%$%/%m%U%!%$%P!<7A>u$N@)8f(B
($BL>Bg9)(B) $B!{(B($B3X(B)$B2,K\(B $B9R0l(B $B!&(B ($BL>Bg1!9)(B) ($B@5(B)Wahyudiono $B!&(B ($B@5(B)Machmudah Siti $B!&(B ($B@5(B)$B?@ED(B $B1Q51(B $B!&(B ($B@5(B)$B8eF#(B $B85?.(B | electrospinnig supercritical
| 8-e | 672 |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $BBm(B $B7rB@O:(B) |
10:00$B!A(B 10:20 | N304 | $BD6NW3&Fs;@2=C:AGCf$G$N%Q%k%9%l!<%6!<%"%V%l!<%7%g%s$K$*$1$kH/8w6/EY$N4Q;!(B
($BL>Bg1!9)(B) $B!{(B($B@5(B)$B8eF#(B $B85?.(B $B!&(B ($B@5(B)Machmudah Siti $B!&(B ($B@5(B)Wahyudiono $B!&(B $B9bED(B $B>:<#(B $B!&(B ($BKLBg1!9)(B) $B:4!9LZ(B $B9@0l(B | Supercritical CO2 Laser ablation Intensity
| 8-e | 783 |
10:20$B!A(B 10:40 | N305 | Cu$B$*$h$S(BMn$BM-5!:xBN$NMO2rEYB,Dj$K4p$E$/%U%m!<<0(BSCFD$B$N86NA6!5k
($BElBg1!9)(B) $B!{(B($B@5(B)$BI4@%(B $B7r(B $B!&(B ($BElBg@88&(B) $B6aF#(B $B0&;R(B $B!&(B ($B%G%s%=!<(B) ($B@5(B)$B;3ED(B $B1QM:(B $B!&(B $BBg86(B $B=_;N(B $B!&(B $BKLB<(B $B9/9((B $B!&(B ($B?.=#Bg9)(B) ($B@5(B)$BFbED(B $BGn5W(B $B!&(B ($BElBg1!9)(B) ($B@5(B)$BAz3@(B $B9,9@(B $B!&(B ($B@5(B)$B?y;3(B $B@5OB(B | supercritical fluid deposition solubility
| 8-e | 511 |
10:40$B!A(B 11:00 | N306 | $B%[%C%H%&%)!<%k<0%U%m!<%A%c%M%k7?%j%"%/%?$rMQ$$$?(BSiO2-SCFD$B$NH?1~2r@O(B
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| 8-e | 597 |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $BJFC+(B $B5*;L(B) |
11:00$B!A(B 11:20 | N307 | Supercritical fluid deposition of crystallized TiO2 with assistance of alcohol {$B%"%k%3!<%kE:2C$K$h$kD6NW3&N.BN$rMQ$$$?7k>=@-(BTiO2$BKl7A@.(B}
(U. Tokyo) $B!{(B($B3X(B)Zhao Yu $B!&(B ($B3X(B)Jung Kyubong $B!&(B ($B@5(B)Momose Takeshi $B!&(B ($B@5(B)Shimogaki Yukihiro | Supercritical Fluid Deposition TiO2 Anatase
| 8-e | 477 |
11:20$B!A(B 11:40 | N308 | Kinetics study of TiO2 deposition in supercritical CO2 using Micro-/Macro-cavity method {$BD6NW3&N.BNCf$K$*$1$k(BTiO2$BGvKlBO@Q$N%_%/%m%^%/%m%-%c%S%F%#K!$rMQ$$$?H?1~2r@O(B}
(U. Tokyo) $B!{(B($B3X(B)Jung Kyubong $B!&(B ($B3X(B)Zhao Yu $B!&(B ($B@5(B)Momose Takeshi $B!&(B ($B@5(B)Shimogaki Yukihiro | Supercritical fluid deposition TiO$2$ Micro-/Macro-cavity
| 8-e | 483 |
11:40$B!A(B 12:00 | N309 | $BBg7?9b05O*8wAuCV$K$h$kBgLL@QB?9&7?%U%l%-%7%V%kDcM6EEN(Kl$N3+H/(B
($B5~Bg9)(B) $B!{(B($B@5(B)$BBm(B $B7rB@O:(B $B!&(B ($B3X(B)$B1s;3(B $B7<2p(B $B!&(B ($B@5(B)$BBgEh(B $B@5M5(B | carbon dioxide low-k porous film
| 8-e | 320 |