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 | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $BD9Nf(B $B?.Je(B) | |||||
A301 | $BIU2C=E9g$H%>%k(B-$B%2%kH?1~$K$h$k%]%j%&%l%"(B/$B%7%j%+J#9gCf6uN3;R$ND4@=(B | sol-gel process hollow particle composite | S-33 | 137 | |
A302 | $BD6NW3&?eG.K!$K$h$k?75,%;%j%"%J%N%/%j%9%?%k$NAO@=(B | Supercritical water Nanocrystal Cerium oxide | S-33 | 913 | |
A303 | $B%=%k%\%5!<%^%k=hM}$K$h$k<'@-;@2=%A%?%s8w?(G^N3;R$N9b8w3h@-2=(B | Photocatalyst Titanium dioxide Magnetite | S-33 | 280 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $BLZB<(B $BM&M:(B) | |||||
A304 | $BD6NW3&(BCO2$B$rMQ$$$?%J%N6u4V$G$NHyN3;R9g@.(B | porous materials catalyst supercritical CO2 | S-33 | 217 | |
A305 | $BD6NW3&<'5$%J%NN3;R$rMQ$$$?EE<'1~Ez%a%?%^%F%j%"%k$NAO@8(B | metamaterials hydrothermal synthesis magnetic nanoparticles | S-33 | 897 | |
A306 | $B6bB0%$%*%s4T85:Y6]$rMxMQ$9$k(BPd$B%J%NN3;R$N%P%$%*9g@.(B | biosynthesis palladium nanoparticle | S-33 | 579 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B | |||||
A307 | $B%J%NN3;RJ,;61UE)$N4%Ag2aDx$K$*$1$k%W%m%;%9>r7o$HN3;R7O9=B$$N4X78(B | simulation droplet evaporation process parameter | S-33 | 378 | |
A308 | Bimodal$B$JN3;R7BJ,I[$rM-$9$kN3;R7O$NEII[4%Ag%W%m%;%9$K$*$1$k<+8JG[Ns(B | Bimodal particle system self-organization core-shell | S-33 | 876 | |
A309 | $B0\N.=8@Q$K$h$kN3;RKl@->u$K5Z$\$94pHD?F?e@-$N1F6A(B | particle film self-assembly hydrophilicity | S-33 | 366 | |
B$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!c4D6-!&>l$N%W%m%;%C%7%s%0@)8f$K$h$k9bJ,;R:`NA$N5!G=AO=P!d(B | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $B8eF#(B $B7rI'(B) | |||||
B301 | $BFqG32=$r$a$6$9%J%N%3%s%]%8%C%H$K$*$1$k?e;@2=%^%0%M%7%&%`N3;R$NE:2C8z2L(B | nanocomposite magnesium hydroxide flame resistance | S-31 | 486 | |
B302 | $B?M9)?(3P8!CN%7%9%F%`$K$h$k9bJ,;R | tactile sensing particle and polymer distinctive frictional behavior | S-31 | 358 | |
B303 | AOT$B5U%_%;%k$rMQ$$$k9ZAGFbJq%]%j%^!<%J%N%+%W%;%k$ND4@=$H9ZAG3h@-(B | reverse micelles encapsulation enzyme | S-31 | 670 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $B8eF#(B $B=!<#(B) | |||||
B304 | $B%Q%s9ZJl8GDj2=%+%W%;%k7?%^%$%/%m%P%$%*%j%"%/%?!<$rMxMQ$9$kIT@F4T85FC@-(B | microcapsule Baker$B!G(Bs Yeast asymmetric reduction | S-31 | 39 | |
B305 | $BFHN)1IM\@-C&Cb:Y6]$r8GDj2=$7$?%+%W%;%k7?%^%$%/%m%P%$%*%j%"%/%?!<$N3+H/$H$=$NC&CbG=NO$NI>2A(B | denitrifying bacteria microencapsulation nitrate nnitrogen | S-31 | 54 | |
B306 | $B?eMO@-;&Cn:^$rFbJq$9$k%+%W%;%k2=G@Lt@=:^$N3+H/$H$=$NFC@-I>2A(B | water-soluble insecticide biodegradable polymer microencapsulation | S-31 | 49 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B | |||||
B307 | $B%^%$%/%m%+%W%;%k2=:+Cn%U%'%m%b%s$rMxMQ$9$kG@:nJ*32Cn$NAm9gKI=|$K4X$9$kI>2A(B | microcapsule insect pheromone controlled release | S-31 | 50 | |
B308 | $B9ZAGJ]8n5!G=$rM-$9$kB?9&@-Cf6u;eKl$X$N9ZAG$N8GDj2=$H$=$N3h@-I>2A(B | Immobilization Polymer brush Esterification | S-31 | 644 | |
B309 | $B?;F)05$rMxMQ$7$??75,9386G'<1%2!<%H7?%P%$%*%;%s%7%s%0K!$N3+H/(B | Biosensing Osmotic pressure Antigen-responsive membrane | S-31 | 659 | |
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 | |
$B!c<+8JAH?%2=%W%m%;%9$H2=3X9)3X!d(B | |||||
(9:00$B!A(B10:20)$B!!(B($B:BD9(B $BLnB<(B $B=SG7(B) | |||||
C301 | $B%G%#%C%W%3!<%F%#%s%0$K$h$kN3;RG[Ns%Q%?!<%s$NB?MM@-$N8!F$(B | Photonic crystal Dip-coating Mono-layer | S-32 | 308 | |
C302 | $B%7%j%+HoJ$6b%J%NN3;R$N(B2$B | two-dimentional array nanoparticle self-assembly | S-32 | 471 | |
C303 | $B<+8JAH?%2=$K$h$j5,B'E*$KG[Ns$7$?%7%j%+%J%NN3;R$N9g@.$H1~MQ(B | silica nanoparticles catalyst | S-32 | 550 | |
C304 | $B%3%"%7%'%k9=B$$rM-$9$kC1J,;6@-5e>uN3;R$N;0 | core-shell particles hollow particles 3-dimensional ordered structure | S-32 | 631 | |
(10:20$B!A(B11:20)$B!!(B($B:BD9(B $BLZKs(B $B8w@5(B) | |||||
C305 | $BM-5!MOG^J,;67?6d%J%NN3;R$N9g@.$HC` | silver nanoparticle tetraalkylammonium stepwise growth | S-32 | 587 | |
C306 | $B%7%j%+HoJ$(BPt$B7O9g6b%J%NN3;R$+$i$N%J%N%9%1!<%k%+!<%\%s$N@8@.(B | silica-coated Pt-alloy nanoparticle carbon nanotube and carbon nanofiber microemulsion | S-32 | 473 | |
C307 | $B%,%i%9I=LL$N%A%*!<%k2~ | glass surface 3-mercaptopropyltrimethoxysilane XPS | S-32 | 910 | |
(11:20$B!A(B12:00)$B!!(B($B;J2q(B $B1v0f(B $B>O5W(B) | |||||
C308 | [$BE8K>9V1i(B]$BN3;RKl@=B$$N$?$a$NHyN3;RG[Ns%W%m%;%9$H%9%1!<%k%"%C%W(B | self assembly self-organization | S-32 | 730 | |
(13:00$B!A(B14:00)$B!!(B($B:BD9(B $B2CF#(B $B7I0l(B) | |||||
C313 | $B%+%A%*%s7?3&LL3h@-:^$K$h$k%*%k%,%N%2%k7O$K$*$1$k9ZAG3h@-(B | CTAB Microemulsion Organogel | S-32 | 722 | |
C314 | $BE>Aj29EYF}2=K!$rMxMQ$7$?%^%$%/%m%j%"%/%?!<$K$h$k%J%N%(%^%k%7%g%s$ND4@=(B | microreactor phase inversion temperature method nano-emulsion | S-32 | 651 | |
C315 | AOT$B$r?eE)3K@8@.>l$H$7$?B?9&@-9bJ,;RKl$N@8@.(B | pore formation AOT polymer film | S-32 | 499 | |
(14:00$B!A(B15:00)$B!!(B($B:BD9(B $BKY2O(B $B=S1Q(B) | |||||
C316 | Low-k, Low-index$B:`NA$H$7$F$N%a%=%]!<%i%9%7%j%+GvKl$N9g@.(B | mesoporous silica vapor phase synthesis low-k, low-index film | S-32 | 177 | |
C317 | $B%$%s%T!<%@%s%9K!$K$h$k?'AGA}46B@M[EECS$N2r@OK!(B | electrochemical impidance dye-sensitized solar cell electron transfer | S-33 | 620 | |
C318 | $B%$%s%T!<%@%s%9K!$K$h$k?'AGA}46B@M[EECS$NEE;R0\F05sF0(B | Dye-sensitized solar cell electron transfer inpidance analysis | S-33 | 624 | |
(15:00$B!A(B16:00)$B!!(B($B:BD9(B $B:#Ln(B $B44CK(B) | |||||
C319 | $BM-5!(B-$BL55!%O%$%V%j%C%I%7%j%+$K$*$1$k%7%m%-%5%s9|3J%Q!<%3%l!<%7%g%s5sF0$N8&5f(B | organic-inorganic hybrid silica random site percolation siloxane domain | S-32 | 329 | |
C320 | $B6/$$N.BNAj8_:nMQ$r | colloidal nanoparticles self-organization hydrodynamic interaction | S-32 | 382 | |
C321 | $B0\N.=8@Q2aDx$K$*$1$k%9%H%i%$%W>uBO@QKl$NH/8=$H$=$N9=B$(B | Convective assembly method Stripe patterned layer Ordered particle array | S-32 | 496 | |
(16:00$B!A(B17:00)$B!!(B($B:BD9(B $BF#ED(B $B>;Bg(B) | |||||
C322 | $B%+!<%\%s%J%N%A%e!<%V4V$NMOG^$r2p$7$?Aj8_:nMQNO(B-$BJ,;6!&9=B$@)8f$N4pAC8&5f(B- | Carbon nanotube GCMC simulation Solvent averaged force | S-32 | 498 | |
C323 | $B6Q0l>l$K$*$1$k1UE)$N<+H/1?F0(B | self-motion of droplet chemical instability liquid-liquid interface | S-32 | 226 | |
C324 | $B%,%i%9MF4oFb$K$*$1$k3&LL$N<+H/2sE>1?F0$HG($lE>0\(B | spontaneous flow nonlinear dynamics oil/water interface | S-32 | 254 | |
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 | |
$B!cN.BN%W%m%;%9%7%s%]%8%&%`!d(B | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $B5HED(B $B2mE5(B) | |||||
E301 | $B3IYBAe$K7Z$$B+$M$kA!0]>u8GBN$NJ,;6(B | fibriform particle dispersion light particle | S-2 | 188 | |
E302 | $B%I%i%U%H%A%e!<%VIU3IYBAe$K$*$1$k9bG;EY8GBNN3;R$NIbM7!&J,;6FC@-(B | mixing draft-tube dispersion state | S-2 | 509 | |
E303 | $BHsEy29>l$K$*$1$k(BMiscible Viscous Fingering$B$N | Viscous Fingering Hele-Shaw cell nonisothermal | S-2 | 281 | |
(10:00$B!A(B10:40)$B!!(B($B:BD9(B $B?N;V(B $BOBI'(B) | |||||
E304 | 3D-PTV$B$K$h$kYxYBAe$NN.$l>l2r@O(B | Mixing 3D PTV liquid flow velocity | S-2 | 55 | |
E305 | $B%*%/%?%8%C%H$N=[4D;~4VJ,I[$NB,Dj(B | Mixing New type impeller Circulation time | S-2 | 22 | |
F$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!cN3;R!&J4BN%W%m%;%9%7%s%]%8%&%`!d(B | |||||
(9:20$B!A(B10:20)$B!!(B($B:BD9(B $B2CG<(B $B=cLi(B) | |||||
F302 | VOF$BK!$K$h$k(B3$BAjN.BNCf$N1UE)@8@.%7%_%e%l!<%7%g%s(B | emulsion VOF CFD | S-4 | 305 | |
F303 | $BN>C<$r5[<}JI$K;}$D(B1$B | Brownian motion Langevin equation one-dimensional diffusion | S-4 | 384 | |
F304 | DEM-CIP$BK!$K$h$k8GBNHyN3;R7|By1U$N4%Ag5sF0%7%_%e%l!<%7%g%s(B | DEM Drying CFD | S-4 | 75 | |
(10:20$B!A(B11:20)$B!!(B($B:BD9(B $BJ?Ln(B $BGnG7(B) | |||||
F305 | $B9bO'Fb$K$*$1$kJ4N3BN$N5sF0(B | blast furnace rigid plastic analysis mathematical model | S-4 | 320 | |
F306 | $BM7@1%\!<%k%_%j%s%0$K$*$1$kFbIt29EY$NB,Dj$HM=B,(B | Planetary ball mill Grinding DEM | S-4 | 89 | |
F307 | $BN3;R7BHf$NBg$-$$>r7o2<$K$*$1$kN3;R8!:w%"%k%4%j%:%`$N9bB.2=(B | Discrete Element Method Contact Detection Speed-up | S-4 | 81 | |
(11:20$B!A(B12:00)$B!!(B($B;J2q(B $B5HED(B $B1Q?M(B) | |||||
F308 | [$BE8K>9V1i(B] $BJ4BN%7%_%e%l(B-$B%7%g%s$N$5$i$J$kH/E8$N$?$a$K(B | $BJ4:U(B $B%7%_%e%l(B-$B%7%g%s(B $B%a%+%N%1%_%9%H%j(B- | S-4 | 72 | |
(14:40$B!A(B16:00)$B!!(B($B:BD9(B $B1JEg!!Bg(B) | |||||
F318 | $BHyN3;R$N4IFbN.$l$K4X$9$k8&5f(B | fine particle flow structure DDS | S-4 | 921 | |
F319 | $BN3;R72$U$k$$J,$12aDx$K$*$1$kHyN3;RDL2a%b%G%k(B | passage probability percolation simulation | S-4 | 362 | |
F320 | $B<'5$J,N%5!$K$h$k(BFCC$BGQ?(G^:o8:$N3+H/Z2=(B | FCC Catalyst HGMS | S-4 | 15 | |
F321 | $BA!0]AX%U%#%k%?$rMQ$$$?47@-$K$h$kN3;R$NJ,5i(B | fibrous filter inertia classification | S-4 | 420 | |
(16:00$B!A(B17:20)$B!!(B($B:BD9(B $B2!C+!!=a(B) | |||||
F322 | $BEE>l0u2C7?$N?77??edA$K$h$kHyN3;R$N9b@:EYJ,5i(B | $BEE5$1KF08z2L(B $B?edA(B $B<><0J,5i(B | S-4 | 73 | |
F323 | $B<><0%5%$%/%m%s$K$h$k@VE%$NJ,5iFC@-(B | wet cyclone red mud classiffication | S-4 | 608 | |
F324 | $B1s?4J,N%5!$K$h$kHyN3;R$NJ,5i(B | classification centrifuge particle | S-4 | 468 | |
F325 | $BGX052<$K$*$1$k%*%j%U%#%9IU$-N.2<4IFb$NN3;R72$N5sF0(B | stand pipe packed bed flow pattern discharge rate | S-4 | 28 | |
G$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 | |
$B!cJ,N%%W%m%;%9It2q%7%s%]%8%&%`!d(B | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $B9>F,(B $BN50l(B) | |||||
G301 | $B<><0GS1lC&N2%7%9%F%`$K$*$1$k(BCO2$B$N5sF0$K4X$9$k4pAC8&5f(B | carbon dioxide desulfurization desorption | S-6 | 413 | |
G302 | $BMO2rEY%Q%i%a!<%?!<$rMQ$$$?%[%C%WgzItJ,$+$i$N%]%j%U%'%N!<%kN`$NJ,N%@-I>2A(B | Separation process SP Polyphenol | S-6 | 653 | |
G303 | $B;0 | microreactor extraction unsaturated fatty acid ester | S-6 | 534 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $BB<;3(B $B7{90(B) | |||||
G304 | $B%3!<%k%?!<%k5[<}L}$N1UKlJ,N%$KBP$9$kF)2aB%?J(B | coal tar absorption oil liquid membrane separation permeation enhancement | S-6 | 708 | |
G305 | $B%+%j%C%/%9%"%l!<%sM6F3BN$r%-%c%j!<$H$7$?%?%s%Q%/ | calixarene protein liquid membrane | S-6 | 890 | |
G306 | $B4D6-E,1~7?MOG^$K$h$kM-5!;@$NCj=P$H6]BNFG@-(B | extraction ionic liquids lactic acid | S-6 | 112 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $BBgEg(B $BC#Li(B) | |||||
G307 | $BH/9ZF};@$N@:@=$K$*$1$kEE5$F)@OK!$N8!F$(B | electric dialysis lactic acid purification | S-6 | 121 | |
G308 | $B%]%j%9%A%l%sHyN3;R$NEE5$1KF08=>]$H$=$N2r@O(B | Fine particle Classification Electrophoresis | S-6 | 314 | |
G309 | $B3K;@1v4p$r8GDj$7$?%-%l!<%HB?9&@-Kl$N@-G=I>2A(B | radiation-induced graft polymerization nucleic-acid base chelate | S-6 | 634 | |
(13:00$B!A(B13:40)$B!!(B($B:BD9(B $B0BED(B $B7<;J(B) | |||||
G313 | $B%9%j%C%H:Y9&Fb$K$*$1$k%U%i!<%l%s$N1UAj5[Ce$K4X$9$kJ,;R%7%_%e%l!<%7%g%s(B | adsorption MD simulation fullerene | S-6 | 261 | |
G314 | $B%?%s%Q%/ | radiation-induced graft polymerization bead protein binding | S-6 | 639 | |
(13:40$B!A(B14:20)$B!!(B($B:BD9(B $B:XF#(B $B630l(B) | |||||
G315 | $B9bJ,;RKl$N?eCfMOB8%a%?%s$KBP$9$kF)2aFC@-(B | dissolved CH4 polymeric membrane permeation | S-6 | 889 | |
G316 | $BD60!NW3&%W%m%Q%s$K$h$k%P%$%*%(%?%N!<%k$N>J%(%MC&?e%W%m%;%9$N:GE,2=(B | Supercritical Extraction Dehydration Ethanol | S-6 | 171 | |
(14:20$B!A(B15:00)$B!!(B($B:BD9(B $B>>K\(B $BF;L@(B) | |||||
G317 | $B3$?e$+$i$N%,%9%O%$%I%l!<%H$N@8@.$H3$?eG;=LA`:n(B | Gas hydrate desalination | S-6 | 17 | |
G318 | $B4%Ag:`NA$N2hA|FC@-$K$h$k4^?eN($NB,Dj(B | image analysis surface moisture content | S-6 | 324 | |
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 | |
$B!cKlJ,N%!&5[CeMQB?9& | |||||
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $B8M0fED(B $B9/9((B) | |||||
H304 | $B%j%0%K%sM6F3BN$rA06nBN$H$9$kJ,;R$U$k$$C:AGKl(B | Lignin Molecular sieve membrane Rapid pyrolysis | S-7 | 289 | |
H305 | $B?eG.C:2=$K$h$k5[Ce:`@=B$$H$=$NI>2A(B | hydrothermal carbonization carbonaceous adsorbent adsorption | S-7 | 892 | |
H306 | $B%?%s%K%s%2%k$N(BHCl$B%(!<%8%s%0$K$h$k%+!<%\%s%/%i%$%*%2%k:Y9&FC@-$N8~>e(B | wattle tannin carbon cryogel HCl aging | S-7 | 443 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $BK>7n(B $BOBGn(B) | |||||
H307 | $B%a%=%]!<%i%9%7%j%+!>%+!<%\%s%3%s%]%8%C%H$N:Y9&9=B$$H5[CeFC@-(B | mesoporous silica mesoporous carbon silica / carbon composite | S-7 | 600 | |
H308 | CVD$BK!$GD4@=$7$?%7%j%+GvKl$N5$BNJ,N%FC@-(B | CVD silica membrane gas permeation | S-7 | 673 | |
H309 | $B9bBQ5W@-$rM-$9$k%"%k%^%$%H!&%Q%i%8%&%`J#9gGvKl$N:n@.(B | palladium membrane hydrogen | S-7 | 679 | |
(13:00$B!A(B13:40)$B!!(B($B;J2q(B $BLnB<(B $B4490(B) | |||||
H313 | [$BE8K>9V1i(B]$B3H;6B.EY!&3h@-E@J,I[$+$i8+$?%<%*%i%$%H?(G^!&Kl$NFC@-@)8f$N2DG=@-(B | zeolite diffusion active site | S-7 | 42 | |
(13:40$B!A(B14:40)$B!!(B($B:BD9(B $B8E@n(B $B?.0l(B) | |||||
H315 | $B%b%N%j%9;Y;}BN>e$X$N%7%j%+%i%$%HKl$N9g@.$H$=$NFC@-I>2A(B | Silicalite Monolith support Hydrothermal seeding | S-7 | 353 | |
H316 | ZSM-5$BKl$K$h$k9b29$K$*$1$k6K@-J,;R(B/$BL55!%,%9J,N%(B | Zeolite membrane ZSM-5 Gas separation | S-7 | 394 | |
H317 | $B%,%9J,N%Kl%b%8%e!<%k$N9=B$:GE,2=%7%9%F%`$N3+H/(B | Gas separation Structural Optimization Genetic Algorithm | S-7 | 698 | |
(14:40$B!A(B15:20)$B!!(B($B:BD9(B $BLnB<(B $B4490(B) | |||||
H318 | $B5$BNJ,N%Kl%b%8%e!<%k$N9bBQG.2=(B | membrane module hydrogen permselective membrane high heat-resistant | S-7 | 412 | |
H319 | $B4%<><0K!$K$h$j:n@=$7$?B?9& | ceramic capillary porous | S-7 | 417 | |
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!c8:$i$;$4$_$N;3!$AO$j=P$;Ju$N;3!d(B | |||||
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $B86ED(B $B9@9,(B) | |||||
I304 | $B6bB0%$%*%s4T85:Y6]$K$h$k%P%$%*%_%M%i%j% | biomineralization gold recovery | S-21 | 662 | |
I305 | Rhizopus oligosporus$B$K$h$kF<(B($B-6(B)$B%$%*%s$N%P%$%*%=!<%W%7%g%s(B | biosorption copper ion microorganism | S-21 | 398 | |
I306 | $B5.6bB0%j%5%$%/%k%7%9%F%`9=C[$rL\;X$7$?9bA*Br5.6bB0Cj=P:^(BMPTDA$B$N3+H/(B | recycle softness noble metals | S-21 | 967 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $BC]2<(B $B7rFs(B) | |||||
I307 | $B4uN2;@$K$h$k%[%?%F3-FbB!GQ4~J*$+$i$N=E6bB0$N?;=PB.EY(B | $B%&%m(B $B?;=P(B $B4uN2;@(B | S-21 | 5 | |
I308 | $B%[%?%F3-FbB"GQ4~J*$N4uN2;@?;=P1U$+$i$N%j%s%4%8%e!<%9%+%9$K$h$k=E6bB0$N5[Ce!&=|5n(B | $B%&%m(B $B=E6bB0(B $B5[Ce(B | S-21 | 6 | |
I309 | $B%J%H%j%&%`7O5[<}:^$K$h$k%P%$%*%^%9%,%9Cf$N%O%m%2%s2=?eAG$N4%<0=|5n(B | Halides removal Sorbent Biomass gas | S-21 | 431 | |
(13:00$B!A(B13:40)$B!!(B($B;J2q(B $B>oED(B $BAo(B) | |||||
I313 | [$BE8K>9V1i(B]$BG@;:GQ4~J*$NM-8zMxMQ$N | utilization of waste bran husks | S-21 | 181 | |
(13:40$B!A(B14:40)$B!!(B($B:BD9(B $B@n4nED(B $B1Q9'(B) | |||||
I315 | $B3h@-C:$rMQ$$$?%P%$%*%^%9%,%92=%,%9Cf$N?e6d=|5n(B | Biomass Mercury Activated carbon | S-21 | 23 | |
I316 | $BGQL}$r86NA$H$7$?>C2P:^$N@=B$5Z$SJ*@-I>2A(B | waste oil fire-fighting agent recycle | S-21 | 772 | |
I317 | $BL55!J,4^M-%P%$%*%^%9GQ4~J*$N?eG.;@2==hM}$H;q8;2s<}(B | Hydrothermal oxidation Biomass Recycling | S-21 | 937 | |
(14:40$B!A(B15:40)$B!!(B($B:BD9(B $B>e9>='(B $B0lLi(B) | |||||
I318 | $B%3!<%R!<^h$NN.F0AX%,%92=(B | fluidized bed gasification coffee grounds | S-21 | 80 | |
I319 | $B2C059b29=hM}$K$h$kLZ | combined treatment of high pressure and heat waste wood recycled board | S-21 | 831 | |
I320 | $B%P%$%*%^%9%,%92=(BMCFC$BH/EE%7%9%F%`MQ4%<0%,%9@:@=%7%9%F%`$N8&5f3+H/(B | high temperature gas purification biomass gasification MCFC | S-21 | 703 | |
(15:40$B!A(B16:40)$B!!(B($B:BD9(B $BK>7n(B $BOBGn(B) | |||||
I321 | $B0!NW3&?e=hM}$K$h$k@=;f%9%i%C%8$N9ZAGE|2=$N9bB.2=(B | Paper sludge Subcritical water Enzymatic saccarifcation | S-21 | 916 | |
I322 | $B9b299b05?e$K$h$k@=;f%9%i%C%8$N%1%_%+%k%j%5%$%/%k(B | Paper sludge hydrothermal | S-21 | 744 | |
I323 | $B@PL}8:05;DL}$N?75,G.J,2rK!$N3+H/(B | automobile fuel thermal cracking supercritical water | S-21 | 588 | |
J$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 | |
$B!c8:$i$;$4$_$N;3!$AO$j=P$;Ju$N;3!d(B | |||||
(9:00$B!A(B9:40)$B!!(B($B;J2q(B $BCSED(B $B:K(B) | |||||
J301 | [$BE8K>9V1i(B]$B4D6-D4OB7?;:6H0i@.$H;q8;$NM-8z:FMxMQ$K9W8%$9$k%P%$%*%F%/%N%m%8!<$NF08~$HE8K>(B | biotechnology environment resource | S-21 | 13 | |
(9:40$B!A(B11:00)$B!!(B($B:BD9(B $BC0<#(B $BJ]E5(B) | |||||
J303 | $B%3%s%]%9%HCf$G@8J,2r@-%W%i%9%A%C%/$NJ,2r$rC4$&Hy@8J*$NLr3d(B | compost ammonia emission microorganisms | S-21 | 783 | |
J304 | $B9%5$8GAjH?1~Ae$K$*$1$kM-5!@-GQ4~J*$NJ,2rB.EY2r@O(B | compost organic waste rate constant | S-21 | 441 | |
J305 | $B$*$+$i$r4p | Lactic acid fermentation Lactic acid enzyme | S-21 | 849 | |
J306 | $B5{GQ4~J*$NF};@H/9Z$X$N1~MQ(B | Lactic acid fermentation nutrient | S-21 | 450 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B9q4c(B $B9'M:(B) | |||||
J307 | $B5[<}7?Kl>xN1K!$rMQ$$$?%"%_%N;@@8;:$r7s$M$?%"%s%b%K%"4^M-GS?e=hM}%W%m%;%9(B | ammonia recovery membrane wastewater treatment | S-21 | 465 | |
J308 | $BJF86NA$NF};@H/9ZZ;n83(B | Rice Lactic acid Scale-up | S-21 | 242 | |
J309 | $B@8J,2r@-%W%i%9%A%C%/@8;:$K$h$k@8%4%_=hM}%7%9%F%`$N(BLCA | LCA PLA Recycle | S-21 | 742 | |
(14:00$B!A(B15:00)$B!!(B($B:BD9(B $BCf:j(B $B@6I'(B) | |||||
J316 | Direct Fermentation for Lactic Acid Production From Onggok by Streptococcus bovis | Lactic acid onggok streptococcus bovis | S-21 | 592 | |
J317 | $B5!G=@-%]%j%Z%W%A%I:`NA$N3+H/(B | poly-glutamic acid | S-21 | 402 | |
J318 | $B>_L}Gt3h@-C:2=J*$r%+%$%m86NA$H$7$FMxMQ$9$k$?$a$N4pACE*8&5f(B | soy sause cake Warmers activatd char | S-21 | 611 | |
(15:00$B!A(B16:00)$B!!(B($B:BD9(B $BJ?ED(B $B@?(B) | |||||
J319 | $BD68EJF$NM-8zMxMQ$K$h$kF};@@8;:(B | lactic acid fermentation rice | S-21 | 682 | |
J320 | $B6L$M$.$r4p | CH4 Methane fermentation activated carbon | S-21 | 853 | |
J321 | $BG@6HGS?e$N=hM}$K4X$9$k8&5f(B | phosprous adsorption | S-21 | 298 | |
K$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!c%P%$%*%$%a!<%8%s%0$H2=3X9)3X$NM;9g$K$h$k3W?7E*$J%J%N%P%$%*5;=Q$NAO=P!d(B | |||||
(9:00$B!A(B12:00)$B!!(B($B:BD9(B $B0$?,(B $B2mJ8!&@n@>!!E0(B) | |||||
K301 | [$B0MMj9V1i(B]$BK}@-<@45$N?GCG<#NE$N(BDDS$B%$%a!<%8%s%0(B | BioImaging DDS | S-23 | 938 | |
K302 | [$B0MMj9V1i(B]$BAH?%I8E*MQJ,;R$N%G%6%$%s$HAO=P(B | DDS Target | S-23 | 958 | |
K304 | [$B0MMj9V1i(B]$B%$%a!<%8%s%0(BQD$B$N93BN!&9386=$>~(B | Imaging QD Antibody | S-23 | 940 | |
K305 | [$B0MMj9V1i(B]$BLH1V0[>o<@45?GCG5;=Q$N3+H/(B:$B5$F;1j>I(B($BSCB)(B)$BIBBV?GCG%$%a!<%8%s%0(B | Imaging QD Bionano | S-23 | 945 | |
K307 | [$B0MMj9V1i(B] $BNL;R%I%C%H$K$h$kLt:^EAC#$H%H%l!<%7%s%0(B | QD BioImaging | S-23 | 985 | |
K308 | [$B0MMj9V1i(B]$B%P%$%*%J%N%+%W%;%k$rMQ$$$?%T%s%]%$%s%H(BDDS$B$N%P%$%*%$%a!<%8%s%02r@O(B | Bionanocapsule DDS Bioimaging | S-23 | 957 | |
(13:00$B!A(B16:00)$B!!(B($B:BD9(B $B6aF#(B $BL@I'!&NkLZ(B $BOBCK(B) | |||||
K313 | [$B0MMj9V1i(B]$BI=LL=$>~%J%NN3;R9g@.(B | Nanoparticle surface modification supercritical water | S-23 | 956 | |
K314 | [$B0MMj9V1i(B]$BI=LL=$>~<'@-%J%NN3;R$N9g@.(B | DDS Target magnetic | S-23 | 960 | |
K316 | [$B0MMj9V1i(B]$B:YK&5!G=$N%$%a!<%8%s%0(B | BioImaging function cell | S-23 | 948 | |
K317 | [$B0MMj9V1i(B]$B8w3X82Hy6@$*$h$SEE;R82Hy6@$rMQ$$$?%P%$%*%$%a!<%8%s%0(B $B!D0_$r9=@.$9$k:YK&$?$A(B | BioImaging microscope | S-23 | 953 | |
K319 | [$B0MMj9V1i(B]$B%l!<%6!<82Hy6@$rMQ$$$?N.$l;I7c | Lazer BioImaging microscope | S-23 | 946 | |
K320 | [$B0MMj9V1i(B]$B0LAj:982Hy6@$rMQ$$$?%P%$%*%$%a!<%8%s%0(B | BioImaging In-situ microscope | S-23 | 947 | |
(16:00$B!A(B17:00)$B!!(B($B:BD9(B $BK\B?(B $BM5G7(B) | |||||
K322 | $BLO5 | Colloid probe AFM Nano-gel mucin | S-23 | 939 | |
K323 | Green synthetic protocol for metal-oxide nanowires with natural cellulose | Ionic liquid metal-oxide nanowires cellulose | S-23 | 602 | |
K324 | $B$,$s:YK&Kl$rI8E*$H$9$k%O%$%V%j%C%I%j%]%=!<%`$N@)$,$s5!9=(B | hybrid liposomes membrane targeting total internal reflection fluorescence | S-23 | 566 | |
(17:00$B!A(B17:40)$B!!(B($B:BD9(B $B?@C+(B $B=(Gn(B) | |||||
K325 | $B8w%T%s%;%C%H$rMQ$$$??75,IbM7G]M\K!$N9=C[$*$h$SC10l:YK&4Q;!(B | floating cell single cell optical tweezers | S-23 | 583 | |
K326 | TOF-SIMS$B$K$h$k@8BN9bJ,;R$N9=B$2r@OK!$N3+H/(B | TOF-SIMS Spectrum Analysis Bioinformatics | S-23 | 3 | |
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$H1~MQ5;=Q!d(B | |||||
(9:20$B!A(B10:00)$B!!(B($B:BD9(B $B8E20(B $BIp(B) | |||||
L302 | $B>o05$+$i9b05$K$*$1$kF0G4EY$NAj4X!&?d;;K!$NHf3S(B | kinematic viscosity NRTL Wong-Sandler mixing rule | S-27 | 138 | |
L303 | $BD6NW3&Fs;@2=C:AGCf$K$*$1$k(BDibenzo-24-crown-8$B$H%S%?%_%s(BK1$B$N3H;678?t$NB,Dj(B | diffusion supercritical carbon dioxide dibenzo-24-crown-8 | S-27 | 909 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $B>>ED(B $B909,(B) | |||||
L304 | $BM6EEFC@-$K$h$kFs;@2=C:AG$HB>J,;R$H$NJ,;R4VAj8_:nMQ$NI>2A(B | supercritical fluid carbon dioxide charge-transfer complex | S-27 | 763 | |
L305 | $BD6NW3&Fs;@2=C:AG$KBP$9$k%m%8%&%`:xBN$NMO2rEY(B | supercritical carbon dioxide solubility fluoride | S-27 | 321 | |
L306 | $BD6NW3&Fs;@2=C:AG$KBP$9$k%?%-%=!<%k$NMO2rEYB,Dj$HAj4X(B | supercritical carbon dioxide solubility taxol | S-27 | 406 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $BKY@n(B $B0&98(B) | |||||
L307 | FT-IR$B$rMQ$$$??e(B/$B:.9g3&LL3h@-:^(B/$BD6NW3&Fs;@2=C:AG7O$NFb?eAj$N4Q;!(B | Supercritical carbon dioxide Microemulsion FT-IR | S-27 | 637 | |
L308 | UV-vis$BJ,8wK!$rMQ$$$?D6NW3&?e!&Fs;@2=C:AG:.9g7O$K$*$1$kC:;@$N2rN%Dj?t$NI>2A(B | proton concentration supercritical water carbon dioxide | S-27 | 627 | |
L309 | $BD6NW3&?e!<%a%?%N!<%k:.9gN.BNCf$N?eAG7k9g(B:$B | supercritical fluid methanol-water mixture hydrogen bonding | S-27 | 710 | |
M$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 $B9CHe(B $B7IH~(B) | |||||
M302 | [$BE8K>9V1i(B]$B!!Nr;K$H2J3X$+$i8+$?4D6-LdBj$NE8K>(B | Environment Technology Safety | S-30 | 970 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $BDjJ}(B $B@55#(B) | |||||
M304 | $BMOM;%9%i%0Cf$N1t4xH/5sF0$K5Z$\$94T85%,%9$*$h$S8GBN%+!<%\%s$N1F6A(B | molten slag lead evaporation | S-30 | 207 | |
M305 | $BL55!8GBN1vAG2=9gJ*$+$i$N(BCl$B7O%,%9J|=P$K5Z$\$98GBNCf6&B8@.J,$N1F6A(B | hydrogen chloride inorganic chloride gas treatment | S-30 | 218 | |
M306 | $B8:052CG.$K$h$k(BPbCl2$B!"(BZnCl2$B!"(BCuCl$B$N4xH/B.EY2r@O(B | Heavy metal Reduced pressure Volatilization rate | S-30 | 210 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $BN$@n(B $B=EIW(B) | |||||
M307 | $BDc29%W%i%:%^K!$rMxMQ$7$?(BVOCs$BJ,2r5;=Q$N:GE,2=(B | VOCs Nonthermal Plasma Decomposition | S-30 | 544 | |
M308 | $BD6DcM;@-$H9bIuCeFC@-$rM-$9$k%P%J%8%&%`7O1t%U%j!<%,%i%9$N4pACE*8&5f(B | lead-free glass low-melting point glass flat fluorescence lump | S-30 | 219 | |
M309 | $B4D6-Ii2YDc8:2=$rL\;X$7$?(BLi2B4O7-ZnO-BaO$B7OIuCe2C9)MQ1t%U%j!<%,%i%9$N3+H/(B | lead-free glass sealing | S-30 | 230 | |
(13:00$B!A(B14:00)$B!!(B($B:BD9(B $B;3:j(B $B>O90(B) | |||||
M313 | $B@8J,2r@-%W%i%9%A%C%/$rMxMQ$7$?Hn8zD4@a7?HnNA$N;\Hn5;=Q3+H/(B | biodegradable polymer fertilizer Manure efficacy adjustment | S-30 | 20 | |
M314 | $B7A>u$N0c$&%<%*%i%$%H$NEZ>m2~NI:`$H$7$F$NHf3S(B | zeolite water permeability water retention capacity | S-30 | 636 | |
M315 | $BCf9q%"%k%+%jEZ>m$N:n@.$*$h$S=|1v | alkali soil ESP EC | S-30 | 848 | |
(14:00$B!A(B15:00)$B!!(B($B:BD9(B $B9b66(B $B9,;J(B) | |||||
M316 | $BC&N2@P9Q$G$N%"%k%+%jEZ>m2~NI$KH<$&1vN`0\F0I>2A(B | soil ESP alkali | S-30 | 792 | |
M317 | $B4%AgCO?"NS$N$?$a$N9-0hE83+$rL\E*$H$7$?I=LLN.=P%b%G%k$N3+H/(B | runoff afforestation simulation | S-30 | 632 | |
M318 | $BC:AG%"%+%&%s%F%#%s%0%7%9%F%`$r%Y!<%9$H$7$?4%AgCO?"NS%7%_%e%l!<%?(B | Carbon fixation arid land carbon accounting system | S-30 | 497 | |
(15:00$B!A(B16:00)$B!!(B($B:BD9(B $B0KCOCN(B $BOBLi(B) | |||||
M319 | $BFs;@2=C:AG3$MN=hM}$K$*$1$k%9%?%F%#%C%/%_%-%5!<$rMQ$$$?(BCO2$BF3F~K!$N%(%M%k%.!<>CHq(B | CO2 Sequestration Static Mixer Energy dissipation | S-30 | 769 | |
M320 | pH$B%9%$%s%0$rMxMQ$7$??75,(BCO2$BC:;@1v8GDj2=%W%m%;%9$K$*$1$k7P:Q@-I>2A(B | CO2 Sequestration Mineral carbonation | S-30 | 908 | |
M321 | THF$B%O%$%I%l!<%H$rMQ$$$??75,$J:.9g%,%9$NJ,N%K!(B | hydrate hydrogen THF | S-30 | 291 | |
(16:00$B!A(B16:40)$B!!(B($B:BD9(B $B9>F,(B $BLw9,(B) | |||||
M322 | $BN3>u$N6]BN$rMQ$$$??eAGH/9Z$K5Z$\$9A`:n>r7o$N1F6A(B | Hydrogen fermentation Granular sludge Foamed glass bead | S-30 | 440 | |
M323 | $B%(%/%;%k%.!<2r@OK!$r1~MQ$7$?;}B32DG=@-I>2A%D!<%k$K$h$kEENO6!5k%7%9%F%`$N9gM}2=(B | Exergy Sustainability Electricity | S-30 | 965 | |
N$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!c | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $B=ULZ(B $B>-;J(B) | |||||
N301 | $BMOG^OBK!$K$h$k5$1UJ?9U$K$*$1$k1v8z2L$N?d;;(B | vapor-liquid equlibria salt effect solvate | S-1 | 557 | |
N302 | $B?e(B-$B%*%/%?%N!<%k(B-$B%(%?%N!<%k7OCf$G@8@.$9$k%/%i%9%?!<$N | Cluster Phase separation Mass spectrometry | S-1 | 196 | |
N303 | ETBE+$B%a%?%N!<%k(B+$B%X%W%?%s7O$N1U1UJ?9U$NB,Dj$HAj4X(B | liquid-liquid equilibrium correlation ETBE | S-1 | 216 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $BD9ED(B $B=(IW(B) | |||||
N304 | $B%W%m%Q%s%O%$%I%l!<%HFb$KM65/$5$l$?%i%8%+%k$N0BDj@-$K4X$9$k8&5f(B | gas hydrate radical Electron Spin Resonance | S-1 | 427 | |
N305 | $B%a%?%s9=B$(BH$B7?%O%$%I%l!<%H$NJ?9U>uBV2<$K$*$1$kG.NO3XJ*@-(B | Gas Hydrate Structure-H Raman Spectroscopy | S-1 | 293 | |
N306 | $B%"%;%H%K%H%j%k(B+n-$B%X%-%5%G%+%s7O$K$*$1$kN22+@.J,$NJ,G[78?t(B | acetonitrile n-hexadecane partition coefficient sulfur compound oxidative desulfurization | S-1 | 286 | |
(11:00$B!A(B11:20)$B!!(B($B:BD9(B $B:48E(B $BLT(B) | |||||
N307 | 2-$B%G%*%-%7(B-D-$B%0%k%3!<%9$NJQ49H?1~(B | biomass bio-plastic | S-1 | 66 | |
(11:20$B!A(B12:00)$B!!(B($B;J2q(B $B:48E(B $BLT(B) | |||||
N308 | [$BE8K>9V1i(B] PCB$BEyFqJ,2r@-M-5!J*$N?eG.J,2r=hM}5;=Q$N3+H/$H%H%l!<%5$rMQ$$$?N.F02r@O$K$D$$$F(B | S-1 | 1001 | ||
(13:00$B!A(B13:40)$B!!(B($B;J2q(B $B7*86(B $B@6J8(B) | |||||
N313 | [$B>7BT9V1i(B] $BNL;R2=3X7W;;$rMxMQ$7$?AjJ?9U?d;;K!$N8=>u$H9b05NN0h$X$NE83+(B | S-1 | 1003 | ||
(13:40$B!A(B14:00)$B!!(B($B;J2q(B $B7*86(B $B@6J8(B) | |||||
N315 | [$B>7BT9V1i(B] $B;g30!&2D;k5[8wK!$rMQ$$$?D6NW3&Fs;@2=C:AGCf$NMO2rEYB,DjK!$N3+H/(B | S-1 | 1002 | ||
(14:00$B!A(B15:00)$B!!(B($B:BD9(B $B2<;3(B $BM52p(B) | |||||
N316 | 2$B@.J,7ODj05!&Dj295$1UJ?9U%G!<%?$N(BPAI$B%F%9%H$K$h$kI>2A!!%"%k%3!<%k(B+$B%O%$%I%m%+!<%\%s7O!!$=$N(B2 | vapor-liquid equilibrium data evaluation activity coefficient | S-1 | 697 | |
N317 | $B3HD%(BRedlich-Kister$B<0$rMQ$$$?(B3$B@.J,7OMO1U$N%P%l%$$*$h$S%j%C%8$N7hDj(B | Isobaric Vapor-Liquid Equilibrium Valley and Ridge Extended Redlich-Kister eq. | S-1 | 777 | |
N318 | $BMO:^%j%5%$%/%k%W%m%;%9@_7W$KI,MW$J(BNRTL$B%Q%i%a!<%?$N7hDj(B | vapor-liquid equilibria NRTL solvent recycling | S-1 | 140 | |
(15:00$B!A(B16:00)$B!!(B($B:BD9(B $B>>;3(B $B@6(B) | |||||
N319 | $B%[!<%k%I%"%C%WJd=~7?%(%V%j%*%a!<%?$K$h$k(BVLE$B$N7hDj(B | ebulliometer vapor-liquid equilibria vapor hold-up | S-1 | 204 | |
N320 | $B;g302D;kJ,8wK!$K$h$k%U%CAG2=9gJ*$N>:2Z05$NB,Dj$J$i$S$KAj4X(B | fluorine sublimation pressure group contribution | S-1 | 408 | |
N321 | COSMO-RS$BK!$rMQ$$$?>:2Z05?d;;K!$NDs0F(B | prediction sublimation pressure COSMO-RS method | S-1 | 109 | |
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;38}(B $BLT1{(B) | |||||
O301 | DMFC$BH/EEFC@-$K5Z$\$9%a%?%N!<%k%/%m%9%*!<%P!<$N1F6A(B | DMFC Methanol crossover Numerical simulation | S-36 | 316 | |
O302 | $BD>@\%a%?%N!<%k7AG3NAEECS$N$?$a$NGr6b%9%Q%C%?%j%s%0GvAX%+%=!<%I$NFC@-I>2A(B | Direct methanol fuel cell Mass activities Sputter-deposition | S-36 | 342 | |
O303 | Efficient DMFC using high methanol concentration | DMFC neat methanol porous plate | S-36 | 633 | |
(10:00$B!A(B11:20)$B!!(B($B:BD9(B $BCf@n(B $B?B9%(B) | |||||
O304 | $B%P%$%*G3NAEECS$K$*$1$k9ZAG8GDj2=EE6K$N@-G=8~>e$X8~$1$?8!F$(B | biofuel cell enzyme reaction redox polymer | S-36 | 116 | |
O305 | PEFC$BMQA4K'9aB2C:2=?eAG7O:Y9&%U%#%j%s%0EE2r | pore-filling electrolyte membrane aromatic hydrocarbon structure of water | S-36 | 249 | |
O306 | [$B>7BT9V1i(B]$B7HBS5!4oMQG3NAEECS$N3+H/(B | fuel cell | S-36 | 577 | |
(11:20$B!A(B12:00)$B!!(B($B:BD9(B $B9>F,(B $BLw9,(B) | |||||
O308 | $B%a%=%]!<%i%9%+!<%\%s$X$N?(G^6bB0C4;}$H$=$N%"%k%3!<%k;@2=3h@-(B | electrode catalyst mesoporous carbon direct alcohol fuel cell | S-36 | 597 | |
O309 | PtRuRh/C$B?(G^$N9g@.$H$=$N;@2=FC@-(B | electrode catalyst direct alcohol fuel cell | S-36 | 655 | |
(13:00$B!A(B14:00)$B!!(B($B:BD9(B $BGk86L@K<(B) | |||||
O313 | $B?bD>G[8~@-$rM-$9$k6bB0(B-$B%7%j%+J#9gGvKl$N@.Kl2aDx$H%a%=B?9& | mesoporous silica sputtering inorganic composite electrolyte | S-36 | 694 | |
O314 | [$B>7BT9V1i(B] $BG3NAEECSMQEE6K?(G^$N3+H/$N8=>u$H:#8e$N2]Bj(B | Fuel Cell | S-36 | 572 | |
(14:00$B!A(B14:40)$B!!(B($B:BD9(B $BBgM'(B $B=g0lO:(B) | |||||
O316 | $BCf290h$K$*$1$k%j%s4^M-%A%?%K%"J#9gKl$N%W%m%H%sEAF3FC@-$HH/EEFC@-(B | proton conductivity titanium-phosphorus oxide membrane fuel cell | S-36 | 251 | |
O317 | $B9b29:nF0(BPEMFC$BMQ?75,M-5!L55!%O%$%V%j%C%IEE2r | PEMFC hybrid interface | S-36 | 127 | |
(14:40$B!A(B15:40)$B!!(B($B:BD9(B $BETN1(B $BL-N;(B) | |||||
O318 | $B<~4|E*%J%N9=B$%j%s;@%7%j%1!<%HGvKl$N>x5$9g@.$H%W%m%H%sEAF3@-(B | Vapor Infiltration synthesis Proton conductivity Phosphoric silicate | S-36 | 661 | |
O319 | $B9-29EY0h:nF0MQ8GBN9bJ,;R7AG3NAEECSEE6K$N3+H/$H$=$N9=B$@)8f(B | PEFC Hybrid SPES | S-36 | 895 | |
O320 | $B%7%j%+HoJ$(BPt$B%J%NN3;R$rMQ$$$?(BPEFC$BEE6K$NH/EEFC@-(B | Silica-coated Pt nanoparticle PEFC anode electrode catalyst three-phase interface | S-36 | 479 | |
(15:40$B!A(B16:20)$B!!(B($B:BD9(B $B4_ED(B $B>;9@(B) | |||||
O321 | $BGr6b(B-$B6bB0;@2=J*J#9g:`NA$N3+H/$HG3NAEECSMQ?(G^$H$7$F$NFC@-I>2A(B | Metal oxide Catalyst Fuel cells | S-36 | 815 | |
O322 | MRI$BEE2r ($BEl9)BgC:AG=[4D%(%M%k%.!<8&5f%;(B) $B!{(B($B@5(B)$B@nED(B $B7rB@O:!&(B | Polymer electrolyte membrane magnetic resonance imaging water transport | S-36 | 991 | |
P$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 | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $BN-(B $B=f0l(B) | |||||
P301 | $B3&LL3h@-:^MO1U$N%P%-%e!<%`@=I9FC@-(B | Ice Slurry Surfactants Vacuum Production | S-28 | 340 | |
P302 | $B@xG.C_G.$KMQ$$$k%(%j%9%j%H!<%k$N=i4|6E8GB.EYB%?J$K4X$9$k8&5f(B | Erythritol Surface roughness Rate of solidification | S-28 | 328 | |
P303 | $B%*%U%i%$%s2=3XC_G.M"Aw$K$h$kCO0h%(%M%k%.! | Chemical Heat Pump Chemical Heat Stotage Chemical Heat Transportation | S-28 | 886 | |
(10:00$B!A(B11:20)$B!!(B($B:BD9(B $B>.AR(B $BM5D>(B) | |||||
P304 | $BCf29GSG.MxMQ7?%1%_%+%k%R!<%H%]%s%WMQC_G.:`$N3+H/(B | Chemical Heat Pump Magnesium Oxide Heat Storage Material | S-28 | 393 | |
P305 | $BC:AG:`NA$rMQ$$$?%1%_%+%k%R!<%H%]%s%WH?1~AX$NEAG.B%?J(B | Heat transfer enhancement chemical heap pump gas-solid reaction | S-28 | 980 | |
P306 | $B6bB01vB?9&BNJ#9g:`NA$N?e<}Ce5sF0$HC_G.:`$H$7$F$N1~MQ(B | Chemical Heat Pump Calcium Chloride Heat Storage Material | S-28 | 396 | |
P307 | $B?eOB1v%9%i%j!<$rMQ$$$?D4<>%W%m%;%9$N%7%9%F%`8!F$(B | chemical dehumidification hydrated salt slurry | S-28 | 839 | |
(11:20$B!A(B12:00)$B!!(B($B;J2q(B $B5bED(B $B44IW(B) | |||||
P308 | [$BE8K>9V1i(B]$B%G%7%+%s%H6uD45;=Q$N?JJb$H2DG=@-(B | Desiccant Heat exchanger Cogeneration | S-28 | 132 | |
(13:00$B!A(B14:20)$B!!(B($B:BD9(B $BN$@n(B $B=EIW(B) | |||||
P313 | $B%,%9%j%U%H$K$h$k%a%?%s%O%$%I%l!<%H2s<}%7%9%F%`$N2s<}4I2 | methane hydrate gas lift CFD | S-28 | 707 | |
P314 | $BM65/%i%8%+%k | gas hydrate thermal stability electron spin resonance | S-28 | 387 | |
P315 | $B?eAG5[B"9g6bN3;R= | metal hydride packed bed heat and mass transfer | S-28 | 253 | |
P316 | $B%,%9%O%$%I%l!<%H$rMxMQ$7$??eAGCyB"!&M"Aw5;=Q$K4X$9$k4pAC8&5f(B | Gas hydrate Hydrogen Storage | S-28 | 295 | |
(14:20$B!A(B15:40)$B!!(B($B:BD9(B $B?{86(B $BIp(B) | |||||
P317 | $B%i%8%+%k>H | Arrhenius plot Steam refomring Non-equilibrium plasma | S-28 | 52 | |
P318 | $B1UBNC:2=?eAGG3NA$N?e>x5$2~ | steam reforming hydrocarbon catalyst life test | S-28 | 164 | |
P319 | $BFs;@2=C:AG2s<}7?G3NA2~ | steam reforming zero emission calcium oxide | S-28 | 209 | |
P320 | $B%j%A%&%`%7%j%1!<%H$rMQ$$$?%a%?%s$NHsJ?9U2~ | hydrogen lithium silicate methane steam reforming | S-28 | 621 | |
(15:40$B!A(B17:00)$B!!(B($B:BD9(B $BB<>>(B $BIpI'(B) | |||||
P321 | $BDc29GSG.$N%(%M%k%.!<2s@8$rL\E*$H$7$?(BDME$B?e>x5$2~ | dimethyl ether steam reforming kinetics | S-28 | 623 | |
P322 | $B%,%92=@8@.%,%9CfITK0OBC:2=?eAG$NC:AG@O=P$K4X$9$k8&5f(B | Gasification carbon deposition unsaturated hydrocarbon | S-28 | 663 | |
P323 | $B%i%^%sJ,8wK!$NG.2=3X?eAG@=B$K!(BIS$B%W%m%;%9$X$NE,MQ@-8!F$(B | Hydrogen production IS process Raman spectroscopy | S-28 | 784 | |
P324 | $B3$?e$+$i$N?eAG@=B$5;=Q$N3+H/8&5f(B | Sea water Hydrogen production Steam bubbling | S-28 | 807 | |
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 | |
$B!c%W%m%;%9$H8=>]$N%@%$%J%_%/%9$K4X$9$kB?MM$J>pJs$N2r@O$H1~MQ!d(B | |||||
(9:00$B!A(B10:20)$B!!(B($B:BD9(B $BEZ20(B $B3hH~(B) | |||||
S301 | $B3IYBAeFb$NAXN.>l$K$*$1$k:.9g@)8f(B | Chaotic Mixing Laminar Mixing Stirred Vessel | S-18 | 229 | |
S302 | $B%^%$%/%mJ,N%J,5i4o$NA`:n8zN($+$i8+$?N3;RG;EY4uGv8B3&$H(BStokes$B?t$N4X78(B | microchannel shear-induced particle collision Stokes number | S-18 | 727 | |
S303 | Taylor$B12$K$*$1$k%j%_%C%H%5%$%/%k$N%7%_%e%l!<%7%g%s$H8G1UJ,N%$H$N4XO"(B | Taylor vortex Visualization Multi-phase | S-18 | 135 | |
S304 | $BCf6u;eKl7?8B30_I2a4o$K$*$1$k5U@v>r7o$HF)2aN.B+$N4X78(B | ultrafiltration hollow-fiber backflush | S-18 | 545 | |
(10:20$B!A(B11:00)$B!!(B($B;J2q(B $BBg?9(B $BN4IW(B) | |||||
S305 | [$BE8K>9V1i(B]$B%^%$%/%mGH4%Ag$N%@%$%J%_%C%/@)8f(B | drying microwave daynamic control | S-18 | 213 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B5H@n(B $B;KO:(B) | |||||
S307 | $B%,%9:.9g4oFb$NN.F0$*$h$S3H;6FC@-$N?tCM%7%_%e%l!<%7%g%s(B | gas mixing jet numerical simulation | S-18 | 489 | |
S308 | $BH?1~@-F1;~0\F08=>]$K$*$1$k?6F0%Q%?!<%s2r@O$X$N2D;k2=>pJs$H%W%m%;%9>pJs$NE,MQ(B | viscous oscillation exothermic reaction fractal analysis | S-18 | 18 | |
S309 | $BF~8}G;EY$N%Q%?!<%K%s%0$K$h$k%^%$%/%m%A%c%M%kFb$NH?1~A`:n(B | microreactor microchannel patterning | S-18 | 390 | |
(13:00$B!A(B14:20)$B!!(B($B:BD9(B $B:y0f(B $B@?(B) | |||||
S313 | $B%,%9%@%$%J%_%C%/%l!<%6! | Gas Dynamic Laser Porous Ceramic Burner Energy Conversion | S-18 | 951 | |
S314 | $BF}2==E9g%W%m%;%96/2=$N$?$a$ND62;GHHsDj>o>H | ultrasound polymerization process indirect irradiation | S-18 | 354 | |
S315 | $B1}I|?6F07?3IYBAuCV$rMQ$$$?O"B3F}2==E9g$N=E9gFC@-(B | Continuous Emulsion Polymerization Vibrating Mixer Particle Size | S-18 | 232 | |
S316 | $B29EY<~4|A`:n2<$K$*$1$k%W%m%T%l%s;@2=H?1~$N2r@O(B | periodic operation oxidation temperature cycling | S-18 | 337 | |
(14:20$B!A(B15:00)$B!!(B($B;J2q(B $B>>K\(B $B=(9T(B) | |||||
S317 | [$BE8K>9V1i(B]$B?(G^H?1~4o$NHsDj>oA`:n$HH?1~J,N%(B | $B?(G^H?1~(B $BH?1~J,N%(B $BHsDj>oA`:n(B | S-18 | 311 | |
(15:00$B!A(B16:20)$B!!(B($B:BD9(B $BBgB<(B $BD>?M(B) | |||||
S319 | $B<~4|A`:nK!$K$h$k7Z | process intensification periodic operation catalytic reaction process | S-18 | 247 | |
S320 | $B%9%W%l!<%Q%k%9K!$rMQ$$$?HsDj>oA`:n$K$D$$$F$N8&5f(B | non-steady operation spray pulse method alumite plate | S-18 | 501 | |
S321 | $B5<;w0\F0AXH?1~4o$K$*$1$k(BPt/Al2O3$B$G$N(BH2/CO$B:.9g%,%9$N;@2=!=F0E*5sF0$N8!F$!=(B | Simulated Moving Bed Reactor CO Oxidation Pt/Al$2$O$3$ | S-18 | 731 | |
S322 | Significance of system analysis by using Biochemical Systems Theory : Examination of a plant population model as an example | Biochemical Systems Theory Plant population model Sensitivity analysis | S-18 | 333 | |
(16:20$B!A(B17:40)$B!!(B($B:BD9(B $B30NX(B $B7r0lO:(B) | |||||
S323 | $B%U%#%k%?@Z$jBX$($rMQ$$$?%j%_%C%H%5%$%/%kK!$K$h$k%W%i%s%HF1Dj(B | plant identification limit cycle filter | S-18 | 174 | |
S324 | $B%T%?%4%i%9(B3$BBNLdBj$K4p$E$/(BTaylor$B5i?tK!$N@-G=I>2A(B | Taylor series method Superhigh-order accuracy Pythagorean problem of three bodies | S-18 | 335 | |
S325 | Taylor$B5i?tK!$K$h$kF0E*46EY7W;;$N8zN(2=(B | Taylor series method Dynamic sensitivities Biochemical Systems Theory | S-18 | 336 | |
S326 | $B6uD4@_Hw$K$*$1$k< | air-conditioning pressure control simulator | S-18 | 36 | |
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 | |
$B!c7P1D%7%9%F%`$H@=B$%7%9%F%`$NO"7H$HI8=`2=!d(B | |||||
(13:00$B!A(B13:40)$B!!(B($B;J2q(B $B^ | |||||
T313 | [$BE8K>9V1i(B] PSE$B$N;kE@$+$i$_$?%P%C%A%W%m%;%9$N2]Bj$H%l%7%T%(%s%8%K%"%j%s%0(B | batch process process system engineering recipe-engineering | S-19 | 749 | |
(13:40$B!A(B15:00)$B!!(B($B:BD9(B $BKLEg(B $BDwFs(B) | |||||
T315 | [$B>7BT9V1i(B]S88$B | S88 Batch Control | S-19 | 437 | |
T316 | [$B>7BT9V1i(B]ISA S88/S95$B5,3J$N%-%c%C%A%"%C%W(B | Batch control MES standard | S-19 | 434 | |
T317 | [$B>7BT9V1i(B]$B3+H/$+$i9)6H2=$^$G$N%9%T!<%I%"%C%W$rL\;X$7$?6HL3J,@O(B | Recipe Design Activity Model | S-19 | 654 | |
T318 | $B3,AX%P%C%A%W%m%;%9%b%G%k$rMxMQ$7$?:GE,A`:n | hierarchical batch process model operational procedure discrete event system | S-19 | 645 | |
(15:00$B!A(B15:40)$B!!(B($B;J2q(B $B7*K\(B $B1QOB(B) | |||||
T319 | [$BE8K>9V1i(B] $B%G%#%9%/%j!<%H!&%1%_%+%k9)>l$N@_7WO@(B | discrete chemical plant dynamic simulation scheduling | S-19 | 745 | |
(15:40$B!A(B16:20)$B!!(B($B:BD9(B $Bzp8}(B $B9';J(B) | |||||
T321 | [$B>7BT9V1i(B] $B2=3X%a!<%+!<$K$*$1$k7W2h6HL3$N8=>u(B | Supply Chain Management | S-19 | 929 | |
T322 | [$B>7BT9V1i(B] IBM$B$K1w$1$k%5%W%i%$%A%'!<%s%^%M%8%a%s%H(B | Supply Chain Management Logistics Innovation | S-19 | 793 | |
(16:20$B!A(B17:00)$B!!(B($B:BD9(B $B66D^(B $B?J(B) | |||||
T323 | [$B>7BT9V1i(B] $B>pJsO"7H%^%M%8%a%s%H$H%W%m%;%9%7%9%F%`9)3X(B | Process Systems Systems Management Process Innovation | S-19 | 773 | |
$BAm9gF$O@(B | |||||
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 | |
$B!c4D6-D4OB7?MOG^$H$7$F$ND6NW3&N.BN$N4pAC$H1~MQ5;=Q!d(B | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $B:#LZ(B $BBnLo(B) | |||||
U301 | $B%$%*%s8r49(BY$B7?%<%*%i%$%H$K$h$kD6NW3&Fs;@2=C:AG6&B82<$N0[@-BN:.9gJ*$N5[CeJ,N%(B | supercritical carbon dioxide Y-type zeolite adsorption | S-27 | 599 | |
U302 | $B0!NW3&!&D6NW3&?e$K$h$k4;5LN`$N=hM}(B | supercritical water hydrolysis mandarin orange | S-27 | 454 | |
U303 | $BD6NW3&(BCO2$BCj=P$rMxMQ$7$?3AHi$+$i$N%+%m%F%N%$%I@.J,$NJ,N%(B | supercritical CO$2$ extraction carotenoid | S-27 | 735 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $B:4F#(B $B9d;K(B) | |||||
U304 | $BD6NW3&Fs;@2=C:AG$rMQ$$$?Hf=E:9J,N%$K$h$k%9%i%j! | Supercritical carbon dioxide Specific gravity difference separation Silicon | S-27 | 445 | |
U305 | $BLZ:`$N0!NW3&?e2C?eJ,2rH?1~F0NO3X(B | sub-critical water reaction kinetics wood | S-27 | 845 | |
U306 | $B0!NW3&?e$rMQ$$$?JF%?%s%Q%/ | sub-critical water protein decomposition | S-27 | 409 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $BNkLZ(B $B>O8g(B) | |||||
U307 | $BD6NW3&(BCO2$BCf$G$N(BPPE$B%]%j%^!<$N=E9gH?1~(B | PPE CO2 POLYMERIZATION | S-27 | 920 | |
U308 | $BD6NW3&Fs;@2=C:AG$rMQ$$$?4^?;(B/$BH/K"%W%m%;%9$K$h$kL55!!&%]%j%^!<%J%N%3%s%]%8%C%H$NAO@=(B | Supercritical CO2 Nanocomposite Polymer | S-27 | 664 | |
U309 | $BD6NW3&%W%m%Q%N!<%k$K$h$k%]%j%(%A%l%s$NKD=aHfB,Dj(B | supercritical alcohol polyethylene swelling ratio | S-27 | 462 | |
(13:00$B!A(B13:40)$B!!(B($B;J2q(B $B@n?,!!Ao(B) | |||||
U313 | [$BE8K>9V1i(B]$B2!=P5!$rMQ$$$?D6NW3&N.BNMQ$N9)6HMQ%W%m%;%9$N2DG=@-(B | supercritical alcohol extruder silane crosslinked polyethylene | S-27 | 185 | |
(13:40$B!A(B14:20)$B!!(B($B:BD9(B $BEOn5(B $B8-(B) | |||||
U315 | $B0!NW3&?e$rMxMQ$7$?%"%k%-%k%0%j%;%j%k%(!<%F%k$N9g@.$*$h$S9)6H2=(B | subcritical water hydration surfactant | S-27 | 709 | |
U316 | $B?)IJ;D^V$ND6NW3&?e%,%92=%W%m%;%9$N3+H/(B | municipal wastes supercritical water gasification | S-27 | 802 | |
(14:20$B!A(B15:00)$B!!(B($B:BD9(B $BFbED!!Gn5W(B) | |||||
U317 | $BD6NW3&?eH?1~MQ%A%?%sFbD%:Y4I$N3+H/-6(B | SuperCriticalWater TitaniumLining DobleTube | S-27 | 304 | |
U318 | $BD6NW3&?eCfG3>FAuCV$K$*$1$k:`NA$NIe?)3d$l;n83(B | SCWO Livestock excrement Clean combustion | S-27 | 614 |