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 $B:4Ln(B $B5*>4(B) | |||||
A201 | $B%K%C%1%k$r%$%*%s8r49C4;}$7$? | Carbon Nanosphere Ion Exchange Resin Nickel | S-33 | 819 | |
A202 | $B%J%NN3;R$N<+8JAH?%7A@.$HC1AX%+!<%\%s%J%N%A%e!<%V@.D9$N?(G^85AG4V$NHf3S(B | single-walled carbon nanotubes nanoparticle catalyst combinatorial method | S-33 | 754 | |
A203 | $BC1AX%+!<%\%s%J%N%A%e!<%V9g@.;~$N(BCoMo$B?(G^$N9=B$JQ2=$H?(G^3h@-$N%a%+%K%:%`(B | single-walled carbon nanotube nanoparticle self-organization | S-33 | 767 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $BLnED(B $BM%(B) | |||||
A204 | $B1UBNCbAGCf%"!<%/J|EE$K$h$k6bB0C4;}%+!<%\%s%J%NN3;R$N@8@.$K4X$9$k8&5f(B | carbon nanoparticle arc discharge catalyst support | S-33 | 193 | |
A205 | $B1U%Q%k%9%$%s%8%'%/%7%g%sK!$rMQ$$$?7>AGJq4^%+!<%\%s%J%N%U%!%$%P!<$N@=B$(B | Carbon nanofiber Liquid pulse injection technique oxidation resistance | S-33 | 446 | |
A206 | $BCbAG4^M-(BTiO2$BGvKl$NAO@=$HFC@-I>2A(B | photocatalyst thin film N-doped TiO2 | S-33 | 433 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $BCf@n(B $B9@9T(B) | |||||
A207 | $B5$Aj9g@.K!$K$h$k%a%=%]!<%i%9%7%j%+GvKl$N9=B$@)8f(B | mesoporous silica film vapor phase synthesis GISAXS | S-33 | 191 | |
A208 | DNA$B$rMQ$$$??75,B?9&@-%7%j%+$N9g@.(B | DNA mesoporous silica | S-33 | 288 | |
A209 | $BD62;GH>H | Zirconia paraffin porous material | S-33 | 167 | |
(14:40$B!A(B15:40)$B!!(B($B:BD9(B $BEVLJ(B $BFF:H(B) | |||||
A218 | $B%i%C%+!<% | magnetic nanobeads laccase enzymatic reaction | S-33 | 604 | |
A219 | $BL55!%J%NN3;R$GHoJ$$7$?(BO/W$BF}2=E)$ND4@=$H$=$NFC@-(B | nanoparticle coating calcium carbonate nanocapsule | S-33 | 683 | |
A220 | $B5UAjJ,;67O$rMxMQ$7$?(BpH$B;I7c1~Ez@-@wNA$N%^%$%/%m%+%W%;%k2=$K4X$9$k8&5f(B | microcapsule pH-sensitive material reverse dispersion | S-33 | 616 | |
B$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!c4D6-!&>l$N%W%m%;%C%7%s%0@)8f$K$h$k9bJ,;R:`NA$N5!G=AO=P!d(B | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $B5HED(B $B>;90(B) | |||||
B201 | $B>C<:7?C4;}BN$rMQ$$$?5!G=@-%j%0%K%s7O9bJ,;R$NC` | lignophenol reaction support heterogeneous reaction | S-31 | 814 | |
B202 | $B8w1~Ez@-9bJ,;R%2%k$rMQ$$$?%^%$%/%m%A%C%W>e$NN.BN@)8f(B | photoresponsive polymer gel microvalve microchannel | S-31 | 203 | |
B203 | $B4629@-%]%j%^!<$rMQ$$$?29EY%9%$%s%0$K$h$k=E6bB0$N5[!&C&CeFC@-(B | thermosensitive polymer adsorption temperature swing | S-31 | 356 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $B;38}(B $BLT1{(B) | |||||
B204 | NO$B%I%J!<$N%^%$%/%m%+%W%;%k2=$K$h$k(BGas Delivery System$B$N9=C[(B | Gas Delivery System NO donor Poly(succinimide) | S-31 | 681 | |
B205 | $B9bJ,;R%2%k7?(BDNA$B%A%C%W$N4pHW$H$7$F$N(Bsemi-IPN$B%2%k$NFC@-(B | semi-IPN gel N-isopropylacrylamide DNA chip | S-31 | 456 | |
B206 | N-$B%$%=%W%m%T%k%"%/%j%k%"%_%I%2%k$rMQ$$$?29EY%9%$%s%05[CeK!$K$h$k6b$NG;=L(B | N-isopropylacrylamide Temperature swing adsorption Gold ion | S-31 | 318 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B1v@9(B $B900lO:(B) | |||||
B207 | $BHsBP>N4629@-FsAX9=B$%2%k$N9g@.$H$=$N6~6JFC@-(B | Thermosennsitive gel two-layer structure bending behavior | S-31 | 692 | |
B208 | [$BE8K>9V1i(B] $BF3EE@-9bJ,;R$K$h$k%=%U%H%"%/%A%e%(!<%?$N3+H/(B | S-31 | 990 | ||
(14:40$B!A(B16:00)$B!!(B($B:BD9(B $BHS_7(B $B9';J(B) | |||||
B218 | $B6bB0%$%*%s5[Ce%]%j%"%/%j%k;@$NAj5sF0$H?FAB?e@-(B | Gel Polymer-metal complex Adsorption | S-31 | 503 | |
B219 | $B%?%s%K%s(B/$BL55!J#9gBN$N%j%s;@%$%*%s5[Ce5!9=(B | tannin phosphate recovery | S-31 | 248 | |
B220 | pH-$B29EY1~Ez@-B?9& | thermosensitive gel adsorption phosphoric acid | S-31 | 478 | |
B221 | $B%^%$%/%m%+%W%;%k2=C&Cb:Y6]$rMxMQ$9$k9b8zN(>t?e%7%9%F%`$N3+H/(B | denitrifying bacteria microencapsulation nitrate nitrogen | S-31 | 9 | |
C$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!c5!G=@-7k>=$N3+H/$H>=@O5;=Q!d(B | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $BBl;3(B $BGn;V(B) | |||||
C201 | $BIT=cJ*5Z$SB?7A@)8f$K$h$k9bLtM}3h@-2=9gJ*$N@=B$%W%m%;%9$N4JN,2=(B | crystallization purification polymorphism | S-35 | 556 | |
C202 | $BE`7k@=Lt$K$*$1$kI97k>=%b%k%U%)%m%8!<$N@)8f(B-$BD62;GH$rMQ$$$?3K7A@.$N@)8f$K$h$k(B- | ice crystal crystallization freezing | S-35 | 643 | |
C203 | $B%^%$%/%mGH>H | Crystallization Micro wave Drug substance | S-35 | 782 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $B9uC+(B $B@5Gn(B) | |||||
C204 | $BD62;GH$K$h$k3K2=8=>]$N2rL@!!3K2=B%?J$KMW$9$k>H | Sonocrystallization Primary nucleation Aspirin | S-35 | 130 | |
C205 | $B%+%F%-%s$*$h$S%(%T%+%F%-%s$H&B%7%/%m%G%-%9%H%j%s$NJq@\7k>=$N9=B$$*$h$S@.D9B.EY(B | crystallization beta-cyclodextrin catechin | S-35 | 809 | |
C206 | $BNd5Q!&2CG.AH$_9g$o$;A`:n$rMQ$$$?2sJ,>=@O$N7k>=N37BJ,I[$N%b%G%k2=(B | Batch crystallization Crystal size distribution Temperature control | S-35 | 4 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B;3K\(B $B1QFs(B) | |||||
C207 | KDP$BC10l7k>=$N@.D9B.EY$H6bB0%$%*%sIT=cJ*$NJ,G[$K$D$$$F(B | KDP crystallization impurity distribution | S-35 | 16 | |
C208 | $B>=@OESCf$NL$K0OBA`:n$,N37BJ,I[$K5Z$\$91F6A$H$=$NI>2A(B | Crystallization Undersaturation CSD | S-35 | 436 | |
$BAm9gF$O@(B | |||||
$B!c<+8JAH?%2=%W%m%;%9$H2=3X9)3X!d(B | |||||
(14:40$B!A(B15:20)$B!!(B($B;J2q(B $B;0Bp(B $B5AOB(B) | |||||
C218 | [$BE8K>9V1i(B]$B;~6u4VCa=x$rAOB$$9$kJ* | self assembly self-organization | S-32 | 729 | |
(15:20$B!A(B16:00)$B!!(B($B:BD9(B $B4];3(B $BC#@8(B) | |||||
C220 | $B%j%s;i | W/O microemulsion Phospholipid Fluorescence analysis | S-32 | 477 | |
C221 | $BHs%$%*%s@-3&LL3h@-:^(BSpan80$B%Y%7%/%k$N9=B$$H$=$NFC@-(B | Span80 Vesicle Non-ionic surfactant | S-32 | 836 | |
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 | |||||
(9:40$B!A(B11:00)$B!!(B($B:BD9(B $B8eF#(B $BK.>4!&>>2<(B $BMN2p(B) | |||||
D203 | $B%^%$%/%mGH>H | microwave irradiation dehydration | S-5 | 598 | |
D204 | $B;@AGG3>F>l$K$*$1$k9b<~GHM6F3Bg5$05%W%i%:%^$NFC@-I>2A(B | oxy-combustion radio heating atomospheric pressure plasma | S-5 | 668 | |
D205 | $B3&LL3h@-:^$rE:2C$7$??eOBJ*%9%i%j!<$NN.F0FC@-(B | Hydrate Slurry Drag Reduction Rheological Characteristics | S-5 | 332 | |
D206 | $B4D>u%0%i%K%e%i!<%U%#%k%?!<$N=8?P8zN( | granular filter dust particle DEM | S-5 | 151 | |
(11:00$B!A(B11:40)$B!!(B($B;J2q(B $B2#ED(B $B | |||||
D207 | [$B>7BT9V1i(B]$BG.EEH/EE$N8=>u$H>-Mh(B | Thermal Engineering | S-5 | 422 | |
(14:40$B!A(B15:20)$B!!(B($B;J2q(B $BEDG7>e(B $B7r0lO:(B) | |||||
D218 | [$B>7BT9V1i(B]$BLZ-Mh$NE8K>(B | Thermal Engineering | S-5 | 421 | |
(15:20$B!A(B17:40)$B!!(B($B:BD9(B $B>>2<(B $BMN2p!&2#ED(B $B | |||||
D220 | $BLZ | woody biomass pyrolysis heat flow | S-5 | 942 | |
D221 | $BFsr7o2<$G$NG3>FFC@-(B | fuel rich secondary fuel soot | S-5 | 717 | |
D222 | $B3F | Coal Combustion Drop Tube Furnace CFD | S-5 | 532 | |
D223 | $B@PC:%A%c! | radiation char extinction efficiency | S-5 | 214 | |
D224 | $B>&MQ%"%W%j%1!<%7%g%s$rMxMQ$7$?HyJ4C:G3>F$N?tCM2r@O(B | pulverized coal firing numerical analysis | S-5 | 723 | |
D225 | $BC(7?%^%k%A%P!<%JO'Fb$K$*$1$kHyJ4C:G3>F?tCM%7%_%e%l!<%7%g%s(B | pulverized coal combustion computational fluid dynamics carbon in ash | S-5 | 77 | |
D226 | $BHyJ4C:%\%$%i$K$*$1$kCe2PFC@-$N?tCM2r@O$K$h$kI>2A(B | coal-combustion radiation simulation | S-5 | 790 | |
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 $B;3:j(B $B5H0l(B) | |||||
E201 | $BL8?a$-$O$J$e$2$k$N$+!!!=(B $BC+0lO:@b$N | Atomizer Bernoulli$B!G(Bs theorem Air flow pattern | S-2 | 269 | |
E202 | $BJ,3d!&:F9gN.7?%^%$%/%m%_%-%5!<$K$*$1$kN.F0FC@-(B | Micromixer Pressure drop correlation Residence time distribution | S-2 | 95 | |
E203 | $B%N%s%(%l%a%s%H%_%-%5!<$N:.9gFC@-(B($BBh(B2$BJs(B) | static mixer visualization mixing pattern | S-2 | 241 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $BK>7n(B $B2mJ8(B) | |||||
E204 | $B$i$;$s7?%^%$%/%m%A%c%s%M%k$K$*$1$kN3;R$H1UBN$NJ,N%(B | microchannnel separation simulation | S-2 | 114 | |
E205 | MRI$B$rMQ$$$?J#;(N.BN$N4IFbN.$l$K$*$1$kN.B.B,Dj(B | Magnetic resonance imaging complex fluid velocity measurement | S-2 | 954 | |
E206 | $BEE5$Dq93%H%b%0%i%U%#!< | electrical resistance tomography mixing gas-liquid system | S-2 | 505 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B2CF#(B $BDw?M(B) | |||||
E207 | $B%?!<%S%sMcLL>e$N05NOJ,I[$K$*$h$\$91UG4EY$N1F6A(B | mixing axial flow impeller pressure distribution | S-2 | 149 | |
E208 | $B1U1U7O3IYBAe$K$*$1$k1UE)J,;65sF0$K5Z$\$9J,;6AjG;EY$N1F6A(B | Liquid-Liquid Dispersion Steric Stabilizers Dispersed Phase Concentration | S-2 | 507 | |
E209 | $BMm$_9g$$D>:?>u9bJ,;R$N9=@.J}Dx<0(B | Polymer dynamics Entanglement Rheology | S-2 | 30 | |
(14:40$B!A(B15:20)$B!!(B($B;J2q(B $B>e%N;3(B $B<~(B) | |||||
E218 | [$BE8K>9V1i(B]$B$I$3$^$G9T$1$k!)!!5$1U:.AjN.2r@O(B | CFD Two-phase flow | S-2 | 988 | |
(15:20$B!A(B16:20)$B!!(B($B:BD9(B $B9b66(B $B9,;J(B) | |||||
E220 | $BHs%K%e!<%H%sG4@-1U$K$*$1$k1}I|F05$1U3IYBMc$NF0NOFC@-(B | Non-Newtonian fluid Aerated mixing Power consumption | S-2 | 885 | |
E221 | $B | unbaffled agitated vessel unsteadily rotating impeller gas-liquid mass transfer | S-2 | 877 | |
E222 | $B1}I|?6F03IYB$K$*$1$k:.9g5!9=$HIT0BDjB?MMBN(B | fluid mixing unstable manifolds mixing mechanism | S-2 | 117 | |
(16:20$B!A(B17:00)$B!!(B($B:BD9(B $B0f>e(B $B5AO/(B) | |||||
E223 | $B1}I|F0Mc | unbaffled agitated vessel unsteadily rotating impeller solid-liquid mass transfer | S-2 | 879 | |
E224 | $BHsDj>o3IYB$K$h$k8G1U:.9g(B | unsteady operation solid-liquid mixing dissolution-time | S-2 | 202 | |
F$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!cN3;R!&J4BN%W%m%;%9%7%s%]%8%&%`!d(B | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $B2<:d(B $B8|;R(B) | |||||
F201 | $B?75,J.L8G.J,2rK!$K$h$kCV497?%9%T%M%k%j%A%&%`%^%s%,%sJ#9g;@2=J*%J%NN3;R$N9g@.(B | Spray pyrolysis Lithium-ion battery Cathod | S-4 | 69 | |
F202 | $BG.J,2r2aDx$K$*$1$k8GBNG3NAN3;RFb$N05NO5sF0(B | pressure measurement thermal decomposition particle | S-4 | 223 | |
F203 | $BL5 | circulating fluidized bed powder dispersion Froude number | S-4 | 979 | |
(10:00$B!A(B11:20)$B!!(B($B:BD9(B $BCfN$!!JY(B) | |||||
F204 | $BBg>.Fs@.J,N3;R7O%I%i%U%H%A%e!<%VIU$-(BSpout-Fluid Bed$B$NN.F0FC@-(B | spout-fluid bed pressure fluctuation gas bypassing | S-4 | 29 | |
F205 | $B8:052aG.?e>x5$N.F0AX4%AgFC@-$K5Z$\$9A`:n>r7o$N1F6A(B | superheated steam fluidized bed drying porous particles | S-4 | 521 | |
F206 | $B8G5$N.F0AX$rMQ$$$?2HEE%7%e%l%C%@!<%@%9%HFb$N1vAG4^M-%W%i%9%A%C%/$NJ,N%(B | Fluidized Bed Home Electric Appliance Shredder Residue Gravity Separation | S-4 | 944 | |
F207 | $B8G1UN.F0AX$K$h$kL)EY:9J,N%(B | Fluidized Bed Solid Waste Sparation | S-4 | 155 | |
(11:20$B!A(B12:00)$B!!(B($B;J2q(B $BN)85(B $BM:<#(B) | |||||
F208 | [$BE8K>9V1i(B] $BGQ4~J*%j%5%$%/%k$N$?$a$N4%<0Hf=EJ,N%5;=Q$N | fluidized bed waste gravity separation | S-4 | 189 | |
(14:40$B!A(B15:20)$B!!(B($B;J2q(B $BBgC+(B $B5H@8(B) | |||||
F218 | [$BE8K>9V1i(B] $B%;%a%s%H@=B$J,Ln$K$*$1$k;q8;%j%5%$%/%k5;=Q(B | $B%j%5%$%/%k(B $B%;%a%s%H(B $B>J%(%M%k%.(B- | S-4 | 71 | |
(15:20$B!A(B16:00)$B!!(B($B:BD9(B $B;3K\(B $BE0Li(B) | |||||
F220 | $B4IFb8G5$FsAjN.$K$*$1$kN3;R$N5sF0$HBSEE$KH<$&EE5$?.9f$N2r@O(B | Gas-solids pipe flow Particle charging Charge transfer | S-4 | 31 | |
F221 | AFM$B$rMQ$$$?HyN3;R$NEE>lCf$K$*$1$k@\?(BSEE$N2r@O(B | Atomic Force Microscope Contact Electrification Electric Potential | S-4 | 606 | |
(16:00$B!A(B17:00)$B!!(B($B:BD9(B $B>>:d(B $B=$Fs(B) | |||||
F222 | $BGQ4~J*7O3J;R;@AG$K$h$kC:2=?eAG=hM}$K4X$9$k8&5f(B | Lattice Oxygen Waste Metal Oxide Gasification | S-4 | 224 | |
F223 | Mechanochemical synthesis of Mg-Al-OH hydrotalcite | mechanochemical hydrotalcite synthesis | S-4 | 380 | |
F224 | $BD62;GH>H | ultrasonic disaggregation nano-sized crystalline particles | S-4 | 590 | |
G$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!cN3;R!&N.BN7O%U%m%s%F%#%"J,N%5;=Q$NE83+!d(B | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $BCfB<(B $B0lJf(B) | |||||
G201 | $B%@%$%J%_%C%/8B30_I2a$K$h$k%U%_%s;@$N=|5nFC@-(B | humic acid ultrafiltration rejection | S-8 | 925 | |
G202 | $B%;%i%_%C%/%9B?9&BN>e$K7A@.$7$?%@%$%J%_%C%/Kl$K$h$kMO2r@-%U%_%s;@MO1U$NDj058B30_I2a(B | porous ceramics humic acid ultrafiltration | S-8 | 411 | |
G203 | $B?eMO2=(BCdSe$B%J%NN3;R$NKl$m2a=hM}(B | nano-particle membrane filtration CdSe | S-8 | 936 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $BJR6M(B $B@?G7(B) | |||||
G204 | $B%^%$%/%mN.BN%G%P%$%9$rMQ$$$?HyN3;RO"B3J,5i$N$?$a$N(BPFF$B$N2~NI(B | microfluidic device pinched flow fractionation continuous separation | S-8 | 983 | |
G205 | $B%J%NN3;R$+$i$J$k_I2a%1!<%/$N9=B$$K5Z$\$9EE>l$HD62;GH$N8z2L(B | ultrafiltration electric field ultrasonic | S-8 | 924 | |
G206 | $BN.F0EE0LK!$K$h$k$m2a%1!<%/AX$NN3;R4V4V7d$NI>2A(B | $BN3;R4V4V7d(B $BI=LL2YEE(B $B@:L)$m2a(B | S-8 | 828 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B;TB<(B $B=E=S(B) | |||||
G207 | $BEE>l2<$N05L)D@9_2aDx$N2r@O(B | Solid-Liquid Separation Electroforced Sedimentation Current Density | S-8 | 33 | |
G208 | $B%=%U%H$*$h$S%O!<%I%3%m%$%I$N1s?4Ib>e!&D@9_$*$h$S05L)FC@-(B | consolidation flotation sedimentation | S-8 | 841 | |
G209 | $B9b5[?e@-%2%kN3;R$K$h$k%j%0%K%s?eMO1U$NG;=L$*$h$S1s?4C&?eFC@-(B | superabsorbent hydrogel centrifugal drainage lignin | S-8 | 399 | |
(14:40$B!A(B15:40)$B!!(B($B:BD9(B $B8~0f(B $B9/?M(B) | |||||
G218 | $B%K%e!<%i%k%M%C%H%o!<%/$rMQ$$$?05=L!&F)2aFC@-$N?dDj(B | Solid-Liquid Separation Specific Filtration Resistance Compression Permeability Test | S-8 | 32 | |
G219 | $B%m!<%?%97?%]!<%i%96bB0$N1UF)2aFC@-(B | water permeability porous metal pressure drop | S-8 | 874 | |
G220 | $B%^%$%/%m%A%c%M%k$K$*$1$k1U!9FsAjN.$NN.F0>uBV(B | microchannel interface stability | S-8 | 811 | |
(15:40$B!A(B16:40)$B!!(B($B:BD9(B $BF~C+(B $B1Q;J(B) | |||||
G221 | Taylor-Couette$BN.$rMxMQ$7$?1U!98~N.7?1s?4Cj=PAuCV$N3+H/(B | Taylor vortex extraction counter-current | S-8 | 968 | |
G222 | $BD62;GHL82=$K$h$k%$%=%W%m%T%k%"%k%3!<%k?eMO1U$NG;=LJ,N%(B | Ultrasonic atomization IPA separation | S-8 | 1 | |
G223 | $BD62;GHL82=J,N%$K$*$1$kL82=NL$NA}Bg0x;R(B | Ultrasonic atomization Atomization rate Separation | S-8 | 2 | |
H$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 | |
$B!c5[Ce!&%$%*%s8r49$,;Y$($k4D6-!&%(%M%k%.!<5;=Q!d(B | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $BNS!!=g0l(B) | |||||
H201 | $B05NO2s<}7?(BPSA$B$N3+H/(B | adsorption PSA pressure recovery | S-9 | 850 | |
H202 | $B%N!<%P!<%8(BVPSA$BK!$K$h$k(BVOC$B$N2s<}(B | Adsorption VOC VPSA | S-9 | 331 | |
H203 | Dual Reflux PSA$B$K$h$kDcG;EY(BVOC$B$N6E=LJ,N%(B | Pressure swing adsorption Dual Reflux PSA VOC | S-9 | 734 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $B;y6L(B $B> | |||||
H204 | $B%O%$%V%j%C%H5[Ce:^$N3+H/(B | Adsorption VOC Adsorbent | S-9 | 325 | |
H205 | $BDc29(BKOH$BIj3hC:$N:Y9&9=B$!"?e>x5$5[CeFC@-$KM?$($k86NA%3!<%/%9@->u$N1F6A(B | Properties of coke Activated carbon KOH chemical activation | S-9 | 330 | |
H206 | $B5[Ce%R!<%H%]%s%W%5%$%/%k;n835!$K$h$k?7:`NAI>2A(B | zeolite Adsorption Heat pump | S-9 | 120 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B7&ED(B $B8w9((B) | |||||
H207 | $B%P%$%*%^%9;q8;$r86NA$H$7$?LtIJIj3hK!$K$h$k9bHfI=LL@Q3h@-C:$ND4@=$H4D6->t2=$X$N1~MQ(B | adsorption activated carbon biomass | S-9 | 453 | |
H208 | $BLZ | molecular sieving carbon biomass adsorption | S-9 | 451 | |
H209 | $B29EY%9%$%s%05[Ce$K$h$kB?@.J,:.9g5$BN$NJ,N%(B | adsorption TSA gas separation | S-9 | 718 | |
$B!cKlJ,N%!&5[CeMQB?9& | |||||
(14:40$B!A(B15:20)$B!!(B($B;J2q(B $BK>7n(B $BOBGn(B) | |||||
H218 | [$BE8K>9V1i(B]$BB?9&@-6bB0:xBN$N5[Ce:`$*$h$SJ,N%:`$X$NE,MQ$K4X$9$kE8K>(B | adsorbent metal complex porous material | S-7 | 593 | |
(15:20$B!A(B16:20)$B!!(B($B:BD9(B $B9b1)(B $BMN=<(B) | |||||
H220 | $BEtL}5[CeC&N2$K$*$1$k8GBN;@7OC&N2:^ | adsorption desulfurization kerosine | S-7 | 350 | |
H221 | $B?75,%G%s%I%j%^! | dendrimer membrane carbon dioxide | S-7 | 172 | |
H222 | $B%G%s%I%j%^! | carbon dioxide separation in-situ composite membrane formation | S-7 | 299 | |
(16:20$B!A(B17:20)$B!!(B($B:BD9(B $B9CHe(B $B>HI'(B) | |||||
H223 | $B2YEEKl$K$h$kEE2r | nanofiltration ion separation molecular dynamics | S-7 | 475 | |
H224 | $BJ,;R%7%_%e%l!<%7%g%s$K$h$kI=LL=$>~%a%=%]!<%i%9%7%j%+Fb$N5[Ce5sF0$N2r@O(B | adsorption molecular simulation mesoporous silica | S-7 | 685 | |
H225 | $B7W;;2=3XE* | zeolite diffusivity molecular dynamics | S-7 | 235 | |
I$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 | |
$B!c>xN1Ec$*$h$S%W%m%;%9$N>J%(%M%k%.!<2=$K8~$1$F!d(B | |||||
(9:00$B!A(B9:40)$B!!(B($B;J2q(B $BCf4d(B $B>!(B) | |||||
I201 | $B%h!<%m%C%Q$K$*$1$k(BHIDiC$B8&5f$N8=>u(B | S-11 | 1005 | ||
(9:40$B!A(B10:20)$B!!(B($B:BD9(B $B>.?{(B $B?M;|(B) | |||||
I203 | $BFbItG.8r49$K$h$k>J%(%M>xN15;=Q3+H/$N?d?J(B | HIDiC Heat Intergrated Distillation Column Energy saving | S-11 | 574 | |
I204 | $BFbItG.8r497?>xN1Ec(B(HIDiC)$B$N%Q%$%m%C%H%W%i%s%H$N>J%(%M1?E>7k2L(B | HIDiC Distillation Energy Saving | S-11 | 119 | |
(10:20$B!A(B11:20)$B!!(B($B:BD9(B $B>>ED(B $B7=8g(B) | |||||
I205 | $B= | HIDiC Distillation rough design | S-11 | 835 | |
I206 | $BFbItG.8r497?>xN1Ec(B(HIDiC)$B$NJ?9UCJ%b%G%k$*$h$SB.EYO@%b%G%k$N9=C[$H2r@O(B | heat-integrated distillation column multicomponent separation rate-based model | S-11 | 642 | |
I207 | $B%W%l!<%H%U%#%s7?(BHIDiC$B$K$h$k6u5$$N>xN1(B | HIDiC cryogenic distillation air separation | S-11 | 901 | |
(11:20$B!A(B12:00)$B!!(B($B:BD9(B $B4dJI(B $B9,;T(B) | |||||
I208 | $B>xN1Ec$K$*$1$kHtKwF1H<$N5sF0(B | distillation entrainment residence time | S-11 | 766 | |
I209 | $B6bB05,B'= | mass transfer coefficient structured packing distillation | S-11 | 867 | |
(14:40$B!A(B15:20)$B!!(B($B:BD9(B $BKYFb(B $B6QJ?(B) | |||||
I218 | $BJ#?tEc4V$NFbItG.8r49K!$K$h$k>J%(%M>xN1%7%9%F%`(B | distillation energy-saving heat integration | S-11 | 7 | |
I219 | $BFbItG.8r497?>xN1Ec$NB?=EDj>o>uBV$K4X$9$k8!F$(B | distillation multiple steady state | S-11 | 262 | |
(15:20$B!A(B16:00)$B!!(B($B:BD9(B $BCf@>(B $B=S@.(B) | |||||
I220 | $BFbItG.8r497?>xN1Ec(B(HIDiC)$B$N%b%G%j%s%0$H%W%m%;%9@_7W(B | heat integration energy-saving rate-based model | S-11 | 629 | |
I221 | $BFbItG.8r497?>xN1Ec(B(HIDiC)$B5;=Q3+H/$N:#8e$NE83+(B | HIDiC energy-saving perspective | S-11 | 646 | |
(16:00$B!A(B16:20)$B!!(B($B;J2q(B $BCf4d(B $B>!(B) | |||||
$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 $BK\4V(B $BE/M:(B) | |||||
L201 | Development of selective hydrogenation using a catalytic membrane reactor in supercritical CO2 | supercritical CO$2$ membrane reactor hydrogenation | S-27 | 514 | |
L202 | $BD6NW3&Fs;@2=C:AGCf$G$NC4;}6bB0?(G^$K$h$k%Y%s%8%k%"%k%3!<%kN`$NItJ,;@2=H?1~(B | partial oxidation supercritical carbon dioxide catalyst | S-27 | 969 | |
L203 | $B9b05(BCO2$B$N%U%i!<%l%sI=LL=$>~H?1~$NH?1~G^BN$X$NE,MQ(B | fullerene CO2 surface-modification | S-27 | 758 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $B9&!!>;0l(B) | |||||
L204 | Selective oxidation of alcohols over nano-gold catalysts in supercritical CO2 | supercritical CO$2$ oxidation Au nano catalyst | S-27 | 612 | |
L205 | $B?e$NFC@-$rMxMQ$7$?L5?(G^O"B3M-5!9g@.(B | water peculiarity organic synthesis | S-27 | 271 | |
L206 | $BN.DL<0H?1~AuCV$rMQ$$$?D6NW3&?eCf$K$*$1$k9bB.M-5!H?1~(B:$B%"%_%N;@9g@.(B | Supercritical water Rapid reaction amino acid | S-27 | 495 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B;0Eg(B $B7r;J(B) | |||||
L207 | $BD69b05D6NW3&?e$K$h$k9g@.H?1~(B | Supercritical water Synthesis Hydrothermal reaction | S-27 | 622 | |
L208 | ($B9V1iCf;_(B) | 100 | 748 | ||
L209 | $B9b299b05?eCf$G$N@PC:$N;@2=J,2rH?1~(B | SCWO coal kinetics | S-27 | 364 | |
(14:40$B!A(B15:20)$B!!(B($B;J2q(B $BhSED(B $B??><(B) | |||||
L218 | [$BE8K>9V1i(B]$BD6NW3&%"%k%3!<%k$rMQ$$$?(BPET$B$N%1%_%+%k%j%5%$%/%k5;=Q(B | supercritical fluid plastic monomerization | S-27 | 561 | |
(15:20$B!A(B16:20)$B!!(B($B:BD9(B $B@n:j(B $B?50lO/(B) | |||||
L220 | $B9b292C?eJ,2rH?1~$rMQ$$$?%]%jF};@%1%_%+%k%j%5%$%/%k$NI>2A(B | poly lactic acid chemical recycle hydrothermal reaction | S-27 | 898 | |
L221 | $BNL;R2=3X7W;;$K$h$kD6NW3&?eCf$G$N%0%j%;%k%"%k%G%R%IJQ49H?1~$N2r@O(B | glyceraldehyde conversion quantum mechanics | S-27 | 715 | |
L222 | $BD6NW3&Fs;@2=C:AGCf$G$N;@2=H?1~$K$h$k2M66%]%j%(%A%l%s$NG.2DA:2=(B | supercritical CO2 cross-linked polyethylene oxidation | S-27 | 494 | |
M$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 | |
$B!c4D6-It2q%7%s%]%8%&%`!d(B | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $B>oED(B $BAo(B) | |||||
M201 | $BCbAG=|5n7?1xE%8:MF%W%m%;%9$N3+H/(B | Sludge digestion Nitrogen removal BOD | S-30 | 19 | |
M202 | $B%(%?%N!<%k=|J|@-G=$rM-$9$k%W%i%9%A%C%/%U%#%k%`$K$h$kCO2K;@=|5n(B | Denitrification Groundwater Plastic film | S-30 | 857 | |
M203 | $BHy@8J*$NAH$_9g$o$;$K$h$k0B2A$JEE;R6!M?BN$rMxMQ$7$?%;%l%s;@4T85(B | selenium wastewater treatment bacteria | S-30 | 902 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $BH*Cf(B $B@i=)(B) | |||||
M204 | $B2C05G.?e=hM}$7$?LZ | plant biomass hot compressed water molding | S-30 | 914 | |
M205 | $B$a$C$-GQ?eCf$NF<(B - $B0!1t%7%"%N:x2=9gJ*$NDc29<><0;@2=J,2rFC@-(B | Wet oxidation Metal cyanide complexes Copper-zinc alloy plating | S-30 | 279 | |
M206 | ($B9V1iCf;_(B) | 100 | 986 | ||
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B>>ED(B $B?N | |||||
M207 | $B%?!<%k%l%9!&%P%$%*%^%9%,%92=AuCV$N3+H/(B | wood chip biomass gasifier tar-free gas | S-30 | 8 | |
M208 | O-$B$K$h$k%P%$%*%^%9%?!<%k$N;@2=(B | biomass/tar oxygen anion radical C12A7 | S-30 | 728 | |
M209 | $BGQ?)L}$h$j@=B$$7$?%P%$%*%G%#!<%<%kG3NACf$NIT=cJ*=|5n(B | biodiesel fuel purification | S-30 | 480 | |
(14:40$B!A(B15:40)$B!!(B($B:BD9(B $B86ED(B $B9@9,(B) | |||||
M218 | $BF3EE@-%@%$%d%b%s%IEE6K$rMQ$$$?M-5!Ce?'GS?e$NEE2rC&?'%7%9%F%`(B | diamond electrode decolorization | S-30 | 805 | |
M219 | $B%"%k%.%s;@%+%k%7%&%`%2%k$X$NHy:YAtN`$N8GDj2=$*$h$S$=$N5sF02r@O(B | algae biosorption immobilization | S-30 | 175 | |
M220 | $BB?9& | porous FeOOH adsorption | S-30 | 63 | |
(15:40$B!A(B16:40)$B!!(B($B:BD9(B $B>>K\(B $BF;L@(B) | |||||
M221 | $B | Anion exchanger Water treatment LDH | S-30 | 310 | |
M222 | $B%*%s%i%$%s%[%&AG%b%K%?!<$N3+H/(B | Boron ion electrode online monitor | S-30 | 68 | |
M223 | $B3$?eCfMOB8E4$NG;EYJ,@O5;=Q$N8&5f(B | sea desert Fulvic acid iron | S-30 | 794 | |
(16:40$B!A(B17:40)$B!!(B($B:BD9(B $B;3K\(B $B=( | |||||
M224 | SPCP$BH?1~4o$K$h$k%H%j%/%m%m%(%A%l%s$NGx5$=hM}(B | aerator ceramic filter active species | S-30 | 838 | |
M225 | $B;g30%(%l%/%H%m%k%_%M%;%s%9$*$h$SHs@~7A8w3X8z2L$rMxMQ$7$?8w?(G^?et2=B.EY$NB%?J(B | photocatalyst electroluminescence nonlinear optical effect | S-30 | 106 | |
M226 | $B6bB0C4;}%+!<%\%s%2%k$rMQ$$$??eCf%U%'%N!<%k$N%*%>%s;@2=B%?J8z2L$K4X$9$k8&5f(B | water purification phenol ozone | S-30 | 195 | |
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 $BG_LZ(B $BC$Li(B) | |||||
N201 | $B%$%*%s1UBN$r4^$`AjJ?9U$X$N(BASOG$B$*$h$S@5B'MO1UO@$NE,MQ(B | ionic liquid ASOG regular solution theory | S-1 | 24 | |
N202 | $B%$%*%s1UBN(B+CO2$B7O$NG.EAF3N($N?d;;(B | CO$2$ ionic liquid thermal conductivity | S-1 | 539 | |
N203 | $B%,%9%/%m%^%H%0%i%UK!$K$h$k%$%*%s1UBNCf$N6K@-M-5!2=9gJ*$NL58B4u | ionic liquid gas chromatography infinite dilution activity coefficients | S-1 | 407 | |
(10:00$B!A(B10:40)$B!!(B($B:BD9(B $BIZED(B $BBgJe(B) | |||||
N204 | $BAB?e@-%$%*%s1UBNCf$K$*$1$k%j%A%&%`1v$NMOB8>uBV$K5Z$\$9?e$N1F6A(B | ionic liquid lithium NMR | S-1 | 237 | |
N205 | $B%$%*%s1UBN!??eFsAj7O$K$*$1$k%U%'%N!<%kN`$NJ,G[78?t$NB,Dj(B | ionic liquid phenol distribution coefficient | S-1 | 610 | |
(10:40$B!A(B11:20)$B!!(B($B;J2q(B $BFbED(B $BGn5W(B) | |||||
N206 | [$B>7BT9V1i(B] $B%8%a%A%k%(!<%F%k(B(DME)$B$rE:2C$7$?:]$N(BLP$B%,%9Cf$N(BC5$BC:2=?eAG$N5$1UJ,G[Hf(B | Liquefied Petroleum Gas Dimethyl Ether Penpane Isomers | S-1 | 161 | |
(11:20$B!A(B12:00)$B!!(B($B;J2q(B $BFbED(B $BGn5W(B) | |||||
N208 | [$BE8K>9V1i(B] $B%W%m%;%9@_7W$H%W%m%;%93+H/$K$*$1$kJ*@-$N=EMW@-$H:#8e$X$N4|BT(B | S-1 | 999 | ||
(14:40$B!A(B15:20)$B!!(B($B;J2q(B $B:4F#(B $BA1G7(B) | |||||
N218 | [$BE8K>9V1i(B] $B9b299b05?eCf$K$*$1$k%$%*%sH?1~J?9UI>2A$N8=>u$H2]Bj(B | S-1 | 1000 | ||
(15:20$B!A(B15:40)$B!!(B($B;J2q(B $B:4F#(B $BA1G7(B) | |||||
N220 | [$B>7BT9V1i(B] $BD6NW3&Fs;@2=C:AG$K$h$kM-32J* | S-1 | 1004 | ||
(15:40$B!A(B16:40)$B!!(B($B:BD9(B $BDT(B $BCRLi(B) | |||||
N221 | $BJ,;R7B$+$i$_$?NW3&E@6aK5$K$*$1$kMO | Supercritical Molecular diameter Clustering | S-1 | 533 | |
N222 | $BFs;@2=C:AG(B-$BD>:?;iKCB2K0OBC:2=?eAG7O$N5$1U8G;0AjJ?9U(B | carbon dioxide normal chain saturated aliphatic hydrocarbon solid-liquid-gas equilibria | S-1 | 864 | |
N223 | $B%"%_%NMo;@0[@-BN$N?eCf$K$*$1$kAj8_3H;678?t(B | binary diffusion coefficient amino acid Taylor dispersion | S-1 | 234 | |
(16:40$B!A(B17:40)$B!!(B($B:BD9(B $BLZ86(B $B?-0l(B) | |||||
N224 | $BMOM;%]%j%^! | Henry's constant CO$2$ polymer | S-1 | 724 | |
N225 | $B%]%j%^! | Diffusion coefficient Polymer Soret Forcer Rayleigh Scattering Method | S-1 | 108 | |
N226 | $B%]%j(B(n$B!>%V%A%k%a%?%/%j%l!<%H(B)+$B%1%H%s7O$NAj8_3H;678?t$NB,Dj$H?d;;(B | mutual diffusion coefficient prediction poly(n-butyl methacrylate) | S-1 | 146 | |
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 $BBgM'=g0lO:(B) | |||||
O201 | $B%9%-%c%K%s%0%"%K!<%k$K$h$kAjJQ2=$r9MN8$7$?B@M[EECSMQ%J%N(BFeSi2/Si$BGvKl$N:n@=(B | Solar Cell Zone Melting Crystallization nano-particle | S-36 | 868 | |
O202 | $BGvKl(BZMC$BK!$K$h$kB@M[EECSMQGvKl$N7k>=2=$H(BSiO2/Si/SiO2$B;0AX9=B$$H$N4X78(B | Zone Melting Crystallization Silicon Solar Cell | S-36 | 891 | |
O203 | $B?'AGA}467?B@M[EECSMQ%J%N%A%?%K%"$ND4@=$H8wEEJQ49FC@-(B | dye-sensitized solar cell anatase-type titanium dioxide nano particle | S-36 | 419 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $B?\F#(B $B2mIW(B) | |||||
O204 | $B0[$J$k(BAg$B%J%NN3;R$r8w5[<}AX$KC4;}$7$??'AGA}46B@M[EECS$NH/EEFC@-(B | Solar cell Nanoparticle Dye sensitized | S-36 | 863 | |
O205 | $B6d%J%NN3;R$rC4;}$7$?8w5[<}AX$N9=B$$,?'AGA}46B@M[EECS$NH/EEFC@-$K5Z$\$91F6A(B | Solar cell Nanoparticle Dye sensitized | S-36 | 869 | |
O206 | $B%l%I%C%/%9%-%c%Q%7%?EE6K:`NA$H$7$F$N%^%s%,%s;@2=J*$NEE5$2=3XFC@-(B | electrochemical capacitor manganese oxide pseudocapacitance | S-36 | 804 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B0K86(B $B3X(B) | |||||
O207 | $BM-5!7OEE2r1U%O%$%Q%o!<%-%c%Q%7%?EE6K$N$?$a$N3h@-C:I=LL%W%i%:%^=hM}8z2L(B | Supercapacitor nonaqueous electrolyte plasma treatment | S-36 | 343 | |
O208 | $BEE5$Fs=EAX%-%c%Q%7%?$NEE2r1U$X$N3&LL3h@-:^$NE:2C$,= | Electric double layer capacitor surfactant aqueous solution | S-36 | 535 | |
O209 | $BFs;@2=%^%s%,%s$rMQ$$$?%"%k%+%j7AG3NAEECS%+%=!<%I$NEE6KFC@-(B | manganese dioxide cathode fuel cell | S-36 | 812 | |
(14:40$B!A(B15:40)$B!!(B($B:BD9(B $B5FCO(B $BN4;J(B) | |||||
O218 | MCFC/$B%^%$%/%m%,%9%?!<%S%s%O%$%V%j%C%IH/EE%7%9%F%`$N=PNOJQF0;~$N0BDj1?E>>r7o$NCN8+(B | fuel cell electric(al) generation hybrid | S-36 | 774 | |
O219 | $BB?9& | solid oxide fuel cell porous structure simulator multi-scale simulation | S-36 | 186 | |
O220 | Ni/ScSZ$BG3NA6K$rMQ$$$?8GBN;@2=J*G3NAEECS$K$*$1$kG3NAEECSH?1~5!9=$N8!F$(B | fuel cell solid oxide fuel cell ScSZ | S-36 | 862 | |
(15:40$B!A(B16:40)$B!!(B($B:BD9(B $BJ!D9(B $BGn(B) | |||||
O221 | SOFC$B>.7?H/EE;n83$K$*$1$k%;%k=8EEJ}K!$N8!F$(B | SOFC fuel cell current density | S-36 | 524 | |
O222 | SOFC$BEE2r | microwave heating SOFC electrolyte sintering | S-36 | 674 | |
O223 | SOFC$B>.7?H/EE;n83AuCV$NG.N.BN%7%_%e%l!<%7%g%s2r@O(B | SOFC test CFD analysis heat and mass transfer | S-36 | 687 | |
(16:40$B!A(B17:40)$B!!(B($B:BD9(B $B8E;3(B $BDL5W(B) | |||||
O224 | $B8GBN;@2=J*7AG3NAEECS$NG3NAB?MM2=$N8!F$(B | Solid oxide fuel cell Propane Decane | S-36 | 466 | |
O225 | $B0[$J$kEE2r%@%$%l%/%H%+!<%\%sG3NAEECS$NH/EEFC@-$N8!F$(B | solid oxide fuel cell fuel cell RDC-FC | S-36 | 795 | |
O226 | $B8GBN;@2=J*7AG3NAEECSG3NA6K$NEE6K9=B$$HM-8zH?1~>l(B | solid oxide fuel cell cermet anode effective reaction zone | S-36 | 900 | |
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 $B>.Eg(B $B5*FA(B) | |||||
P201 | $B%^%k%A?6F0%_%k$K$h$kLZ | Woody Biomass Pulverization Vibration Mill | S-28 | 912 | |
P202 | ($B9V1iCf;_(B) | 100 | 894 | ||
P203 | $BGQ4~J*!&%P%$%*%^%99b8zN(H/EEMQ9b29=8?P$rA[Dj$7$?3%5Z$SIe?)@-@.J,$N9b295sF0@)8f(B | High Temperature Gas cleaning Ash behavior control | S-28 | 949 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $BDMED(B $B$^$f$_(B) | |||||
P204 | $B%f!<%+%jLZ | biomass carbon neutral gasification | S-28 | 635 | |
P205 | $B%P%$%*%^%9?e>x5$%,%92=H?1~$K$*$1$k%?!<%k@8@.%a%+%K%:%`$N2rL@(B | biomass tar continuous cross-flow moving bed type differnecial reactor | S-28 | 826 | |
P206 | $B%P%$%*%^%9$NG.J,2rH?1~$H$=$N%b%G%j%s%0(B | Biomass Pyrolysis Modeling | S-28 | 148 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $BB<>e9b9-(B) | |||||
P207 | $B%b%&%=%&%A%/$N5^B.G.J,2rFC@-(B | Mosochiku Pyrolysis Rapid heating | S-28 | 504 | |
P208 | $B%+%k%7%&%`C4;}%P%$%*%^%9$HDc292s<}%P%$%*%*%$%k$N6&G.J,2r$K$h$k@8@.%?!<%k$NDc8:(B | biomass pyrolysis tar | S-28 | 101 | |
P209 | $BB?9& | biomass porous material adsorption | S-28 | 641 | |
(14:40$B!A(B16:00)$B!!(B($B:BD9(B $BD9C+@n(B $B8y(B) | |||||
P218 | $B%P%$%*%^%9$NL59ZAG!"?eG.E|2=(B | Biomass Hydrothermal Saccharification | S-28 | 44 | |
P219 | $B?(G^7|By%9%i%j!<$ND6NW3&?e%,%92=4pACFC@-(B | biomass supercritical water gasification slurry | S-28 | 840 | |
P220 | $B2HC\GS]uJ*$ND6NW3&?e%,%92=5;=Q$N3+H/(B | Supercritical Water Gasification Livestock excreta | S-28 | 934 | |
P221 | $B%P%$%*%G%#!<%<%kG3NA@8;:$K$*$1$k%$%*%s8r49 | biodiesel fuel ion-exchange resin transesterification | S-28 | 808 | |
(16:00$B!A(B17:20)$B!!(B($B:BD9(B $B>>B<(B $B9,I'(B) | |||||
P222 | $B;22C7?CO0h7W2h$N$?$a$N8x6&%W%i%C%H%U%)!<%`(BPEGASUS$B$N3+H/(B | pegasus regianal planning regional energy | S-28 | 871 | |
P223 | $B@D?98)HDLxD.$r%b%G%k%1!<%9$H$7$?CO0h%(%M%k%.!<$N<+5k$K$D$$$F(B | biomass regional energy | S-28 | 975 | |
P224 | $BCO0h%(%M%k%.!<<+5k$N$?$a$NMWAG5;=Q72!"%7%9%F%`$*$h$SF3F~ | regional energy nano grid | S-28 | 858 | |
P225 | $B%?%s%G%`7??'AGA}46B@M[EECS$N3+H/(B | dye-sensitized solar cell tandem | S-28 | 964 | |
Q$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!cH?1~9)3X$N?7$7$$E83+!d(B | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $BB?8P!!516=(B) | |||||
Q201 | C12A7$B8GBNFb$N3h@-;@AG$rMQ$$$?(BVOC$B;@2=H?1~$NDc292=(B | active oxygen species C12A7 VOC | S-12 | 688 | |
Q202 | C12A7$B$+$i$N(BO-$B@8@.$NDc292=(B | C12A7 oxygen anion radical | S-12 | 740 | |
Q203 | O-$B$N1UAjH?1~$N5sF0$K$D$$$F(B | oxygen anion radical ion reaction pH | S-12 | 762 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $B@>2,!!>-51(B) | |||||
Q204 | HCFC-22$B$NJ,2rB.EY$K$*$1$k(BNaOH$B$N1F6A(B | HCFC-22 vapor-liquid equilibrium reaction rate controlling | S-12 | 14 | |
Q205 | $B9b;@AGG;EY2<$G$NL5?(G^C&>K$K$*$1$k(BNOx$BH?1~5!9=$N8!F$(B | non-catalytic reduction NOx mechanism | S-12 | 865 | |
Q206 | $B%j%s;@%^%0%M%7%&%`4XO"2=9gJ*$K$h$k%"%s%b%K%"$NO"B32s<}$N;n$_(B | removal and recovery aqueous ammonium magnesium phosphates | S-12 | 56 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B30NX!!7r0lO:(B) | |||||
Q207 | $B%j%s;@%^%0%M%7%&%`%"%s%b%K%&%`$K$h$k%P%$%*%^%9GQ4~J*$+$i$N%"%s%b%K%"2s<}(B | Biomass ammonia MAP | S-12 | 260 | |
Q208 | Ni-Y$B7?%<%*%i%$%H$K$h$k?eAjCf4uGv%A%*%U%'%N!<%k9b8zN(=|5n(B | bio-polyester thiophenol Ni-Y type zeolite | S-12 | 263 | |
Q209 | Reaction Kinetics of the synthesis of a novel biodegradable plastic using a water-soluble protein under the sub-critical water condition | Sub-critical water Reaction engineering biodegradable plastic | S-12 | 516 | |
(14:40$B!A(B15:20)$B!!(B($B;J2q(B $B4_ED!!>;9@(B) | |||||
Q218 | [$BE8K>9V1i(B]$B%"%b%k%U%!%99g6b$r86NA$H$9$k?(G^D4@=5;=Q$NE8K>(B | S-12 | 768 | ||
(15:20$B!A(B16:00)$B!!(B($B;J2q(B $B8^==Mr!!E/(B) | |||||
Q220 | [$BE8K>9V1i(B]$B?e>x5$2~ | Pre-reforming 10-Hole shape ISOP catalyst | S-12 | 750 | |
(16:00$B!A(B16:40)$B!!(B($B;J2q(B $BA}ED!!N4IW(B) | |||||
Q222 | [$BE8K>9V1i(B]10$BG/8e$N9)6H?(G^(B | Changing Market New catalysts Catalyst industry | S-12 | 753 | |
(16:40$B!A(B17:20)$B!!(B($B;J2q(B $BED@n!!CRI'(B) | |||||
Q224 | [$BE8K>9V1i(B]$B%(%s%8%K%"%j%s%0$+$i8+$??(G^$HH?1~4o$N@_7W(B | Structure of Catalytic Reactor Simulation Design of Catalytic Reactor | S-12 | 760 | |
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$$E83+!d(B | |||||
(9:00$B!A(B10:00)$B!!(B($B:BD9(B $BHx>e!!70(B) | |||||
R201 | $BEE2r?eAG!&;@AG$rMQ$$$?2a;@2=?eAG$ND>@\9g@.(B | hydrogen peroxide electrolysis catalyst | S-12 | 258 | |
R202 | $B?eMO@-%]%j%^! | Water-soluble polymer Electrolyte Kinetics | S-12 | 733 | |
R203 | CO$B%W%i%:%^$K$h$k%+!<%\%s%J%N%U%!%$%P!<$NDc299g@.!=4pHD:`NA$*$h$S?(G^6bB0$N1F6A!=(B | CO plasma carbon nanofiber low temperature synthesis | S-12 | 896 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $BD9DE!!M:0lO:(B) | |||||
R204 | $BD>N.%Q%k%9J|EE$rMQ$$$??eMO1UCfM-5!1vAG7O=|Ap:^$N%W%i%:%^J,2r(B | Plasma decomposition Wastewater treatment Organic chloride | S-12 | 292 | |
R205 | $B4u%,%9%W%i%:%^$rMQ$$$?C:2=?eAG$NE>49(B | microwave plasma dehydrogenation | S-12 | 549 | |
R206 | $BM6EEBN%P%j%"J|EEH?1~4o$rMQ$$$?%G%#!<%<%kGS%,%9Cf$NC:AG7OHyN3;R$N=|5n(B | diesel exhaust particulate matter dielectric barrier discharge | S-12 | 415 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $B?9!!?-2p(B) | |||||
R207 | TiN-CVD$B$NAm3gH?1~$N%b%G%k2=$H%R!<%?!<%W%j%3!<%H%7%_%e%l!<%7%g%s(B | TiN TiCl4 Reaction model | S-12 | 803 | |
R208 | GaAs$BA*Br(BMOVPE$B@.D9$K$*$1$kIT=cJ*E:2C%,%9$N1F6A(B | MOVPE CVD Selective Growth | S-12 | 470 | |
R209 | $BA*Br@.D9$rMxMQ$7$?(BInP-MOVPE$B%W%m%;%9$N2r@O(B | InP MOVPE Selective Growth | S-12 | 474 | |
S$B2q>l(B | |||||
$B9V1i(B $B;~9o(B | $B9V1i(B $BHV9f(B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $BJ,N`(B | $BHV9f(B $B | |
$B!cE}9g2=9)3X!d(B | |||||
(9:00$B!A(B10:40)$B!!(B($B:BD9(B $BNkLZ(B $B2mG7!&EgED(B $B9T63(B) | |||||
S201 | [$BE8K>9V1i(B]$BE}9g2=5;=Q$O2?8NI,MW$+!)(B | Life Cycle Engineering Integrated Technique Technical Information Infrastructure | S-16 | 97 | |
S203 | [$B>7BT9V1i(B]$BE}9g2=LdBj$H$7$F$N=[4D7? | Sustainable society Integration Production | S-16 | 231 | |
S204 | [$B>7BT9V1i(B]$B2=3X%W%m%;%9;:6H$K$*$1$kE}9g2=%"%W%m!<%A(B | safety operation chain management life cycle engineering | S-16 | 303 | |
S205 | [$B>7BT9V1i(B]$BE}9g3X$+$i8+$?(BSCM$B$H%"%&%H%=!<%7%s%0(B | SCM Outsourcing Logistics | S-16 | 371 | |
(10:40$B!A(B11:40)$B!!(B($B:BD9(B $BHxF#(B $B@65.!&;32<(B $BA1G7(B) | |||||
S206 | [$B>7BT9V1i(B]HORIBA Group IT$BE}9g7W2h$K$*$1$k@=IJ>pJsE}9g$K$D$$$F(B | ERP PLM PLIB | S-16 | 105 | |
S207 | [$B>7BT9V1i(B]$B@P2=9)>l8=>l$+$i$NE}9g2=$X$N;W$$(B | $BE}9g3X(B factory KPI | S-16 | 124 | |
S208 | [$B>7BT9V1i(B]$B%(%s%8%K%"%j%s%02q | Multidisciplinary Engineering Solution | S-16 | 376 | |
(11:40$B!A(B12:00)$B!!(B($B;J2q(B $BHxF#(B $B@65.!&;32<(B $BA1G7(B) | |||||
$BAm9gF$O@(B | |||||
$B!c>pJs5;=Q650i$N?JE8!JBh#52s3X@8%=%U%H%&%(%"!&%D!<%k%3%s%F%9%H!K!d(B | |||||
(14:40$B!A(B16:20)$B!!(B($B;J2q(B $B4X8}(B $B=(=S!&^ | |||||
S218 | $BBh(B5$B2s%=%U%H%&%'%"!&%D!<%k3X@8%3%s%F%9%H(B | information technology software tool process simulation | S-17 | 595 | |
(16:20$B!A(B16:40)$B!!(B($B;J2q(B $BIpED(B $BOB9((B) | |||||
S223 | [$BE8K>9V1i(B]$B5~ETBg3X$K$*$1$k%W%m%;%9@_7W650i(B | information technology process design education | S-17 | 306 | |
(16:40$B!A(B17:20)$B!!(B($B;J2q(B $B2#;3(B $B9n8J(B) | |||||
S224 | [$BE8K>9V1i(B]$B%W%m%;%99=C[G=NO3+H/$NI,MW@-$K$D$$$F(B | process design information technology | S-17 | 591 | |
(17:20$B!A(B18:00)$B!!(B($B;J2q(B $B4X8}(B $B=(=S!&^ | |||||
$BAm9gF$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$H1~MQ5;=Q!d(B | |||||
(9:20$B!A(B10:00)$B!!(B($B:BD9(B $B?y;3(B $B@5OB(B) | |||||
U202 | $BD6NW3&Fs;@2=C:AGCf$G$N<+8JAH?%2=$rMxMQ$7$?5e>u9bJ,;RHyN3;R$N9g@.(B | Supercritical carbon dioxide Self-assembly Microspheres | S-27 | 40 | |
U203 | $BD6NW3&Fs;@2=C:AGCf$G$N%]%j%T%m!<%k$N9g@.(B | pyrrole supercritical carbondioxide particle | S-27 | 844 | |
(10:00$B!A(B11:00)$B!!(B($B:BD9(B $BEDB | |||||
U204 | $BD6NW3&Fs;@2=C:AG$rMxMQ$7$?9bJ,;RHyN3;R:n@=2aDx$K$*$1$kJd=uMOG^$N8z2L$K$D$$$F(B | nucleation polymer particle CO2 | S-27 | 915 | |
U205 | $BD6NW3&Fs;@2=C:AG$rMQ$$$?>=@O$K$h$kM-5!HD>uN3;RJ4BN$N3+H/(B | supercritical carbon dioxide crystallization organic plate particle | S-27 | 76 | |
U206 | $BD6NW3&Fs;@2=C:AGCf$K$*$1$k6bB0:xBN$NG.J,2r5sF0(B($BBh(B2$BJs(B) | Supercritical CO2 Metal Chelate Decomposition | S-27 | 522 | |
(11:00$B!A(B12:00)$B!!(B($B:BD9(B $BBgLg(B $BM5G7(B) | |||||
U207 | $B0eNE1~MQ$rL\;X$7$?%O%$%V%j%C%IL55!%J%NN3;R$ND6NW3&?eG.9g@.(B | Supercritical water hydrothermal nanoparticle | S-27 | 652 | |
U208 | SCFD(Supercritical Fluid Deposition)$B$K$h$k(BSiO2$BGvKl$N9g@.(B | supercritical deposition silicon dioxide | S-27 | 680 | |
U209 | $BD6NW3&(BCO2$B%(%^%k%8%g%s$rMQ$$$?L5EE2r(BNi-P$B$a$C$-K!$N3+H/(B | carbon dioxide supercritical fluid electroless plating | S-27 | 35 |