A$B2q>l(B | |||||
---|---|---|---|---|---|
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!c:`NAAO@=$H3&LL8=>]!d(B | |||||
(9:20$B!A(B10:00)$B!!(B($B;J2q(B $BEOJU(B $BN49T(B) | |||||
A102 | [$BE8K>9V1i(B]$B7k>=2=8=>]$K$*$1$k3&LL$NLr3d$H5!G=(B | interfacial structure nucleation combined crystal | S-33 | 993 | |
(10:00$B!A(B10:40)$B!!(B($B;J2q(B $BH( | |||||
A104 | [$BE8K>9V1i(B]$B5!G=H/8=$K$`$1$?9bJ,;R%3%m%$%I$*$h$S$=$NJ,;67O$N9=C[(B | Microsphere microcapsule polymer colloid | S-33 | 994 | |
(10:40$B!A(B11:20)$B!!(B($B;J2q(B $B;3B<(B $BJ}?M(B) | |||||
A106 | [$BE8K>9V1i(B]$B2=3X9)3X | self-organization self-assembly chemical engineering | S-33 | 995 | |
(11:20$B!A(B12:00)$B!!(B($B;J2q(B $BGw86(B $B=$<#(B) | |||||
A108 | [$BE8K>9V1i(B]$B:`NA$NB?9&9=B$$H3K@8@.!&@.D9(B-$B9bJ,;R:`NA2C9)$NJ,Ln$+$i!<(B | Nucleation polous structure polymer processing | S-33 | 996 | |
(13:00$B!A(B13:40)$B!!(B($B;J2q(B $B>1Ln(B $B8|(B) | |||||
A113 | [$BE8K>9V1i(B]$BEII[5;=Q$NNr;K$HE8K>(B | Coating Research Association Fundamental coating phenomena Coating Technology & Material developments | S-33 | 997 | |
(13:40$B!A(B14:40)$B!!(B($B:BD9(B $B?@C+(B $B=(Gn(B) | |||||
A115 | YSZ$BI=LL$K$*$1$k?eAGH?1~%5%$%H$N8!F$(B | YSZ MDsimulation | S-33 | 122 | |
A116 | $B%W%m%T%l%s$K$h$k(BNO$B$N4T85H?1~$G$N(BPt$B7ABV@)8f8z2L(B | Pt nanoparticles structure sensitive reaction lean de-NOx | S-33 | 300 | |
A117 | $B7k>=@-M-5!J*=%,%i%9@-G^BNCf$X$N0BDjIuF~>r7o(B | stable dissolution in glass retardayion of crystallization temperature triggered cure | S-33 | 568 | |
(14:40$B!A(B15:40)$B!!(B($B:BD9(B $BGr@n(B $BA19,(B) | |||||
A118 | $B2~ | fluidized bed fine limestone powder calcination | S-33 | 977 | |
A119 | $B;@2=%A%?%s%J%NN3;R$NL56K@-MOG^Cf$X$NJ,;6(B | titanium dioxide Nonpolar solvent nanoparticle dispersion | S-33 | 264 | |
A120 | $B%7%j%+%J%NN3;R$NI=LL=$>~FC@-$HI=LL4VAj8_:nMQ$K5Z$\$9N3;R7B$N1F6A(B | silica colloid probe particle diameter | S-33 | 381 | |
(15:40$B!A(B16:40)$B!!(B($B:BD9(B $B1v0f(B $B>O5W(B) | |||||
A121 | TiO2$B%J%NN3;R$NI=LL9=B$@_7W$HJ*M}E*J,;6K!$NAH$_9g$o$;$K$h$k | Dispersion control Silane coupling agent PMMA | S-33 | 154 | |
A122 | $B%*%k%,%N%>%k$rMQ$$$?F)L@(BPMMA$B%J%N%O%$%V%j%C%I$NAO@=(B:$B%]%j%^! | organo sol nano particle PMMA nanohybrid | S-33 | 246 | |
A123 | $B?eMO@-9bJ,;RE:2C?eAj@O=P=E9g$K$h$kC1J,;6@-%]%j%^! | monodisperse polymer particle polymeric stabilizer dispersion stability | S-33 | 368 | |
(16:40$B!A(B18:00)$B!!(B($B:BD9(B $B:#Ln(B $B44CK(B) | |||||
A124 | $B%;%s%5! | Hydrogel Phase-transition Model | S-33 | 490 | |
A125 | $BHsBP>N4SDL7?%^%$%/%m%A%c%M%k$rMQ$$$?Hy>.1UE):n@=%W%m%;%9$N(BCFD$B2r@O(B | Asymmetric straight-through microchannel Droplet generation CFD | S-33 | 212 | |
A126 | $B6bB0%"%U%#%K%F%#8GDj2=%j%]%=!<%`%/%m%^%H%0%i%U%#!<$rMQ$$$k%9%H%l%91~Ez7?J,N%%W%m%;%9(B | membrane stress biotechnology metal affinity immobilized liposome chromatography bioseparation | S-33 | 911 | |
A127 | $BBg5$05HsJ?9U%W%i%:%^$K$h$kGQ2HEE$+$i$N%l%"%a%?%k$N2s<}(B | atmospheric plasma liquid crystal panel rare metal | S-33 | 797 | |
B$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!c4D6-!&>l$N%W%m%;%C%7%s%0@)8f$K$h$k9bJ,;R:`NA$N5!G=AO=P!d(B | |||||
(13:00$B!A(B14:00)$B!!(B($B:BD9(B $BBgEg(B $B@5M5(B) | |||||
B113 | PLA-NIPAAm$B%8%V%m%C%/%3%]%j%^!<$r9|3J$H$9$k4D6-J,2r%_%/%m%9%U%'%"$N3+H/(B | temperature response poly(N-isopropylacrylamide) microsphere | S-31 | 51 | |
B114 | $BJ,;R(BImprint$BK!$rMxMQ$9$kEE>l%7%s%/%m%_%/%m%9%U%'%"$N3+H/(B | molecular imprinting liquid crystal microsphere | S-31 | 245 | |
B115 | Polymerization of L-Lactic Acid through Direct Polycondensation | Polylactic acid Polymerization Direct polycondensation | S-31 | 671 | |
(14:00$B!A(B15:00)$B!!(B($B:BD9(B $BGw86(B $B=$<#(B) | |||||
B116 | $B@8J,2r@-9bJ,;R6E=8:^$NAO@=(B | Poly(aspartic acid) Flocculation Biodegradable polymer | S-31 | 650 | |
B117 | $B%"%k%3!<%k$N>x5$05@)8f$K$h$k9bJ,;RHyN3;RH/K"BN$NAO@=(B | nanocapsule PMMA particle | S-31 | 547 | |
B118 | $B:`NA$K<+8J=$I|5!G=$rIUM?2DG=$J%$%s%F%j%8%'%s%H%^%$%/%m%+%W%;%k$N3+H/(B | microcapsules self-healing | S-31 | 250 | |
(15:00$B!A(B16:00)$B!!(B($B:BD9(B $B5H_7(B $B=(OB(B) | |||||
B119 | W$B!?(BO$B%(%^%k%7%g%s$NHy>.J,;6E)$r=E9gH?1~>l$H$7$?%]%j%T%m!<%kHyN3;R$N9g@.(B | polypyrrole emulsion particle | S-31 | 843 | |
B120 | $BFsAjJ,N%7O3&LLH?1~$K$h$k%j%0%N%;%k%m!<%9J,;RJ#9g7O$N@:L)5!G=@)8f(B | lignin surface reaction phase-separation system | S-31 | 816 | |
B121 | $B%U%'%K%k%[%&;@4p$rM-$9$k4629@-%]%j%^!<$NE|$*$h$S%]%j%S%K%k%"%k%3!<%k$H$NAj8_:nMQ$K$h$kFC@-JQ2=(B | thermo sensitive polymer gel formation molecular recognition | S-31 | 695 | |
(16:00$B!A(B17:00)$B!!(B($B:BD9(B $BBm7r(B $BB@O:(B) | |||||
B122 | $B%W%i%:%^=E9gK!$K$h$kJ#9g2=J,;R%$%s%W%j%s%H4629@-%2%k$N3+H/$H=E6bB05[CeFC@-(B | plasma polymerization N-isopropylacrylamide molecular imprinted gel | S-31 | 458 | |
B123 | $B%?%s%K%s%2%k$K$h$k6d%$%*%s$N5[Ce!&4T855!9=(B | tannin silver adsorption | S-31 | 220 | |
B124 | $B%Q%i%8%&%`(B(II)$B!$Gr6b(B(IV)$B$N%?%s%K%s%2%k(B/$B1UCj=P$K$*$1$k(BSCN-$B!$(BBr-$B$N8z2L(B | Tannin gel Palladium(II) Extraction | S-31 | 432 | |
(17:00$B!A(B18:00)$B!!(B($B:BD9(B $B@6ED(B $B2BH~(B) | |||||
B125 | $B%+%W%;%k7?%^%$%/%m%j%"%/%?!<$NAO@=(B | enzyme immobilization calcium alginate capsules carboxymethyl cellulose | S-31 | 429 | |
B126 | [$BE8K>9V1i(B] $B2=3XH?1~>l$N@)8f$K$h$k9bJ,;R%2%k$N?7$7$$5!G=AO=P(B | Gel | S-31 | 506 | |
C$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!c5!G=@-7k>=$N3+H/$H>=@O5;=Q!d(B | |||||
(13:00$B!A(B14:00)$B!!(B($B:BD9(B $BHx>e(B $B70(B) | |||||
C113 | $B9bJ,;REE2r | nm size metal reduction crystallization mono dispersion | S-35 | 322 | |
C114 | $B9bJ,;REE2r | reactive crystallization monodispersed particle polyelectrolyte | S-35 | 385 | |
C115 | $BD62;GH$rMxMQ$7$?HyN3;R7k>=@8@.$NA`:n>r7o$N8!F$(B | ultrasonic wave nucleation crystallization | S-35 | 67 | |
(14:00$B!A(B15:00)$B!!(B($B:BD9(B $BJ?Bt(B $B@t(B) | |||||
C116 | $BH?1~>=@O$K$h$k%j%s;@%+%k%7%&%`N3;R$N@8@.$H%[%(! | cheese whey calcium phosphate EDTA | S-35 | 123 | |
C117 | [$BE8K>9V1i(B] $BH?1~>=@O8&5f$N8=>u$H:#8e$NE83+(B | S-35 | 992 | ||
(15:00$B!A(B16:00)$B!!(B($B:BD9(B $BBgED86(B $B7rB@O:(B) | |||||
C119 | $B0[$J$k(BCa$B1vMO1U$X$N(BCO2/NH3$BHy:Y5$K"$N?a$-9~$_$K$h$kC:;@%+%k%7%&%`$NH?1~>=@O(B | micro bubble reactive crystallization polymorphs | S-35 | 626 | |
C120 | $BHy:Y5$K"$rMQ$$$?H?1~>=@OK!$K$h$kC:;@1vHyN3;R$N@=B$(B | micro bubble crystallization fine particles | S-35 | 630 | |
C121 | $BHy:YM6EE:`NA(BMgTiO3$B$N@8@.$H$=$NI>2A(B | dielectric material nano-size sol-gel method | S-35 | 798 | |
(16:00$B!A(B17:00)$B!!(B($B:BD9(B $B8^==Mr(B $B9,0l(B) | |||||
C122 | $B9bG;EY7O$K$*$1$k(BZnO$BN3;R$N9g@.(B | ZnO ZnCl$2$$B!&(B4Zn(OH)$2$ particle | S-35 | 822 | |
C123 | $BM;1U>=@O$K$*$1$k7k>==cEY$K4X$9$k8&5f(B | crystallization solute distribution purity | S-35 | 190 | |
C124 | CDC:$B2#7?B?CJNd5Q>=@OAuCV(B | Crystal Crystallization CFD | S-15 | 529 | |
D$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!cG.9)3X%7%s%]%8%&%`!d(B | |||||
(9:00$B!A(B10:40)$B!!(B($B:BD9(B $BEDG7>e(B $B7r0lO:!&6bED(B $B>;G7(B) | |||||
D101 | $BFs=E3H;6BPN.$N5 | double-diffusive convection interface Convection velocity | S-5 | 648 | |
D102 | $BFsAX7OFs=E3H;6BPN.$N?tCM2r@O!=Cf4VAX7A@.2aDx$K5Z$\$9IbNOHf$N1F6A!=(B | double diffusion mumerical analysis middle layer | S-5 | 941 | |
D103 | Cz$BK!IT=cJ*G;EY$K5Z$\$9<'>l0u2CJ}<0$N1F6A(B | Cz method rotational magnetic field concentration | S-5 | 392 | |
D104 | FZ$BFb0\F08=>]$K5Z$\$929EY:9!&G;EY:9%^%i%s%4%KBPN.6&B8$N1F6A$K4X$9$k?tCM2r@O(B | Marangoni convection Floationg zone method Numerical simulation | S-5 | 881 | |
D105 | $B%Z%k%A%'AG;R$rMQ$$$?MOM; | peltier device melten resin cooling speed | S-5 | 395 | |
(10:40$B!A(B12:00)$B!!(B($B:BD9(B $BHDC+(B $B5A5*!&CfA>(B $B9@0l(B) | |||||
D106 | $BL55!J*?eMO1U$N7k>=2=G.$rMxMQ$7$?>o297?@xG.C_G.%7%9%F%`$N3+H/(B | latent heat storage efficient of thermal storage heat of crystallization | S-5 | 656 | |
D107 | $B4xH/@-Fs | Absorption Refrigerator Triple effects Volatile Coolant | S-5 | 989 | |
D108 | $B5[<}NdE`5!$K$*$1$k?bD>J?HD<0AuCV$*$h$S?eJ?4I<0AuCV$N:F@84o!&5[<}4o$H$7$F$N@-G=Hf3S(B | Absorption Refrigerator Vertical Flat Plate Horizontal Tube | S-5 | 676 | |
D109 | AB5$B7??eAG5[B"9g6b$NAH@.$,?eJ,$K$h$kHoFG$K5Z$\$91F6A$N8!F$(B | hydrogen storage alloy H$2$O poisoning La content | S-5 | 283 | |
(13:20$B!A(B14:00)$B!!(B($B;J2q(B $B8eF#(B $BK.>4(B) | |||||
D114 | [$B>7BT9V1i(B]$B9b@-G=%G%9%1!<%j%s%0%N%:%k(B | Thermal Engineering | S-5 | 423 | |
(14:00$B!A(B14:40)$B!!(B($B:BD9(B $B5HED(B $B@5F;(B) | |||||
D116 | $B>x5$D>@\@\?(2CG.$N%7%_%e%l!<%7%g%s(B | steam injection Euler's multiphase flow model sterilizer | S-5 | 12 | |
D117 | $B%$%s%/%8%'%C%H@=Kl$K$*$1$k(B2$B@.J,MOG^$N8z2L(B | droplet evaporation binary solvent | S-5 | 277 | |
(14:40$B!A(B16:20)$B!!(B($B:BD9(B $B8eF#(B $BK.>4!&2,Ln(B $BBYB'(B) | |||||
D118 | $B%R!<%H%Q%$%W2CG.$rMQ$$$?%S%K!<%k%O%&%9$N:GE,@_7W(B | Green house Heat Pipe Energy Conservation | S-5 | 852 | |
D119 | DME$B%j%P!<%K%s%0$NC&>K@-G=$K5Z$\$9?e>x5$$N1F6A(B | NO Reduction Dimethyl Ether steam addition | S-5 | 596 | |
D120 | CVD$BK!$K$h$k%U%'%m%;%s$rMQ$$$?(BCNT$B@8@.$K29EY$HO'FbBZ:_;~4V$,5Z$\$91F6A$N8!F$(B | CVD Carbon nanotubes Ferrocene | S-5 | 65 | |
D121 | $BBSEE$7$?%+!<%\%s%V%i%C%/N3;R$N6E=8$K$h$j@8@.$9$k6E=8BN7A>u$K4X$9$k?tCM2r@OE*8!F$(B | carbon black Cluster-Cluster Aggregation electrostatic repulsion | S-5 | 657 | |
D122 | $B%+!<%\%s%J%NJ* | Carbon nanomaterial Thermal conductivity Silicone grease | S-5 | 502 | |
(16:20$B!A(B18:00)$B!!(B($B:BD9(B $BLnED(B $B1QI'!&?<0f(B $B=a(B) | |||||
D123 | $B%9%]%C%HK`;$YxYB@\9g$K$*$1$kG.0\F0%W%m%;%9$NM}O@E*8&5f(B | Spot friction stir welding Unsteady-state heat conduction Numerical analysis | S-5 | 541 | |
D124 | $B?eAG5[B"H?1~$K5Z$\$9EAG.B%?J$N8z2L(B | metal hydride packed-bed heat conduction | S-5 | 273 | |
D125 | $BG4CF@-N.BN$N%P%i%98z2L$rMxMQ$7$?%-%c%S%F%#FbAXN.EAG.B%?J(B | Visco-elastic fluid Barus effect Heat transfer augmentation | S-5 | 158 | |
D126 | $B5[G.$HH/G.H?1~$,JILL$r2p$7$FF1;~$K?J9T$9$kEAG.B%?J7?%^%$%/%m2=3XH?1~>l$N9=C[(B | Conductional heat transfer Microreactor Hydrogen production | S-5 | 360 | |
D127 | $B29EYJ,I[@)8f$r$a$6$7$?G3NAEECS%;%k%9%?%C%/FbG.0\F08=>]$K4X$9$k?tCM2r@O(B | Cell stack Numerical simulation Cell orientation | S-5 | 317 | |
E$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!cN.BN%W%m%;%9%7%s%]%8%&%`!d(B | |||||
(10:20$B!A(B11:00)$B!!(B($B:BD9(B $B<<;3(B $B>!I'(B) | |||||
E105 | $B5$BN05NOJQF0$rMxMQ$7$?C10lHy:Y5$K"H/@8K!(B | micro-bubble bubble generator acoustic | S-2 | 62 | |
E106 | $BG4CF@-N.BN$NC&K"$K$*$1$k5$K"7A>u$N9M;!(B | Viscoelastic removal bubble | S-2 | 580 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $BEZ20(B $B3hH~(B) | |||||
E107 | $BC10l5$K"$+$i$N%,%95[<}2aDx$K$*$1$kJ* | Gas absorption Two-color LIF PIV | S-2 | 601 | |
E108 | $B@E;_1UBNCf$r>e>:$9$k(B2$B5$K"$N9gBN$*$h$SH?H/(B | bubble bouncing coalescence | S-2 | 61 | |
E109 | $BG4@-N.BNCf$r>e>:$9$k5$K"!?1UE)1?F0$X$NFsAjN.BNG4EY$N1F6A(B | Bubble/drop rise motion Viscosity ratio Numerical analysis | S-2 | 667 | |
(13:00$B!A(B13:40)$B!!(B($B;J2q(B $BC]ED(B $B9((B) | |||||
E113 | [$BE8K>9V1i(B]$B%^%$%/%m%P%V%k8&5f$N8=>u$HE8K>(B | microbubble water treatment bubble column | S-2 | 118 | |
(13:40$B!A(B14:40)$B!!(B($B:BD9(B $Bc7F#(B $BN4G7(B) | |||||
E115 | $B%9%i%j! | Slurry Bubble Liquid mixing | S-2 | 270 | |
E116 | $B?eJ?6k7A%Q%$%W%i%$%s$rDL2a$9$k5$1U(B2$BAjN.$N5sF0(B | bubble laser-scanning two-phase flow | S-2 | 25 | |
E117 | $B6k7A4IFb$rN.$l$k5$1U(B2$BAj5$K"N.$NHsDj>oB.EYJQF02r@O(B | Numerical simulation Bubble flow Velocity fluctuation | S-2 | 152 | |
(14:40$B!A(B15:40)$B!!(B($B:BD9(B $BB@ED(B $B8w9@(B) | |||||
E118 | $B5$K"<~JUN.$l$H05NOJ,I[$N?tCM2r@O(B | bubble wake numerical simulation pressure distribution | S-2 | 488 | |
E119 | $B6k7A5$K"Ec$K$*$1$kBg5,LON.F09=B$(B | Bubble Column Two-phase Flow LDA | S-2 | 801 | |
E120 | Plunging jet$B$K$h$jM65/$5$l$k5$1UFsAjN.F0$N9=B$(B | multi-phase flow F-TOP(Four-Tip Optical-fiber Probe) plunging jet | S-2 | 518 | |
(15:40$B!A(B16:40)$B!!(B($B:BD9(B $B;{:d(B $B9(0l(B) | |||||
E121 | $B5$K"Ec$GG]M\$7$?(BAgaricus blazei$B6];eBN$NBe | Bubble Column Agaricus blazei Submerged culture | S-2 | 416 | |
E122 | $B8GDj2==$>~%;%k%i!<%<$K$h$kITMO@-%;%k%m!<%9$N%(%"%j%U%HE|2=H?1~A`:n(B | Immobilized cellulase Cellulose saccharification Airlift bioreactor | S-2 | 100 | |
E123 | U$B%A%e!<%VH?1~4o$rMQ$$$?0{MQ?e%*%>%s=hM}$N%7%_%e%l!<%7%g%s(B | U-tube Bubble Column Ozonation Drinking water | S-2 | 397 | |
F$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!c0\F08=>]%7%s%]%8%&%`!d(B | |||||
(10:00$B!A(B11:20)$B!!(B($B:BD9(B $BK\4V(B $B=S;J(B) | |||||
F104 | Smoothed Profile$BK!$K$h$k2YEE%3%m%$%IN3;R$NEE5$1KF0%7%_%e%l!<%7%g%s(B | colloid simulation electrophoresis | S-3 | 139 | |
F105 | $BB?N3;R4V6E=8$r9MN8$7$?O"B3F}2==E9g$N3NN(%b%G%k(B | Continuous Emulsion Polymerization Stochastic Model Dynamic Behavior | S-3 | 236 | |
F106 | $B%/%m%9%U%m!<8B30_I2a$K$*$1$kBO@QAX$N%l%*%m%8!<$r9MN8$7$?F)2a2aDx$N%b%G%k2=(B | cross flow ultrafiltration rheology | S-3 | 225 | |
F107 | $B%^%$%/%mN.O)Fb$K$*$1$kN.F08=>]$N?tCM2r@O(B | micro-channel two-phase flow numerical calculation | S-3 | 389 | |
(11:20$B!A(B12:00)$B!!(B($B;J2q(B $BBgB<(B $BD>?M(B) | |||||
F108 | [$BE8K>9V1i(B]$B5$K"$r4^$`N.$l$N%^%k%A%9%1!<%k%7%_%e%l!<%7%g%s(B | Multi-Scale Simulation Bubbly Flow Two-Phase Flow | S-3 | 359 | |
(13:00$B!A(B13:40)$B!!(B($B;J2q(B $B>>7(!!MN2p(B) | |||||
F113 | [$BE8K>9V1i(B]$B3J;R%\%k%D%^%sK!$K$h$kJ#;($J0\F08=>]$N%7%_%e%l!<%7%g%s(B | Lattice Boltzmann | S-3 | 435 | |
(13:40$B!A(B15:00)$B!!(B($B:BD9(B $B5H@n(B $B;KO:(B) | |||||
F115 | $BI=LL@->u$r9MN8$7$?8GBNI=LL>e$N1UE)5sF0$N?tCM2r@O(B | PEFC droplet Lattice Boltzman | S-3 | 374 | |
F116 | $B4pHD>e$G>xH/$9$k9bJ,;RMO1UE)Fb$N<+A3BPN.$N2D;k2=(B | droplet visualization internal flow | S-3 | 294 | |
F117 | $BEE<'IbM7%7%j%3%s1UE)FbBPN.$K5Z$\$9@E<'>l0u2C8z2L(B | Static magnetic field Electromagnetic levitation Molten silicon | S-3 | 233 | |
F118 | $BI=LLD%NON.$l$K$h$kGvKlI=LL1zFL$N7A@.(B | marangoni flow drying coating | S-3 | 141 | |
(15:00$B!A(B16:20)$B!!(B($B:BD9(B $B;3B<(B $BJ}?M(B) | |||||
F119 | $B%8%'%C%H$N%T%s%A%*%U$H%5%F%i%$%H1UE)$N@8@.$K4X$9$k?tCM2r@O(B | Satellite Drop Pinch-Off Front-Tracking | S-3 | 74 | |
F120 | $BB?AX%U%#%k%`MOM;2!=P%W%m%;%9$N2r@O5;=Q$N3+H/(B | multi-layer film extrusion polymer melt flow | S-3 | 266 | |
F121 | $B9BIU$-%P%l%k$rM-$9$kFs<4%9%/%j%e2!=P5!Fb$NMOM;:.N}It$N2r@O(B-$BJ,G[:.9g$KBP$9$k9B7A>u$N1F6A(B- | Twin Screw Extruder Grooved barrel Groove geometry | S-3 | 377 | |
F122 | $BEAG.JI3&LL$N29EYB,DjK!$K$D$$$F(B | Mixing Heat transmission Temperature measurement | S-3 | 546 | |
G$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!cN3;R!&N.BN7O%U%m%s%F%#%"J,N%5;=Q$NE83+!d(B | |||||
(9:40$B!A(B10:40)$B!!(B($B:BD9(B $BEDCf(B $B9'L@(B) | |||||
G103 | $BE`7kM;2rK!$K$h$k(BO/W$B%(%^%k%7%g%s$NL}E)6E=8$H2rF}2=FC@-(B | freeze-thaw O/W emulsion aggregation | S-8 | 854 | |
G104 | $BD62;GH>H | ultrasonic irradiation freeze concentration diffusion coefficient | S-8 | 786 | |
G105 | $B1s?4>=@OK!$K$h$k7k>=HyN3;R$N@8@.!&J,N%%W%m%;%9$N3+H/(B | crystallization centrifugation amino acid crystal | S-8 | 923 | |
(10:40$B!A(B11:20)$B!!(B($B:BD9(B $BGOEO(B $B2B=((B) | |||||
G106 | $B?;DR7?KlJ,N%3h@-1xE%K!$K$*$1$kKl_I2aFC@-$K5Z$\$93+;O(BMLSS$B!"(BSRT$B$N1F6A(B | Submerged Membrane Activated Sludge Process Membrane Filtration Characteristics Initial MLSS | S-8 | 706 | |
G107 | $BF};@H/9Z%W%m%;%9$K$*$1$kH?1~!&J,N%>r7o$NC5:w(B | separation fermentation lactic acid | S-8 | 846 | |
(11:20$B!A(B12:00)$B!!(B($B;J2q(B $B8~0f(B $B9/?M(B) | |||||
G108 | [$BE8K>9V1i(B]$BN3;R$NKlF)2a5!9=$N2rL@$HKl$rMQ$$$?N3;RJ,5i(B | membrane particle classification | S-8 | 165 | |
(13:00$B!A(B13:40)$B!!(B($B;J2q(B $BEDCf(B $B9'L@(B) | |||||
G113 | [$BE8K>9V1i(B] $BFq$m2a@-J* | centrifugation centrifugal separation disc-stack centrifuge | S-8 | 166 | |
(13:40$B!A(B14:40)$B!!(B($B:BD9(B $B@n:j(B $B7rFs(B) | |||||
G115 | Effect of addition of surfactant on porous PES membrane formation | Porous membrane Surfactant Membrane formation mechanism | S-8 | 607 | |
G116 | $BI=LL1zFL9=B$$K$h$j | filtration biodegradable plastics filter | S-8 | 296 | |
G117 | $B%1!<%/%l%99bG;=LO"B3$m2a%7%9%F%`$N3+H/(B | Dispersant Cake less filtration Fluidity | S-8 | 147 | |
(15:00$B!A(B16:00)$B!!(B($B:BD9(B $BCfAR(B $B1QM:(B) | |||||
G119 | $B79 | lamella settler tube settler settling tank | S-8 | 59 | |
G120 | $BL)JD5[0z<079 | settling velocity inclined settler | S-8 | 78 | |
G121 | $B%o!<%k%W!<%kA`:n$K$*$1$kAj4X<0$N3+H/(B | solid-liquid separation eddy flow whirlpool | S-8 | 403 | |
(16:00$B!A(B17:00)$B!!(B($B:BD9(B $B4dED(B $B@/;J(B) | |||||
G122 | $B3h@-C:HyN3;R$r=u:^AX$H$7$?MO2r@-%U%_%s;@MO1U$N@6@!_I2aFC@-(B | activated carbon humic acid deep bed filtration | S-8 | 404 | |
G123 | $BC]C:HyN3;R$r=u:^AX$H$7$?MO2r@-%U%_%s;@MO1U$N@6@!_I2aFC@-(B | bamboo charcoal humic acid deep bed filtration | S-8 | 628 | |
G124 | $B%W!<%k?e$*$h$SCS?e$NDj05_I2a$K$*$1$k_I2aB.EY$N2r@O(B | microfiltration pore blocking cake formation | S-8 | 832 | |
H$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
(9:20$B!A(B10:40)$B!!(B($B:BD9(B $BBgEg(B $BC#Li(B) | |||||
H102 | $B%(!<%F%k7?%"%k%-%k%H%j%a%A%m!<%k2=9gJ*$rG'<1AG;R$H$9$k%j%A%&%`A*Br@-EE6K$N3+H/(B | ion selective electrode broom type compound lithium | S-9 | 873 | |
H103 | $B%+%j%C%/%9(B[4]$B%"%l!<%s$r4pBN$H$7$?%[%9%[%s;@7OCj=P:^$N3+H/$H4uEZN`6bB0$NCj=PFC@-(B | extraction calix[4]arene rare earth metal | S-9 | 842 | |
H104 | $B%"%_%s7?%[%&%-J,;R$K$h$k(BMo,V,W$B$NCj=PJ,N%5sF0(B | extraction broom amine compound molybdenum | S-9 | 837 | |
H105 | $B>F5QHt3%$+$i$N=E6bB0$N2s<}(B | Fly ash citric acid heavy metal | S-9 | 829 | |
(10:40$B!A(B12:00)$B!!(B($B:BD9(B $BBgEO(B $B7<2p(B) | |||||
H106 | $BB?9& | tansition metal porous glass separation | S-9 | 327 | |
H107 | $B%-%H%5%s8GDj2=%7%j%+%2%k$K$h$k6bB0$N2s<}(B | chitosan silica gel adsorption | S-9 | 927 | |
H108 | $B%[%9%[%s;@%-%H%5%sM6F3BN$N9g@.$H$a$C$-GQ1U=hM}$X$N1~MQ(B | chitosan adsorption phosphonic acid | S-9 | 457 | |
H109 | $B%$%*%&86;R$rG[0L;R$H$7$?%-%H%5%sM6F3BN$N9g@.$H$=$N6bB05[CeFC@-(B | chitosan adsorption precious metal | S-9 | 459 | |
(13:00$B!A(B14:20)$B!!(B($B:BD9(B $B>>K\(B $BF;L@(B) | |||||
H113 | [$BE8K>9V1i(B]$B4D6-1x@wJ*u$H:`NA@_7W@oN,(B | environmental pollutant adsorbent computational chemistry | S-9 | 605 | |
H115 | $BI9>=%F%s%W%l!<%HK!$rMxMQ$7$?HyNL4D6-J* | sol-gel ice templating solid phase dynamic extraction | S-9 | 10 | |
H116 | $B8w?(G^3h@-$rM-$9$k%A%?%K%"HyN3;R$N9g@.$H4D6->t2=$X$N1~MQ(B | photocatalyst anatase-type titanium dioxide environmental purification | S-9 | 276 | |
(14:20$B!A(B15:40)$B!!(B($B:BD9(B $B@n4nED(B $B1Q9'(B) | |||||
H117 | $B%U%'%i%$%HHyN3;R$rMQ$$$?%RAG$N5[CeFC@-(B | adsorption ferrite arsenic | S-9 | 467 | |
H118 | $B&A(B-FeO(OH)$B7O5[Ce:^$N=E6bB0%$%*%s5[CeFC@-(B | goethite adsorption selenium | S-9 | 82 | |
H119 | $B%-%H%5%s7O5[Ce:^$rMQ$$$?GQ%P%C%F%j!<$+$i$NM-2A6bB0$NJ,N%!&2s<}!!(B-$B5[CeJ?9U(B- | Adsorption Heavy metals Chitosan | S-9 | 933 | |
H120 | Adsorption of Heavy Metal Ions from Squid Oil by Chelate Ion Exchanger | Metal ions Chelate Ion Exchanger Squid Oil | S-9 | 821 | |
(15:40$B!A(B16:40)$B!!(B($B:BD9(B $BCfB<(B $B=(H~(B) | |||||
H121 | $B%U%CAG%$%*%sG'<1It0L$r3&LL$K$b$D5[Ce:^$N9&7B@)8f(B | fluorine ion surface template polymerization pore size | S-9 | 855 | |
H122 | $B9ZAGH?1~$G@8@.$7$?%G%-%9%H%i%s$G=$>~$7$?B?9&@-Kl$N9&7BJQ2=$HJ,N%@-G=(B | dextransucrase dextran separation | S-9 | 820 | |
H123 | $B%P%/%F%j%"%;%k%m!<%9M6F3BN$K$h$k%+%A%*%s@-%?%s%Q%/ | bacterial cellulose adsorption protein | S-9 | 463 | |
I$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!c%0%j!<%s%F%/%N%m%8!<$H$7$F$NKlJ,N%!d(B | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $BEDCf(B $B0l9((B) | |||||
I101 | $B?"J*:OG]$N$?$a$N1UBNKl<0C:;@%,%9G;=L6u5$6!5kAuCV(B | liquid membrane carbon dioxide | S-10 | 527 | |
I102 | CO$BJQ@.?(G^H?1~4o$KE,MQ$9$k(BCO2$BA*BrF)2aKl$N3+H/(B | gas separation ionic liquid facilitated transport membrane | S-10 | 439 | |
I103 | $B8w?(G^Kl7?H?1~4o$K$*$1$k4xH/@-M-5!2=9gJ*$NJ,2rFC@-(B | Nano porous TiO$2$ membrane Photocatalytic membrane reactor VOC decomposition | S-10 | 483 | |
(10:00$B!A(B11:20)$B!!(B($B:BD9(B $B0KEl!!>O(B) | |||||
I104 | $BKl7?H?1~4o$K$h$k%W%m%Q%s$N2~ | inorganic membrane membrane reactor reforming | S-10 | 257 | |
I105 | $B%P%$%b!<%@%k?(G^Kl$rMQ$$$?%a%?%s2~ | bimodal catalytic membrane methane steam reforming hydrogen separation | S-10 | 476 | |
I106 | Multi-objective optimization of membrane reactor without sweep gas | multi-objective optimization membrane reactor hydrogen production | S-10 | 252 | |
I107 | $B%A%?%N%7%j%1!<%HKl$NF)2aJ*@-$H%a%s%V%l%s%j%"%/%?!<$X$N1~MQ(B | Zeolite membrane Titanosilicate Membrane reactor | S-10 | 206 | |
(11:20$B!A(B12:00)$B!!(B($B;J2q(B $BApJI(B $B9n8J(B) | |||||
I108 | $BDc4D6-Ii2Y%W%m%;%9$rL\;X$7$?%a%s%V%l%s%j%"%/%?!<$N3+H/(B | Green Technology Membrane reactor | S-10 | 58 | |
(13:20$B!A(B14:00)$B!!(B($B;J2q(B $B?\ED(B $BMN9,(B) | |||||
I114 | $B%J%NB?9&@-J,N%Kl$N3+H/$H1UAj7OJ,N%$X$N1~MQ(B | nanoporous membranes liquid phase separation | S-10 | 418 | |
(14:00$B!A(B15:00)$B!!(B($B:BD9(B $B5H2,(B $BJ~5W(B) | |||||
I116 | $B8e=hM}$,(BPHI$BKl$N(BPV$B@-G=$KM?$($k1F6A(B | zeolite membrane pervaporation post treatment | S-10 | 284 | |
I117 | $B%<%*%i%$%HKl$K$h$kD>@\%Q!<%Y!<%Q%l!<%7%g%s$N%W%m%;%96/2=$X$N1~MQ(B | zeolite membrane pervaporation process intensification | S-10 | 282 | |
I118 | $B%<%*%i%$%H$NMO2r!&EII[$K$h$k?eAGJ,N%Kl$N9g@.(B | zeolite H2 separation | S-10 | 452 | |
(15:00$B!A(B16:00)$B!!(B($B:BD9(B $BD9C+@n(B $BBY5W(B) | |||||
I119 | $B%U%k%U%j%k%"%k%3!<%k>x5$$rMQ$$$?%_%/%m9&C:AGKl$N9g@.$H?eAGJ,N%(B | carbon membrane micropore vapor phase synthesis | S-10 | 275 | |
I120 | $B%j%0%N%/%l%>!<%k$rA06nBN$H$9$kC:AGKl$K$h$k?;F)5$2=J,N%(B | Lignin Molecular sieve membrane Membrane separation | S-10 | 278 | |
I121 | $B%j%0%K%s$rA06nBN$H$9$kC:AGKl$N%^%$%/%mGH2CG.K!$K$h$k@=Kl$H$=$NF)2aJ*@-(B | Lignin Molecular sieve membrane Menbrane separation | S-10 | 365 | |
(16:00$B!A(B17:00)$B!!(B($B:BD9(B $BEDCf(B $B=SJe(B) | |||||
I122 | $B9b29?e>x5$BQ@-$rM-$9$k%3%P%k%H%I!<%W%7%j%+Kl$N3+H/$H5$BNF)2aFC@-(B | hydrogen separation silica membrane metal doping | S-10 | 208 | |
I123 | $BM-5!!&L55!J#9g%W%m%;%9$K$h$jD4@=$7$?%Q%i%8%&%`9g6bKl$NI>2A(B | Combined organic/inorganic process Pd alloy membrane Hydrogen separation | S-10 | 274 | |
I124 | $B?eAGA*BrF)2aKl$NEE5$2=3X%G%P%$%9$X$NE,MQ2DG=@-$N8!F$(B | Hydrogen separation Membrane Electrochemical device | S-10 | 448 | |
J$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!c?75!G=$rDI5a$9$k?)IJ9)3X$N?7E83+!d(B | |||||
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $B5\OF(B $BD9?M(B) | |||||
J104 | $B24iZ$N2CG.2aDx$K$*$1$k%F%/%9%A%c! | oyster texture viscoelasticity | S-25 | 194 | |
J105 | Factors Affecting the Particle Size of b-Carotene Nanodispersions Prepared by Solvent-Displacement Technique | beta-carotene nanodispersion solvent-displacement | S-25 | 239 | |
J106 | Formulation of O/W emulsions containing lipophilic compounds by microfluidic emulsification process | Microfluidic emulsification gamma-oryzanol beta-carotene | S-25 | 513 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B8EED(B $BIp(B) | |||||
J107 | $B%^%$%/%m%A%c%M%k$rMQ$$$?E>AjKlF}2=5!9=$N2rL@$H$=$N1~MQ(B | microchannel Membrane Phase Inversion Emulsification | S-25 | 860 | |
J108 | [$BE8K>9V1i(B] Controlled production of emulsions using membrane and microchannel technology | emulsions membrane microchannel | S-25 | 491 | |
(13:00$B!A(B14:00)$B!!(B($B:BD9(B $B0BC#(B $B=$Fs(B) | |||||
J113 | $B%A!<%:@=B$MQ%W%m%T%*%s;@6]$N9%5$G]M\$K$h$k(BBGS$B@8;:$H$=$NBe | Propionibacterium growth factor aerobic culture | S-25 | 309 | |
J114 | $B9m=AG]CO$rMQ$$$F@8;:$7$?F};@6]%P%/%F%j%*%7%s$K$h$k@6 | Hiochi bacteriocin Koji medium | S-25 | 313 | |
J115 | $B@:JF;D^V$N9bB.9ZAGE|2=$H$=$NH/9Z86NA$H$7$F$NM-8zMxMQ(B | rice bran fermentation lactic acid | S-25 | 315 | |
(14:00$B!A(B15:00)$B!!(B($B:BD9(B $BCfEh(B $B8wIR(B) | |||||
J116 | $B5!G=@-%?%s%Q%/ | ultrasonic disinfection titania lactoferrin | S-25 | 267 | |
J117 | [$BE8K>9V1i(B]$BB?9& | Nanobubble Bubble size control Polass membrane | S-25 | 111 | |
(15:00$B!A(B16:00)$B!!(B($B:BD9(B $BJFK\(B $BG/K.(B) | |||||
J119 | $B$o$,9q$N?)@83h9=B$$,Fs;@2=C:AGGS=PNL$K5Z$\$91F6A$K$D$$$F(B | carbondioxide emission self-sufficiency rate of food food consumption pattern | S-25 | 856 | |
J120 | $B%l!<%@!<%A%c!<%H$K$h$k?)IJ93;@2=@.J,$NAm9gI>2A(B | anitoxidant food radical | S-25 | 564 | |
J121 | $B8zN(E*$J?)IJ%/%m%^%HJ,N%%W%m%;%9$N@_7WJ}K!$N3+H/(B | chromatography food separations design calculation | S-25 | 974 | |
(16:00$B!A(B17:00)$B!!(B($B:BD9(B $BC+8}(B $B@5G7(B) | |||||
J122 | $B9ZJl$N4%Ag$K$*$1$k<:3h5!9=(B:$BDc4^?eN(NN0h$K$*$1$k<:3h$H0BDj2=(B | Drying Yeas Water activity | S-25 | 739 | |
J123 | CLSM$B$rMQ$$$?J.L84%AgJ4Kv$+$i$N%U%l!<%P!<=yJ|2r@O(B | CLSM Flavor Release | S-25 | 45 | |
J124 | $B%"%k%3!<%kC&?eAG9ZAG$NJ.L84%AgK!$K$h$k:n@=(B | ADH Spray drying Trehalose | S-25 | 70 | |
(17:00$B!A(B18:00)$B!!(B($B:BD9(B $B;{Eh(B $B@5L@(B) | |||||
J125 | $B3F | amorphous sugar glass transition temperature hydrogen bond | S-25 | 689 | |
J126 | $B0!NW3&?e$K$h$k%7%gE|$N2C?eJ,2r$K5Z$\$91v$N1F6A(B | subcritical water hydololysis of sucrose salt | S-25 | 586 | |
J127 | $BG.?e>r7o2<$K$*$1$k%]%j%,%i%/%D%m%s;@$N2C?eJ,2r(B | Hydrothermal Hydrolysis Polygalacturonic acid | S-25 | 553 | |
K$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!c%P%$%*%a%G%#%+%k%^%F%j%"%k$N:GA0@~!d(B | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $B2CF#(B $B7I0l(B) | |||||
K101 | ($B9V1iCf;_(B) | 100 | 351 | ||
K102 | $BEE>l$HD62;GH$rJ;MQ$7$?LtJ*HiIf5[<}B%?J(B | Iontophoresis Sonophoresis Synergetic effect | S-22 | 361 | |
K103 | $B4N44:YK&$N9bL)EYG]M\$H7A | hepatic stem cell high density culture culture substrate | S-22 | 705 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $BEl[j(B $B3Q<#(B) | |||||
K104 | $B%R%HBgD24b$N=i4|<#NE$KMxMQ$9$k934b:^FbJq(BSpan80$B%Y%7%/%k$N%^%&%9EjM?8z2L(B | Lectin DDS Colon cancer | S-22 | 833 | |
K105 | $B%R%HG> | Immuno vesicle Human brain tumor DDS | S-22 | 834 | |
K106 | $B%]%j%S%K%k%T%m%j%I%s$K$h$k%J%N%l%Y%k$N:`NAI=LL2~ | Atomic Force Microscopy Polyvinylpyrrolidone Biocompatibility | S-22 | 859 | |
(11:00$B!A(B11:40)$B!!(B($B;J2q(B $B6b?9(B $BIR9,(B) | |||||
K107 | [$BE8K>9V1i(B]$B?M9):YK&Kl9=B$BN$N%J%N%P%$%*%$%s%?!<%U%'%$%9(B | biomaterials hemocompatibility MPC polymer | S-22 | 94 | |
(11:40$B!A(B12:20)$B!!(B($B;J2q(B $B | |||||
K109 | [$BE8K>9V1i!W9EAH?%%P%$%*%^%F%j%"%k$N8=>u$H>-MhE8K>(B | hard tissue biomaterials scaffold tissue regeneration | S-22 | 134 | |
$B!c%*!<%`>pJs$O@8J*2=3X9)3X$K?7Iw$r$b$?$i$9$+!d(B | |||||
$B3+2q0';"(B | |||||
(13:20$B!A(B14:00)$B!!(B($B;J2q(B $B4_K\(B $BDL2m(B) | |||||
K114 | [$BE8K>9V1i(B]$B%W%m%F%*!<%`2r@O | electrophoresis yeast proteome | S-24 | 508 | |
(14:00$B!A(B14:40)$B!!(B($B:BD9(B $BK\B?(B $BM5G7(B) | |||||
K116 | $B%P%$%*>pJs9)3X$NE83+(B | $BBe $B%P%$%*%W%m%@%/%7%g%s(B | S-24 | 91 | |
K117 | $B:YK&$NBe | metabolic flux transcriptome flux balance analysis | S-24 | 129 | |
(14:40$B!A(B15:20)$B!!(B($B:BD9(B $BARED(B $BGnG7(B) | |||||
K118 | [$B>7BT9V1i(B]$B@6 | $B@6 GC-MS$BJ,@O(B | S-24 | 778 | |
K119 | [$B>7BT9V1i(B]$BEE5$2=3X(BDNA$B%A%C%W$N4b?GCG$X$N1~MQ(B | electrochemical DNA chip ferrocenylnaphthalene diimdie cancer diagnosis | S-24 | 211 | |
(15:20$B!A(B16:00)$B!!(B($B:BD9(B $B@6?e!!9@(B) | |||||
K120 | $B%H%i%s%9%/%j%W%H!<%`2r@O$K$h$k<@45?GCG<#NE!A2DG=@-$HLdBjE@(B | DNA microarray cancer diagnosis bioinformatics | S-24 | 830 | |
K121 | Membranome$B$K4p$E$/(BAlzheimer$B>I$X$N%"%W%m!<%A!A(BMembrane Stress Biotechnology$B$N1~MQ!A(B | membrane stress biotechnology membranome Alzheimer disease | S-24 | 903 | |
$BAm9gF$O@(B | |||||
L$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!c4D6-D4OB7?MOG^$H$7$F$ND6NW3&N.BN$N4pAC$H1~MQ5;=Q!d(B | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $B7*86(B $B@6J8(B) | |||||
L101 | $BD6NW3&Fs;@2=C:AG$rMO2r$7$?%]%j%W%m%T%l%s$NG4@-FC@-(B | supercritical fluid viscosity polymer | S-27 | 205 | |
L102 | $B?e(B/$B:.9g3&LL3h@-:^(B/$BD6NW3&Fs;@2=C:AG7O$N3&LLJ*@-(B | Supercritical CO2 Surfactant W/scCO2microemulsion | S-27 | 677 | |
L103 | $BD6NW3&Fs;@2=C:AG$KBP$9$k%"%;%A%k%5%j%A%k;@(B($B%"%9%T%j%s(B)$B$NMO2rEY$NB,Dj$*$h$SAj4X(B | supercritical carbon dioxide acetylsalicylic acid solubility | S-27 | 847 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $BLZ86(B $B?-0l(B) | |||||
L104 | $BD6NW3&Fs;@2=C:AG$rMQ$$$?:xBN7A@.$K$h$k=E!&5.6bB0$NCj=P(B | supercritical chelating agent heavy metal | S-27 | 726 | |
L105 | $BD6NW3&Fs;@2=C:AG$K$h$k%b%G%kEZ>m$+$i$NB?4DK'9aB2C:2=?eAG$NCj=P5sF0(B | supercritical carbon dioxide aromatic hidrocarbon extraction | S-27 | 757 | |
L106 | $BD6NW3&Fs;@2=C:AG$rMOG^$H$7$?(BPPO$B$N9g@.$K$*$1$kAj5sF0$N1F6A(B | supercritical carbon dioxide poly(2,6-dimethyl-1,4-phenylene oxide) oxidative coupling polymerization | S-27 | 312 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $BFbED(B $BGn5W(B) | |||||
L107 | $BD6NW3&Fs;@2=C:AG$rMOG^$H$7$?EE5$2=3XH?1~$H$=$N%a%+%K%:%`2r@O(B | supercritical carbon dioxide conducting polymer diffusion coefficient | S-27 | 827 | |
L108 | $BD6NW3&(BCO2$BCf$G$N%9%A%l%s$NJ,;6=E9g(B | supercritical carbon dioxide dispersion polymerization polystyrene | S-27 | 932 | |
L109 | $BD6NW3&Fs;@2=C:AGN.BN$rMQ$$$?%J%NNN0h@)8f$K$h$k7k>=@-9bJ,;R!?Hs>=@-9bJ,;R%O%$%V%j%C%I$ND4@=(B | lamellar repeated structure supercritical carbon dioxide nanohybrid | S-27 | 272 | |
(13:00$B!A(B14:00)$B!!(B($B:BD9(B $BBm(B $B7rB@O:(B) | |||||
L113 | $BD6NW3&Fs;@2=C:AGCf$N0eLtIJ$NMO2rEYB,Dj$H$=$NHyN3;R2=(B | Supercritical carbon dioxide Solubility Micronization | S-27 | 880 | |
L114 | $BD6NW3&?eG.K!$r1~MQ$7$?C4;}7??(G^$N9g@.$H?(G^@-G=$NI>2A(B | supercritical water nano-paticle hydrothermal synthesis | S-27 | 810 | |
L115 | $BD6NW3&5^B.KDD%K!$rMxMQ$7$?%$%V%W%m%U%'%s$N%J%NN3;RAO@=$KBP$9$kA`:n0x;R$N1F6A(B | RESS supercritical carbon dioxide ibuprofen nanoparticle | S-27 | 872 | |
(14:00$B!A(B15:00)$B!!(B($B:BD9(B $B:4F#(B $BA1G7(B) | |||||
L116 | $BD6NW3&?eG.9g@.K!$rMQ$$$?B?9& | Supercritical water nano-particle hydrothermal synthesis | S-27 | 787 | |
L117 | $B9b299b05%Y%s%8%k%"%k%3!<%k$rMQ$$$?(BFRP$B$N%j%5%$%/%kK!$N3+H/(B | Fiber reinforced plastic solvothermal recycling | S-27 | 720 | |
L118 | $BD6NW3&?eCf$G$N%P%$%*%^%99bB.E>49$N$?$a$NN.DLH?1~AuCV$N3+H/(B | subcritical sugar conversion | S-27 | 401 | |
(15:00$B!A(B16:00)$B!!(B($B:BD9(B $B:4!9LZ(B $BK~(B) | |||||
L119 | $B%"%s%b%K%"@-G.?e$rMQ$$$?9E | Poly(vinyl chloride) Hydrothermal Dechlorination | S-27 | 585 | |
L120 | $BG.?e$rMQ$$$?%J%$%m%s(B6$B$N%b%N%^!<2=$K$*$1$kMOG^E:2C$N1F6A(B | Nylon 6 Hydrothermal Deploymerization | S-27 | 603 | |
L121 | $BD6NW3&?e;@2=H?1~$rMQ$$$? | catalic supercritical water oxidation laboratory waste water compact apparatus | S-27 | 950 | |
(16:00$B!A(B16:40)$B!!(B($B:BD9(B $B2,Eg(B $B$$$E$_(B) | |||||
L122 | $BG.?eCf$K$*$1$k%]%j%+!<%\%M!<%H$N%b%N%^!<2=(B | Polycarbonate Depolymerization Bisphenol A | S-27 | 615 | |
L123 | $BD6NW3&?e;@2=H?1~$rMQ$$$?%*%s%5%$%H7?0eNEGQ4~J*=hM}K!$N3+H/(B | supercritical water medical waste on-site treatment | S-27 | 952 | |
M$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!c4D6-It2q%7%s%]%8%&%`!d(B | |||||
(9:20$B!A(B10:00)$B!!(B($B;J2q(B $B9>F,(B $BLw9,(B) | |||||
M102 | [$BE8K>9V1i(B] $B91>o@- | S-30 | 972 | ||
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $BB<;3(B $B7{90(B) | |||||
M104 | $BD69E9g6b$K4^$^$l$k%l%"%a%?%k$N1v2=4xH/(B | carbochlorination rare metal recovery | S-30 | 179 | |
M105 | Sulfidation treatment of mixed plating sludges towards heavy metals recovery | Sulfidation Plating sludge Metal recovery | S-30 | 290 | |
M106 | $B@P9QGQ:`$N4T85G.J,2r$K$h$k=E6bB0N22=:^$N:n@.(B | Waste gypsum Reductive decomposition Calcium sulfide | S-30 | 515 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B>.@>(B $B9/M5(B) | |||||
M107 | $B29EY%9%$%s%0%/%m%^%HJ,N%K!$K$h$kL5GQ4~J*7?6bB0%j%5%$%/%k%7%9%F%`$N9=C[(B | Thermal Swing Gel Metal Recycle | S-30 | 962 | |
M108 | $B8w1~EzCj=PK!$K$h$k4uGv5.6bB04^M-GQ1U$+$i$N6b$N2s<}(B | Optical Response Extraction Noble Metals | S-30 | 963 | |
M109 | $B%Q%k%9!?D>N.=E>vEEN.$rMQ$$$kNt2=Fs | Worn-out batteries Pulse current Electrolysis | S-30 | 578 | |
(13:00$B!A(B13:40)$B!!(B($B;J2q(B $BC]2<(B $B7rFs(B) | |||||
M113 | [$BE8K>9V1i(B]$B!!:.;@GQ1U$+$i$N;@$N>xN12s<}5;=Q$N3+H/(B | distillation mixed acid recycle | S-30 | 971 | |
(13:40$B!A(B14:40)$B!!(B($B:BD9(B $BA%B$(B $B=S9'(B) | |||||
M115 | $BEE2rC4;}$K$h$k0u:~!&EIAu9)>l$NGS%,%9>t2=MQDLEE2CG.%"%k%^%$%H?(G^$N3+H/(B | Volatile Organic Compounds Electrolysis supporting process Electrothermal Alumite Catalyst | S-30 | 625 | |
M116 | $BFbG35!4X$rMxMQ$7$??eG.H?1~$K$h$kM-5!MOG^=hM}(B | automobile engine hydrotermal reaction dechlorination | S-30 | 201 | |
M117 | $BD6NW3&Fs;@2=C:AG$N5^B.KDD%$rMxMQ$7$?8zN(E*Cj=P$N$?$a$NA0=hM}J}K!$N3+H/(B | Supercritical carbon dioxide Rapid expansion Pre-treatment | S-30 | 472 | |
(14:40$B!A(B15:40)$B!!(B($B:BD9(B $BN)85(B $BM:<#(B) | |||||
M118 | $B%a%?%sH09Z$HC:;@?e=hM}$rJ#9g$7$?3-N`GQ4~J*=hM}%W%m%;%9$N3+H/(B | shell waste recycle | S-30 | 240 | |
M119 | $B6bB0%$%*%s4T85:Y6]$K$h$kGr6b$N%P%$%*%_%M%i%j% | biomineralization platinum metal-reducing bacteria | S-30 | 575 | |
M120 | $BFqG3%W%i%9%A%C%/$+$i$NG.J,2r@8@.=-AG7O%,%9$N8GBN5[<}=|5n(B | bromine flame-retardant dry gas cleaning | S-30 | 751 | |
(15:40$B!A(B16:40)$B!!(B($B:BD9(B $B:4Gl(B $B9'(B) | |||||
M121 | $B@PC:3h@-%3!<%/%9$rMQ$$$?4%<0C&N22=?eAG%W%m%;%9$N3+H/(B | adsorption activated coal hydrogen sulfide | S-30 | 215 | |
M122 | $B%U%m%s$N4%<0:F;q8;2=5;=Q$N4pAC8&5f(B | HCFC-22 dry-fixation reconverted resources | S-30 | 199 | |
M123 | $B%,%9%O%$%I%l!<%H$rMQ$$$?(BHFC-134a$B%,%9J,N%@-G=$N2r@O(B | gas recovery gas hydrate gas separation | S-30 | 737 | |
(16:40$B!A(B17:40)$B!!(B($B:BD9(B $B9bM|(B $B7 | |||||
M124 | $BJ* | material flow poisonous material environment | S-30 | 788 | |
M125 | $B!V%j%5%$%/%k%\%C%/%9!&_n>C<0!W$K$h$k%@%$%*%-%7%s$J$I4D6-GQ4~J*$NJ,2r=hM}(B | Smoke Permanent magnet Dioxin | S-30 | 743 | |
M126 | $B%^%V%A(BMZ$B%j%5%$%/%kAuCV$K$h$k>_L}Gt!"%*%jGQ1U$NJ,2r=hM}(B | Steam Soy lees Atomic conversion | S-30 | 759 | |
N$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!cM%=(O@J8>^^9V1i$*$h$S2=3X9)3XJ,Ln$N3X=QO@J8$N$"$jJ}!d(B | |||||
(13:00$B!A(B14:00)$B!!(B($B:BD9(B $BB?ED(B $BK-(B) | |||||
N113 | [$BM%=(O@J8>^(B]$BD>@\%a%?%N!<%k7?G3NAEECS$NG3NA6!5k7ABV$HF0:nFC@-(B | Direct methanol fuel cell (DMFC) Liquid phase feeding Gas phase feeding | S-37 | 551 | |
N114 | [$BM%=(O@J8>^(B]$BAPOS<0<>=aJ4BNYTOB5!$K$*$1$kHy;kE*:.9g>uBV$NI>2AK!(B | kneading mixing wet particle | S-37 | 559 | |
N115 | [$BM%=(O@J8>^(B]$B&R7?J?HD@E;_%^%$%/%m%_%-%5!<$N3+H/$*$h$S$=$N:.9gFC@-(B | Micromixer Plate Static Mixer Microreactor | S-37 | 565 | |
(14:00$B!A(B15:00)$B!!(B($B:BD9(B $BBgB<(B $BD>?M(B) | |||||
N116 | [$BM%=(O@J8>^(B]$BM-5!!&?e:.9gMOG^Cf$K7|By$7$?%3%m%$%IN3;R$N%G%C%I%(%s%I@:L)_I2a$K$*$1$k@8@._I2a%1!<%/$NFC@-(B | Microfiltration Organic Solvent Coagulation Parameter | S-37 | 570 | |
N117 | [$BM%=(O@J8>^(B]$B9b | Nonlinear System Modeling Historical Data | S-37 | 573 | |
N118 | [$BM%=(O@J8>^(B]$B:Y9&I=LL$r%7%j%k2=$7$?%a%=%]!<%i%9%7%j%+$KBP$9$k%"%;%H%s!??e$N5[CeJ,;R%7%_%e%l!<%7%g%s(B | Molecular Simulation Adsorption Mesoporous Material | S-37 | 584 | |
(15:00$B!A(B16:00)$B!!(B($B;J2q(B $BBgEh(B $B42(B) | |||||
N119 | [$B>7BT9V1i(B]$B1Q8l$i$7$$O@J8$N=q$-J}(B | English Expression Usage Publication | S-37 | 998 | |
O$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!cG3NAEECS!&?7EECS$*$h$S$=$N4XO"5;=Q$N?7E83+!d(B | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $B>1Ln(B $B8|(B) | |||||
O101 | $B%/%i%9%l!<%H%O%$%I%l!<%H$rMQ$$$??eAGCyB"$K4X$9$k4pACE*8&5f(B | hydrogen gas hydrate storage | S-36 | 878 | |
O102 | $B?eAGCyB":`NA$H$7$F$N%7%/%m%X%-%5%s(B+$B%a%A%k%7%/%m%X%-%5%s:.9g7O$N=tJ*@-(B | Fuel Cell Solid-liquid Equilibria Hydrogen Solubility | S-36 | 163 | |
O103 | $B?eAGCyB":`NA$H$7$F$N%7%/%m%X%-%5%s!<%a%A%k%7%/%m%X%-%5%s:.9g7O$NC&?eAGH?1~(B | hydrogen storage cyclohexane dehydrogenation | S-36 | 150 | |
(10:00$B!A(B10:40)$B!!(B($B:BD9(B $B>e5\(B $B@.G7(B) | |||||
O104 | $B%G%+%j%sC&?eAGH?1~$K$*$1$k4pxH/B.EY$NB,Dj(B | Organic chemical hydride Superheated liquid-film state Evaporation rate | S-36 | 825 | |
O105 | $B2~ | preparation of standard gas for reformed gas gas analysis solid oxide fuel cell (SOFC) | S-36 | 888 | |
(10:40$B!A(B11:20)$B!!(B($B:BD9(B $B>.3^86(B $B7<0l(B) | |||||
O106 | $BD6NW3&$a$C$-K!$K$h$k%Q%i%8%&%`(B-$B6d9g6bGvKl$ND4@=$H?eAGJ,N%F)2aFC@-$NI>2A(B | membrane Pd hydrogen | S-36 | 405 | |
O107 | $BD6NW3&%J%N%W%l!<%F%#%s%0K!$rMQ$$$?!"%"%k%^%$%H(B/Pd$B79 | fuel cell super critical nano plating palladium | S-36 | 678 | |
(11:20$B!A(B12:00)$B!!(B($B;J2q(B $B0KF#(B $BD> | |||||
O108 | [$B>7BT9V1i(B] $BG3NAEECSMQ?eAG@=B$5;=Q$N3+H/>u67$H>-MhE8K>(B | $BG3NAEECS(B | S-36 | 567 | |
(13:00$B!A(B14:20)$B!!(B($B:BD9(B $B55;3(B $B=(M:(B) | |||||
O113 | $B%;%i%_%C%/%94p:`%Q%i%8%&%`?eAGJ,N%Kl$NGvKl2=$N8!F$(B | membrane Pd hydrogen | S-36 | 424 | |
O114 | $B9b8zN($J(BCO$B%U%j! | membrane reactor hydrogen catalytic reaction | S-36 | 192 | |
O115 | $B%Q%i%8%&%`!&6d9g6bEE5$$a$C$-$K$h$k?eAGJ,N%Kl$N@=:n(B | hydrogen separation membrane palladium silver alloy | S-6 | 765 | |
O116 | $B%^%$%/%m?(G^G3>FAuCV$rMQ$$$?(BLPG$B$NG3>F;n83(B | catalytic combustor deactivation NOx | S-36 | 256 | |
(14:20$B!A(B15:20)$B!!(B($B:BD9(B $BApJI(B $B9n8J(B) | |||||
O117 | $B%a%?%N!<%k$rMQ$$$?ItJ,;@2=2~ | partial oxidation methanol reformer | S-36 | 563 | |
O118 | $BA*Br;@2=?(G^Kl%j%"%/%?!<$rMQ$$$?2~ | CO Selective Oxidation Membrane Reactor Fuel Cell | S-36 | 693 | |
O119 | CO2$B5[<}:^$rC4;}$7$?DLEE2CG.%"%k%^%$%H?(G^$K$h$k%(%?%N!<%k$N?e>x5$2~ | ethanol steam reforming Nonequilibrium operation CO2 absorption | S-36 | 806 | |
(15:20$B!A(B16:00)$B!!(B($B;J2q(B $B;38}(B $BLT1{(B) | |||||
O120 | [$B>7BT9V1i(B] $BJ,;67?EE5$%(%M%k%.!<%M%C%H%o!<%/$K$*$1$k%7%9%F%`LL$+$i8+$?G3NAEECS!&?7EECS3hMQ$X$N4|BT(B | fuel cell | S-36 | 581 | |
(16:00$B!A(B16:40)$B!!(B($B:BD9(B $B0f>e(B $B85(B) | |||||
O122 | $B%"%k%^%$%H?(G^$rMQ$$$?G3NAEECSMQ(BCO$B=|5n4o$K4X$9$k8&5f(B | Selective CO Oxidation Alumite Catalyst Serrated Fin Reactor | S-36 | 638 | |
O123 | $B8GBN9bJ,;R7?G3NAEECS$X$NCbAG4^M-?eAGG3NAMxMQ$K4X$9$k8&5f(B | PEFC Hydrogen Fuel mixed Nitrogen Fuel Flow | S-36 | 961 | |
(16:40$B!A(B17:40)$B!!(B($B:BD9(B $B2O@%(B $B85L@(B) | |||||
O124 | PEFC$BH/EE@-G=$K5Z$\$9N.O)Fb1UE)BZN1>uBV$N4V@\B,Dj(B | PEFC flooding relative humidity | S-36 | 736 | |
O125 | PEFC$BH/EE@-G=$K5Z$\$93H;6AXFb%U%i%C%G%#%s%0$N8!F$(B | PEFC flooding gas diffusion layer | S-36 | 741 | |
O126 | PEFC$B3H;6AXFbFsAjN.F0$N(BLBM$B?tCM%7%_%e%l!<%7%g%s(B | PEFC Two-phase flow Lattice Boltzmann Method | S-36 | 987 | |
(17:40$B!A(B18:40)$B!!(B($B:BD9(B $B:y0f(B $B@?(B) | |||||
O127 | $B8GBN9bJ,;R7AG3NAEECS$N%,%93H;6AXFb$N29EYJ,I[$H?e$NN.B+J,I[$N?dDj(B | PEFC One-dimensional nonisothermal model Gas diffusion layer | S-36 | 770 | |
O128 | $BC:AGA!0]@QAX9=B$$r9MN8$7$?(BPEFC$B3H;6AXFb$NFsAjN.2r@O(B | PEFC flooding gas diffusion layer | S-36 | 746 | |
O129 | $B?eAG5[B"9g6b%"%N!<%I$N?eAG9bB.%,%9= | fuel cell metal hydride hydrogen | S-36 | 818 | |
P$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!cCO5e4D6-LdBj$N2r7h$rL\;X$9D94|%(%M%k%.!<5;=Q@oN,$r9M$($k!*!d(B | |||||
(9:40$B!A(B11:00)$B!!(B($B:BD9(B $B5A2H(B $BN<(B) | |||||
P103 | $BMO:^Cj=PK!$rMxMQ$7$?3lC:$N%U%i%/%7%g%M!<%7%g%s(B | brown coal fractionation of coal solvent extraction | S-28 | 531 | |
P104 | $B@PC:$NDc29?e>x5$%,%92=FC@-$K$*$h$\$9%,%905NO$N1F6A(B | coal gasification fluidized bed | S-28 | 500 | |
P105 | $B3lC:$N?WB.G.J,2r!&(Bin-situ$B?e>x5$2~ | Coal Steam gasification Thermochemical energy recuperation | S-28 | 935 | |
P106 | Effects of Interactions among Inherent Minerals on the Emission of Fine Particulates during Coal Combustion | coal combustion PM coal density separations | S-28 | 658 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B>>2,(B $B9@0l(B) | |||||
P107 | $B3h@-%3!<%/%9$NIj3hK!$K$h$jC&N2FC@-$K4X$9$k8&5f(B | Exhaust gas desulfurization activated coke | S-28 | 96 | |
P108 | $B?e6d$N5$AjH?1~5sF0(B | Mercury Gas-phase reaction Coal Combustion | S-28 | 721 | |
P109 | $BGQ=a3jL}Cf$KIT=cJ*$H$7$F4^$^$l$kHyNL85AG$NJ,N%=|5nFC@-(B | Waste lubricating oil Trace elements Refining process | S-28 | 747 | |
(13:00$B!A(B13:40)$B!!(B($B;J2q(B $BDi(B $BFX;J(B) | |||||
P113 | [$BE8K>9V1i(B] "On the Roadmap, Off the Roadmap, Or Beyond the Roadmap ? That is the Question." -$B2=3X$H%(%M%k%.!<5;=Q!";:6H!& | . . . | S-28 | 978 | |
(13:40$B!A(B14:20)$B!!(B($B;J2q(B $BARK\(B $B9@;J(B) | |||||
P115 | [$BE8K>9V1i(B] $B%P%$%*%^%9%(%M%k%.!<$NM-8z3hMQ$H;q8;=[4D(B($B7\$U$s>F5QH/EE(B) | . . . | S-28 | 525 | |
(14:20$B!A(B15:00)$B!!(B($B;J2q(B $B0K86(B $B3X(B) | |||||
P117 | [$BE8K>9V1i(B]$BH/EE%7%9%F%`$H$7$F$N(BSOFC$B$N3+H/>u67$H:#8e$N2]Bj(B | . . . | S-28 | 528 | |
(15:00$B!A(B15:40)$B!!(B($B;J2q(B $B>.NS(B $B7I9,(B) | |||||
P119 | [$BE8K>9V1i(B]$BCOCfCyN1$HJ,;67?H/EE%7%9%F%`(B | . . . | S-28 | 530 | |
(15:40$B!A(B16:20)$B!!(B($B;J2q(B $B@6?e(B $BCiL@(B) | |||||
P121 | [$BE8K>9V1i(B]$B;}B37? | . . . | S-28 | 536 | |
(16:20$B!A(B17:00)$B!!(B($B;J2q(B $B>>B<(B $B9,I'(B) | |||||
P123 | [$BE8K>9V1i(B]$B;}B32DG=$J>CHq$H$O!)(B | . . . | S-28 | 537 | |
(17:00$B!A(B18:00)$B!!(B($B;J2q(B $BARK\(B $B9@;J!&0K86(B $B3X(B) | |||||
$BAm9gF$O@(B | |||||
Q$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!cH?1~9)3X$N?7$7$$E83+!d(B | |||||
(9:20$B!A(B10:40)$B!!(B($B:BD9(B $B4_ED!!>;9@(B) | |||||
Q102 | $B0eLtIJ%?%s%Q%/ | Micron-size device surface material aqueous polymer two-phase systems | S-12 | 943 | |
Q103 | $B%R%H(BDNase_I$B@8;:MQ9ZJl$rMQ$$$?%^%$%/%m6u4VFb@8J*H?1~$N2r@O(B | $B%^%$%/%m@8J*H?1~4o(B $B2sJ,G]M\(B $BO"B3G]M\(B | S-12 | 244 | |
Q104 | $B1UAj%^%$%/%m%j%"%/%?!<$G$NFs2A(B-$B3H;6$N1F6A(B | microreactor rapid reaction diffusion | S-12 | 145 | |
Q105 | $B1UAj%^%$%/%m%j%"%/%?!<$G$NC`2A(B-$B3H;6$NA*Br@-$X$N1F6A(B | microreactor consecutive reaction transport phenomena | S-12 | 156 | |
(10:40$B!A(B12:00)$B!!(B($B:BD9(B $BJ!86!!D9 | |||||
Q106 | $B9b299b05%^%$%/%m%_%-%5!<$N3+H/(B | micromixer high pressure and temperature supercritical fluid | S-12 | 85 | |
Q107 | $BHsEy297O$K$*$1$kN.BN%;%0%a%s%H$K4p$E$$$?:.9g!&H?1~A`:n$N@_7W(B | microreactor fluid segment nonisothermal operation | S-12 | 38 | |
Q108 | $BN.BN%;%0%a%s%H>WFM$K4p$E$$$?%^%$%/%m%_%-%5!<$K$h$k%S%9%U%'%N!<%k(BF$B$N9g@.(B | micromixer bisphenol F selectivity | S-12 | 37 | |
Q109 | $B%^%$%/%m=E9gH?1~%7%9%F%`$rMQ$$$?9bJ,;RHyN3;R$NN37B@)8f$N;n$_(B | microreactor soap free polymerization suspension polymerization | S-12 | 86 | |
(13:00$B!A(B14:20)$B!!(B($B:BD9(B $BKR(B $BBYJe(B) | |||||
Q113 | $B%^%$%/%m%A%c%M%k$rMxMQ$7$?HyNL1UBN$N>xN1(B | distillation microchannel microreactor | S-12 | 984 | |
Q114 | $B5$8G?(G^H?1~7O$K$*$1$k%^%$%/%m%A%c%M%kJILLC4;}?(G^$K4X$9$k9M;!(B | micro channel catalyst gas solid reaction | S-12 | 755 | |
Q115 | $B%>%k%2%kK!$rMxMQ$7$?%^%$%/%m%A%c%M%k?(G^$N:n@=(B | catalyst microchannel sol gel | S-12 | 259 | |
Q116 | $B%^%$%/%m%j%"%/%?!<$N$?$a$NGr6b(B-$B%"%k%_%J?(G^$X$N%"%k%+%j6bB0E:2C$N1F6A(B | microreactor catalyst alkali | S-12 | 60 | |
(14:20$B!A(B15:20)$B!!(B($B:BD9(B $B4X!! | |||||
Q117 | $B%^%$%/%m%A%e!<%V7?(BPd-Zn$B7O?(G^$K$h$k%a%?%N!<%k$N?e>x5$2~ | Microreactor Methanol steam-reforming Pd-Zn catalyst | S-12 | 355 | |
Q118 | $B%8%a%A%k%(!<%F%k2~u$K$h$k3h@-$X$N1F6A(B | dimethylether steam reforming catalyst | S-12 | 383 | |
Q119 | $BG3NAEECSMQ%8%a%A%k%(!<%F%k?e>x5$2~ | DME CFD reforming | S-12 | 200 | |
(15:20$B!A(B16:40)$B!!(B($B:BD9(B $BC]Cf!!AT(B) | |||||
Q120 | $B%"%k%^%$%H?(G^$rMQ$$$?7HBS5!4o8~$1G3NAEECSMQ%^%$%/%m2~ | Almite Catalyst Micro Reactor Steam Reforming | S-12 | 640 | |
Q121 | $B?(G^0lBN2=%b%8%e!<%k$N3+H/(B | Hydrogen Membrane Reformer | S-12 | 426 | |
Q122 | Ru/ZrO2$B?(G^>e$G$N%a%?%s$N9b05?e>x5$2~ | Methane steam reforming High pressure Initial reaction rate | S-12 | 170 | |
Q123 | $B2~2A(B | Palladium Alloy Membrane Impurity Gas Surface Reaction | S-12 | 430 | |
(16:40$B!A(B17:40)$B!!(B($B:BD9(B $BApJI!!9n8J(B) | |||||
Q124 | CO$B$NA*Br;@2=$N$?$a$N%^%$%/%m%A%e!<%V>u?(G^$ND4@=(B | Microreactor Preferential CO oxidation Co/Al catalyst | S-12 | 357 | |
Q125 | $B%8%a%A%k%(!<%F%k6&B82<$K$*$1$k(BCO$BA*Br;@2=H?1~FC@-(B | dimethylether preferential oxidation catalyst | S-12 | 512 | |
Q126 | $B@PL}7OC:2=?eAG$NJ,2rK!$K$h$k(BCOx$B%U%j! | nickel COx-free hydrogen hydrocarbon decomposition | S-12 | 571 | |
R$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!cH?1~9)3X$N?7$7$$E83+!d(B | |||||
(9:20$B!A(B10:40)$B!!(B($B:BD9(B $B9CHe!!7IH~(B) | |||||
R102 | $B%"%k%_%JC4BN>e$N6bB0(BCo$B$H(BRu$B$NAj8_G[CV@)8f(B | alumina-supprted Co Ruthenium addition CO hydrogenation | S-12 | 560 | |
R103 | $B%a%?%sItJ,;@2=$KBP$9$k%7%j%+HoJ$%K%C%1%k?(G^$NBQ5W@-$N8!F$(B | silica-coated Ni silica-supported Ni partial oxidation of methane | S-12 | 461 | |
R104 | $B?e(B/$BM-5!MOG^(B/$B3&LL3h@-:^MO1U$rH?1~>l$H$7$?%<%*%i%$%H%J%N%/%j%9%?%k9g@.K!(B | zeolite nanocrystal surfactant | S-12 | 875 | |
R105 | $B<+F0 | diffusion coefficient automotive catalysts gas | S-12 | 882 | |
(10:40$B!A(B12:00)$B!!(B($B:BD9(B $B;3ED!!Gn;K(B) | |||||
R106 | $BC4;}5.6bB0?(G^>e$G$N(BNO-CO$BH?1~$K$*$1$k<~4|E*(BO2$BE:2C8z2L(B | Periodic Operation NO-CO-O$2$ Reaction Noble Metal | S-12 | 776 | |
R107 | $B;@2=E4$N4T85!&:F;@2=$NB.EYO@E*8!F$$K4p$E$/5<;w0\F0AX7?H?1~4o@_7W(B | hydrogn storage iron oxide simulated moving bed reactor | S-12 | 789 | |
R108 | Bi-P-O$B?(G^;@2=EY$X$NN.NL$N1F6A$H<~4|E*N.NLJQF0A`:n$X$N1~MQ(B | Bi-P-O catalyst gas velocity forced flow rate cycling | S-12 | 817 | |
R109 | $BBN@Q8:>/$r4^$`H?1~$rN.F0?(G^AX$G9T$&>l9g$NH?1~%,%9B?CJ6!5k$N8z2L(B | reactor fluidized bed defluidization | S-12 | 83 | |
(13:00$B!A(B14:00)$B!!(B($B:BD9(B $B0BED!!7<;J(B) | |||||
R113 | $B%^%$%/%mGH>H | microwave aromatic compound alkylation | S-12 | 57 | |
R114 | $BD62;GH>H | ultrasound extraction organo-chlorine herbicide | S-12 | 287 | |
R115 | $B%A%e!<%V7?KlH?1~4o$KE,9g$7$?%^%$%/%mGH2CG.AuCV$N3+H/(B | microwave membrane reactor palladium | S-12 | 699 | |
(14:00$B!A(B15:00)$B!!(B($B:BD9(B $B>.Eg(B $B5A90(B) | |||||
R116 | $BBg7?$ND62;GHH?1~4o$N3+H/(B | ultrasonic reactor superposition large-scale | S-12 | 369 | |
R117 | $B%(%?%N!<%k$ND62;GHL82=J,N%$K$*$1$k>xH/$N1F6A(B | ultrasonic atomization evaporation ethanol | S-12 | 428 | |
R118 | $BD62;GH$rMQ$$$?%(%^%k%7%g%s$+$i$NL}AjJ,N%B%?J(B | ultrasonic separation emulsion coalescence | S-12 | 617 | |
(15:00$B!A(B16:00)$B!!(B($B:BD9(B $BGr@P!!J8=((B) | |||||
R119 | $BFs;@2=%A%?%s!&D62;GHK!$K$h$k(BOH$B%i%8%+%k$N@8@.$HMOB8%"%k%4%s$NB%?J8z2L(B | TiO2 cavitation ultrasound | S-12 | 716 | |
R120 | $B?e$N2D;k8wJ,2r%b%G%k$K$*$1$k8w?(G^@QAXKl$N9=C[(B | Photolysis of Water Titania Platinum | S-12 | 142 | |
R121 | $B9b5!G=8w?(G^6t$K$h$k%[%k%`%"%k%G%R%I$N=|5n(B | TiO2 photocatalyst zeolite lime plaster | S-12 | 367 | |
(16:00$B!A(B17:00)$B!!(B($B:BD9(B $BBg^ | |||||
R122 | $B>.7?2=$7$?JBNs4I7?8w?(G^H?1~4o$N@-G=I>2A(B | Compacted photocatalytic reactor Volatile organic compounds PET film | S-12 | 339 | |
R123 | $BJBNs4I7?8w?(G^H?1~4o$K$h$kL)JD6u4VFb$N6u5$CfHyNL%H%k%(%sJ,2r$HLdBjE@(B | Photocatalytic reacto Toluene Adsorption | S-12 | 341 | |
R124 | $BMO | Photocatalyst Thermal spraying Water treatment | S-12 | 344 | |
(17:00$B!A(B17:40)$B!!(B($B:BD9(B $B>>:,!!1Q | |||||
R125 | $B6KDcG;EY$NM-5!J*J,2r$K$*$1$k8w?(G^H?1~FC@-(B | Photocatalytic activity Very-low concentration UV intensity | S-12 | 345 | |
R126 | $B2C=y<>K!$K$h$k6u5$>t2=$NFC@-(B | Rapid air purification Gaseous ammonia Simultaneous humidification and dehumidification | S-12 | 346 | |
S$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!c%7%9%F%`!&>pJs!&%7%_%e%l!<%7%g%s5;=Q$N?7$?$JE83+!d(B | |||||
(9:00$B!A(B10:40)$B!!(B($B:BD9(B $B2CG<(B $B3X(B) | |||||
S101 | OJT$B$N$?$a$N1?E>0wG[CV7W2h$N:GE,2=(B | OJT plant operator optimization | S-13 | 136 | |
S102 | $B7A>u5-219g6bGvKl$rMQ$$$?%"%/%A%e%(!<%?$N@)8f$K$D$$$F(B | shape-memory alloy control | S-13 | 481 | |
S103 | $B8zN(FC@-$r<+8J3X=,$9$k<+N'J,;66%Ah7?%K%e!<%m%3%s%H%m!<%i(B | neural network process control decentralized autonomus control | S-13 | 922 | |
S104 | $B%*%s%i%$%s%b%K%?%j%s%0$N$?$a$N%W%m%;%9FbIt;~6u4V%Q%?!<%s$N%/%i%9%?%j%s%0(B | clustering process monitoring pattern processing | S-13 | 88 | |
S105 | Modeling human behavior of fault detection and identification in plant operations | plant operation fault detection and identification model-based evaluation | S-13 | 796 | |
(10:40$B!A(B12:20)$B!!(B($B:BD9(B $BLnED(B $B8-(B) | |||||
S106 | $BF1?4:Y@~7?%3%m%JJ|EEH?1~4o$K$h$k%"%s%b%K%"J,2r%7%_%e%l!<%7%g%s(B | Ammonia gas Corona discharge Simulation | S-13 | 613 | |
S107 | $B2=3XJ*t%W%m%;%9@_7W$N$?$a$N5!G=%b%G%k(B | Industrial cleaning Risk-based process design Function model | S-13 | 26 | |
S108 | $BMM!9$JMxMQ | BTO Web application | S-13 | 228 | |
S109 | $B%0%i%UM}O@$K$h$kJ]29J]NdG[4I$N30LLIe?)MW0x$N=g=x<\EY$N?dDj(B | surface corrosion graph theory insulated pipeline | S-13 | 53 | |
S110 | $BJ]29J]NdG[4I$N30LLIe?)8:FyB.EY$N?d;;K!$N2~A1(B | surface corrosion maximal corrosion rate maintenance | S-13 | 352 | |
$B!c$h$jNI$$%W%i%s%HA`6H$rL\;X$7$F!];:6H3&$G$N:G?7%"%W%m!<%A!d(B | |||||
(13:00$B!A(B14:00)$B!!(B($B;J2q(B $B2CG<(B $B3X(B) | |||||
S113 | [$BE8K>9V1i(B] Model-based Innovation in the Process Industries: R&D, Modelling and Risk (Imperial College London / Process Systems Enterprise) $B!{(BPantelides C. C. | S-14 | 981 | ||
(14:00$B!A(B15:20)$B!!(B($B:BD9(B $B;32<(B $BA1G7(B) | |||||
S116 | $BBg7?@PL}@:@=!&%,%9%W%i%s%H$K$*$1$k%W%i%s%H>pJs%7%9%F%`$N%H%l%s%I$N>R2p(B | plant operations managemanet real-time performance management MES | S-14 | 756 | |
S117 | $B@QJ,%W%m%;%9$N%5%s%W%k(BPI$B@)8f@_7W(B | sampled sata control integrating process settling time | S-14 | 197 | |
S118 | $B2=3X%W%i%s%H$K$*$1$k%l%Y%k@)8f%"%k%4%j%:%`$N9M0F!&3+H/$H | PID Control Level Control | S-14 | 157 | |
S119 | $BB?JQNL2r@O$rMxMQ$7$?@=IJIJ | multivariate analysis quality improvement steel making and finishing process | S-14 | 926 | |
(15:20$B!A(B16:20)$B!!(B($B:BD9(B $B@>_7(B $B=_(B) | |||||
S120 | $B@)8fJ[Ey$NIT6q9g;vNc$H2~A1$X$N | Performance monitoring Control valve | S-14 | 609 | |
S121 | $B%W%i%s%H%7%_%e%l!<%?$r3hMQ$7$?D4@aJ[8GCe;~$N@)8f1~Ez$N2r@O$H8GCe8!=P | process control process monitoring plant wide control | S-14 | 227 | |
S122 | $B%W%i%s%H@)8f@-G=?GCG%7%9%F%`$N9=C[(B | plant operation control performance monitoring fault diagnosis | S-14 | 47 | |
(16:20$B!A(B17:40)$B!!(B($B:BD9(B $BLnED(B $B8-(B) | |||||
S123 | $B9)6HMQ2CG.O'$X$N%b%G%kM=B,@)8f$NE,MQ(B | model predictive control industrial furnace process control | S-14 | 222 | |
S124 | $B%W%m%;%9@)8f$X$N%b%G%k%Y!<%9%I%G%6%$%s$NE,MQ(B | Model based design Model predictive control MATLAB/Simulink/Stateflow | S-14 | 21 | |
S125 | $B%&%'!<%V%l%C%H2r@O$HB?JQNL2r@O$rMQ$$$?%P%C%A%W%m%;%9A`:n%W%m%U%!%$%k$N:GE,2=(B | batch process wavelet analysis optimization | S-14 | 265 | |
S126 | $B%(%A%l%s%W%i%s%H=iN1Ec$NG.2s<}:GE,2=(B | Primary Fractionator Model Predictive Control Optimizer | S-14 | 861 | |
T$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!c%W%m%;%90BA44IM}$N%U%l!<%`%o!<%/9=C[$N$?$a$K!d(B | |||||
(9:00$B!A(B10:40)$B!!(B($B:BD9(B $B^ | |||||
T101 | [$BE8K>9V1i(B]$B0BA4It2q$G9M$($k%U%l!<%`%o!<%/$O(B | Process Safety Safey Framework | S-29 | 180 | |
T103 | $BGQ4~J*=hM};\@_$N0BA4%U%l!<%`%o!<%/9=C[(B | safety framework waste management | S-29 | 302 | |
T104 | $B%W%m%;%90BA44IM}$N%U%l!<%`%o!<%/9=C[(B | Process Safety Management Risk Management Plant Life Cycle | S-29 | 90 | |
T105 | $B;v8N!?%R%d%j%O%C%H;vNc$N%G!<%?%Y!<%92=$H3hMQ(B | Safety management Data-base Near-miss | S-29 | 79 | |
(10:40$B!A(B12:00)$B!!(B($B:BD9(B $B@nC<(B $B1T7{(B) | |||||
T106 | $B2=3X9)>l$K4X$9$k>pJs8x3+$K$D$$$F$N<~JU;TL1$N9%46EYEyD4::$N7k2L$K$D$$$F(B | risk communication WEB recearch public acceptance | S-29 | 464 | |
T107 | $BJ]0B$N$?$a$KI,MW$J4IM}5;=Q$H$O(B | maintenance safety | S-29 | 178 | |
T108 | [$BE8K>9V1i(B]$B;:6HJ]0B@/:v$N:#8e$NE8K>(B | industrial safety safety programm | S-29 | 482 | |
$B!c@8;:3W?7$N$?$a$N%3%9%H%^%M!<%8%a%s%H!d(B | |||||
(13:00$B!A(B14:40)$B!!(B($B:BD9(B $B;{_7(B $B?5M4(B) | |||||
T113 | $B%3%9%H(B1$B!?(B2$B$H7P1D3W?7(B | AACEI Skills&Knowlegs Costengineering | S-15 | 307 | |
T114 | $B@8;:3W?7?d?J$N$?$a$N%3%9%H3+H/(B | cost management cost development cost planning | S-15 | 133 | |
T115 | $BH/EE@_Hw$N7P:Q@-I>2A(B | Power Generation Power Generation Cost Power Generation Economy | S-15 | 492 | |
T116 | Aspen ICARUS$B@=IJ$rMQ$$$?8zN(E*$J7P:Q@-I>2A(B | Aspen ICARUS Cost evaluation | S-15 | 162 | |
(14:40$B!A(B16:00)$B!!(B($B:BD9(B $B@6?e(B $B@5 | |||||
T118 | AACEI/Skills &$B!!(BKnowledges$B$NF|K\8lK]Lu;v6H(B | AACEI Skills & Knowledges Costengineering | S-15 | 131 | |
T119 | $B@_HwHq?d;; | COST ENGINEERING COST ESTIMATE PLANT CAPACITY EXPONENT | S-15 | 285 | |
T120 | $B%[!<%`%*%U%#%9%3%9%H8+@Q$N:G>.2=(B($B%/%j%F%#%+%k%A%#!<%s$rMQ$$$F(B) | Home office cost estimation Critical chain Chemical plant | S-15 | 11 | |
T121 | $B2=3X%W%i%s%H7z@_9);v%3%9%H4p=`:n@.$X$N0l9M;!(B | Costmanagement Constructioncost Coststandard | S-15 | 99 | |
(16:00$B!A(B16:20)$B!!(B($B;J2q(B $B;{_7(B $B?5M4(B) | |||||
T122 | $B%W%i%s%H(BEPC$B$K$*$1$k%3%9%H%^%M!<%8%a%s%H(B | Cost Management Engineering Proposal | S-15 | 126 | |
(16:20$B!A(B16:40)$B!!(B($B;J2q(B $B@6?e(B $B@5 | |||||
T123 | $B2=3X%W%i%s%H$ND4C#6HL3$K$*$1$k%3%9%H%^%M%8%a%s%H(B | Cost Management Procurement Activity Chemical Plant | S-15 | 87 | |
U$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!c | |||||
(10:00$B!A(B12:00)$B!!(B($B:BD9(B $B2,K\(B $B>0 | |||||
U104 | [$B>7BT9V1i(B] $B%;%s%5%M%C%H%o!<%/MQD6>.7?L5@~%;%s%5%b%8%e!<%k$N | Sensor networks Wireless sensor module Ubiquitous system | S-20 | 153 | |
U106 | $B1t%U%j! | Lead-free Solder RoHS Adhesive Sheet | S-20 | 917 | |
U107 | $B%,%i%94pHD>e$N(BCu$B$a$C$-G[@~$KE,$7$?Dc@~KDD%$a$C$-Kl$N:n@=(B | alloy plating copper nickel | S-20 | 143 | |
U108 | $B%]%j%^!<$N%^%$%/%mGHBS0h$K$*$1$kM6EEFC@-B,Dj5;=Q(B | permittivity cavity microwave | S-20 | 493 | |
U109 | $B | FeRAM ruthenium electrodeposition | S-20 | 48 | |
(13:00$B!A(B14:40)$B!!(B($B:BD9(B $B6aF#(B $BOBIW!&NS!!=(?C(B) | |||||
U113 | [$B>7BT9V1i(B]$BH>F3BN | Wire-bonding Flip-chip Micro-joining | S-20 | 198 | |
U115 | $B6d$N%^%$%0%l!<%7%g%s$K4X$9$k4pAC8&5f(B | Silver ion migration Diffusion Electric field | S-20 | 976 | |
U116 | COF$B4p:`$K$*$1$k%$%*%s%^%$%0%l!<%7%g%s5sF0(B | COF ionmigration | S-20 | 866 | |
U117 | $BEE2r(BCu$BGs>e$N(BSn$B$a$C$-Kl$+$iH/@8$9$k%&%#%9%+(B | whisker Copper foil Tin | S-20 | 243 | |
(15:00$B!A(B16:40)$B!!(B($B:BD9(B $B@P0f(B $B@5?M!&2.Ln(B $BJ84](B) | |||||
U119 | [$B>7BT9V1i(B]FPC($B%U%l%-%7%V%k%W%j%s%H2sO)(B)$B$N | Flexible Printed Circuit Jisso FPC Production System | S-20 | 511 | |
U121 | $B9bL)EY | multi-layer FPC solder interconnection high density mounting | S-20 | 696 | |
U122 | $B9bL)EY | Cutting method Adhesion Organic thin film | S-20 | 824 | |
U123 | $BF<%@%^%7%s$a$C$-$K$*$1$kEE2rEEN.GH7A$HCf4VB%?J:xBN(B | electroplating copper damascene rotating ring disk electrode | S-20 | 34 |