$B:G=*99?7F|;~!'(B2013-08-09 19:09:01
T zeolite membrane (1$B7o(B) | ||||
---|---|---|---|---|
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-45 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
263 | T$B7?%<%*%i%$%HKl$N(BCO2$BF)2a@-G=I>2A(B | S-45 | T zeolite membrane CO2 separation separation factor | 5/10 13:26:05 |
tail fiber (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-6 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
837 | T$B6v?t7O%P%/%F%j%*%U%!!<%8$K$*$1$kHxA!0]%?%s%Q%/ | S-6 | bacteriophage tail fiber host range | 5/13 18:56:21 |
tangential flow filtration (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-8 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
168 | $B%?%s%Q%/F)2a@-$N9b$$Cf6u;eKl(B | S-8 | tangential flow filtration protein permeability clarification of cell culture | 5/9 11:28:35 |
tantalum oxide (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-4 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
515 | The oxygen reduction reaction of well-dispersed TaOx nanoparticles on carbon black for PEFC applications. | S-4 | PEFCs Oxygen reduction reaction tantalum oxide | 5/13 10:33:52 |
tar (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-3 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
119 | $BGQ%W%i%9%A%C%/%9$NG.J,2r;~$K@8@.$9$k%?!<%k$NJ,@O$H?e>x5$J,2r(B | S-28 | tar plastics gasification | 5/8 15:40:59 |
586 | $BC:AG | S-3 | microwave plasma carbon nano-material tar | 5/13 13:30:36 |
Taylor dispersion (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-13 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
801 | CO2-$B%a%?%N!<%k:.9gN.BNCf$K$*$1$kM-5!2=9gJ*$NL58B4u | S-13 | Taylor dispersion CO2 mixture Diffusion coefficient | 5/13 18:11:05 |
Taylor Voltex (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-21 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
166 | $BFb1_E{$r%3!<%F%#%s%0$7$?Fs=E1_E{4V%F%$%i!<12$NN.F0(B | S-21 | Taylor Voltex Drag Reduction Coating | 5/9 09:57:10 |
Taylor vortex flow (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-25 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
193 | Taylor-Couette$B12N.$l$ND62;GH7WB,K!$K$D$$$F(B | S-25 | Taylor vortex flow Ultrasound velocity measurement Visualization | 5/9 15:36:32 |
Taylor-couette vortex flow (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-6 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
200 | Taylor-Couette $B12%P%$%*%j%"%/%?!<$K$*$1$k8w9g@.Hy@8J*$NA}?#FC@-(B | S-6 | Taylor-couette vortex flow Bioreactor Mixing | 5/9 16:36:25 |
TCA cycle (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-6 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
727 | $BI=AX%G%6%$%s%j%]%=!<%`Kl$K$h$k%/%(%s;@2sO)4XO"9ZAG$N;@2=4T85H?1~$N@)8f(B | S-6 | Membranome TCA cycle Redox reaction | 5/13 17:04:53 |
temperature dependence (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-43 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
511 | $B3h@-C:A!0]$H9u1t2=%+!<%\%s%V%i%C%/$X$N?e>x5$5[Ce$N29EY0MB8@-(B | S-43 | water vapor adsorption activated carbon fiber temperature dependence | 5/13 10:24:55 |
Temperature Distribution Analysis (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-4 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
211 | $B%5!<%b%0%i%U%#!<$G | S-4 | PEFC Heat Transfer Model Temperature Distribution Analysis | 5/9 18:29:51 |
Temperature Responsive Polymer (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-45 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
145 | $B29EY1~Ez@-J,N%Kl$ND4@=$*$h$S$=$NJ,N%FC@-(B | S-45 | Temperature Responsive Polymer membrane separation | 5/8 19:20:19 |
temperature swing (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-45 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
538 | $B?75,$J29EY1~Ez7?5[Ce:`$K$h$k?eCf$N9EEY@.J,$N5[C&CeFC@-(B | S-45 | thermosensitive polymer temperature swing adsorption | 5/13 11:25:57 |
temperature-swing adsorption (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-34 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
606 | $B4629@-9bJ,;R%2%k$K$h$k(BPd($B-6(B)$B5[CeFC@-$N8!F$(B | S-34 | temperature-swing adsorption polymer gel palladium | 5/13 14:05:42 |
template (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-21 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
27 | [$BM%=(O@J8>^(B] $BN.L.LL$NJQ7A$K$h$k:.9g$NB%?J(B | S-21 | mixing streak surface template | 4/25 13:47:52 |
template method (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-33 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
921 | $B%]%k%U%#%j%s:xBN!?%J%U%?%l%s$N5e>uJ,;R=89gBN$rCr7?$H$7$?Cf6u%7%j%+%J%NN3;R$N?75,9g@.K!$H9=B$@)8f(B | S-33 | tetraphenylporphyrincobalt(II) complex template method hollow silica nanoparticles | 5/13 20:07:02 |
terephthalic acid (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-3 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
306 | $B%^%$%/%mGH%P%V%k%W%i%:%^$K$h$j@8@.$9$k(BOH$B%i%8%+%k$NH?1~(B | S-3 | plasma hydroxyl radical terephthalic acid | 5/10 16:26:48 |
312 | $B%^%$%/%mGH%P%V%k%W%i%:%^$K$h$j@8@.$9$k(BOH$B%i%8%+%k$NH?1~(B | S-29 | plasma hydroxyl radical terephthalic acid | 5/10 16:39:36 |
Terminal deoxynucleotidyl transferase (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-6 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
225 | $B9ZAG(B-$B3K;@J#9gBN$K$h$kI8E*%?%s%Q%/ | S-6 | DNA-enzyme conjugate Terminal deoxynucleotidyl transferase Microbial transglutaminase | 5/9 21:30:48 |
Terminal electrode (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-33 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
10 | [$BM%=(O@J8>^(B] $B1UAjK!$K$h$k@QAX%;%i%_%C%/%3%s%G%s%5! | S-33 | Metallic film Terminal electrode Wet chemical preparation | 4/23 10:40:36 |
ternary phase diagram (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-35 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
46 | $B%5%j%A%k;@!?%K%3%A%s%"%_%I7O(Bcocrystal$B$N;0@.J,Aj?^$HMO2r5sF0(B | S-35 | cocrystal dissolution behavior ternary phase diagram | 4/30 10:58:44 |
tetradecane (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-15 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
202 | Effect of Reaction Parameters on the Activity of Kovar Based Catalyst for Dry Reforming of Tetradecane | S-15 | Kovar dry reforming tetradecane | 5/9 16:42:35 |
tetraphenylporphyrincobalt(II) complex (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-33 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
921 | $B%]%k%U%#%j%s:xBN!?%J%U%?%l%s$N5e>uJ,;R=89gBN$rCr7?$H$7$?Cf6u%7%j%+%J%NN3;R$N?75,9g@.K!$H9=B$@)8f(B | S-33 | tetraphenylporphyrincobalt(II) complex template method hollow silica nanoparticles | 5/13 20:07:02 |
the droplet coalescence method (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-34 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
335 | $BE)4V9g0lK!$K$h$k%;%k%m!<%97O%U%!%$%P!<$rJI:`$H$7$?@8J,2r@-%+%W%;%k$ND4@=$H1~MQ(B | S-34 | biodegradable capsules the droplet coalescence method cellulose fiber shell | 5/10 17:54:46 |
the Ionic Semiconductor (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-15 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
66 | $B%(%M%k%.!<4XO"J,Ln$K$*$1$k%$%*%sH>F3BN$N1~MQ(B | S-15 | the Ionic Semiconductor Antioxidative Effect Energy Consumption Reduction Systems | 5/2 18:45:56 |
the Japan Sea (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-31 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
733 | $BF|K\3$$K$*$1$kM-5!1x@wJ* | S-31 | the Japan Sea Organic Pollutants PAH | 5/13 17:09:48 |
Theophylline nanoparticle production (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-14 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
471 | RESS-SC$BK!$K$h$k%F%*%U%#%j%s$N%J%NN3;RAO@=$KBP$9$k(B(-)-$B%\%k%M%*(B-$B%k$N8GBN6&MOG^8z2L$N2rL@(B | S-14 | RESS-SC technique Theophylline nanoparticle production Solid cosolvent effects | 5/13 02:46:39 |
Thermal Conductivity (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-15 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
557 | $B%a%?%s%O%$%I%l!<%H8:05J,2r2aDx$K$*$1$kLO5<%3%"$NG.EAF3EYB,Dj$H9=B$%b%G%k(B | S-15 | Methane Hydrates Thermal Conductivity Core Structure | 5/13 12:16:43 |
thermal CVD (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-2 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
508 | Co$B%"%_%G%#%M!<%H$rMQ$$$?(BCo-CVD$B%W%m%;%9$K$*$1$k5$AjH?1~$H$=$NLr3d(B | S-2 | amidinate cobalt thermal CVD | 5/13 10:12:55 |
thermal decomposition (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-5 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
713 | $B%]%jN2;@BhFsE4$NG.J,2rFC@-$K4X$9$k8&5f(B | S-15 | flocculant thermal decomposition desulfurization | 5/13 16:52:03 |
993 | $B%H%j%"%>!<%k%*%sM6F3BN$NG.J,2r5sF0$HJ,2r5!9=$N8!F$(B | S-5 | triazole derivatives thermal decomposition molecular orbital calculation | 5/13 21:49:13 |
Thermal degradation (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-49 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
266 | $B%(%]%-%7 | S-49 | Epoxy Thermal degradation IR spectroscopy | 5/10 13:39:04 |
thermal energy storage (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-15 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
850 | $BM;E@9_2<$K$h$kE|%"%k%3!<%k7O@xG.C_G.:`$ND9 | S-15 | Phase change material thermal energy storage nanomaterial | 5/13 19:07:25 |
thermal expansion coeffcient (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-17 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
565 | $BEE5$F<$a$C$-$K$h$j:n@.$7$?(BTSV$BG[@~$NG.@~KDD%78?tDc8:(B | S-17 | TSV Copper thermal expansion coeffcient | 5/13 12:37:53 |
Thermal Plasma (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-3 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
554 | $B%$%s%U%i%$%HMOM;N3;R$NFC@-$KM?$($kB?Aj8rN.%"!<%/$N6u4V6Q0l@-(B | S-3 | Thermal Plasma Multi-phase arc In-flight melting | 5/13 12:11:43 |
Thermochemical (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-1 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
711 | $B%3%P%k%H;@%j%A%&%`$rMQ$$$??75,G.2=3X?eJ,2r(B | S-1 | Hydrogen Water-splitting Thermochemical | 5/13 16:51:07 |
Thermochemical gasification (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-50 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
874 | $B@8J*FqJ,2r@-M-5!J*$NG.2=3XE*%,%92=FC@-$N8!F$(B | S-50 | Anaerobic digestion sludge Aquaticweed Thermochemical gasification | 5/13 19:24:13 |
Thermochemikal Cycle (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-1 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
315 | ISN$B%5%$%/%k$K$*$1$k%"%s%b%K%"@8@.H?1~$N8!F$(B | S-1 | Ammonia synthesis Thermochemikal Cycle Reaction Rate | 5/10 16:43:46 |
Thermoduric lactobacilli (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-50 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
976 | $B3$AtBOHn$+$iBQG.@-F};@@8@.6]$NC1N%(B | S-50 | Isolation Thermoduric lactobacilli Lactic acid | 5/13 21:22:32 |
Thermodynamic consistency line (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-38 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
715 | $BG.NO3X7rA4@~$rMQ$$$k1U1UJ,G[78?t$N?d;;(B | S-38 | Thermodynamic consistency line liqui-liquid partition coefficient grand correlation | 5/13 16:54:04 |
thermophoresis (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-18 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
648 | $B%^%$%/%m%A%c%M%kFb$NBg$-$J29EY8{G[2<$K$*$1$kHyN3;R$NG.1KF0(B | S-18 | thermophoresis soret cofficient micro channel | 5/13 15:28:29 |
thermophysical property (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-38 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
548 | [$B>7BT9V1i(B] $BDc(BGWP$BNdG^$N3+H/!!(B-$BB,DjAuCV$H | S-38 | refrigerants thermophysical property high pressure | 5/13 11:52:32 |
Thermoplastics (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-49 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
619 | $B%(%?%N!<%k4D6-$K$*$1$kG.2DA:@-%W%i%9%A%C%/$N?;F)Nt2=5sF0$HD62;GH$K$h$kI>2A(B | S-49 | Thermoplastics Permeation degradation ethanol | 5/13 14:23:11 |
thermosensitive gel (4$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-43 (2$B7o(B), S-36 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
348 | $BKlF}2=K!$rMQ$$$?4629@-9bJ,;R%*%k%,%N%2%kHyN3;R$N:n@=$HLtJ*J|=PFC@-(B | S-34 | thermosensitive gel organogel drug delivery system | 5/10 18:24:12 |
401 | $B<'@-N3;R$r4^$`4629@-%2%k$N<'>lJQ2=$K$h$kAB?e@-J* | S-36 | thermosensitive gel magnetic field adsorption | 5/11 13:42:14 |
1010 | $BB?:BJq@\7?G[0L;R$r4^M-$9$k4629@-%2%k$K$h$k(BAm/Eu $BJ,N%(B ----$B%2%k$N(BAm/Eu$BCj=PJ,N%$HCj=P5!9=(B--- | S-43 | Thermosensitive Gel Extraction Mechanism XAFS | 5/13 22:18:43 |
1012 | $BB?:BJq@\7?G[0L;R$r4^M-$9$k4629@-%2%k$K$h$k(BAm/Eu $BJ,N%(B----- $BB?9& | S-43 | Extraction Chromatography Thermosensitive Gel Porous Silica | 5/13 22:35:29 |
thermosensitive polymer (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-45 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
538 | $B?75,$J29EY1~Ez7?5[Ce:`$K$h$k?eCf$N9EEY@.J,$N5[C&CeFC@-(B | S-45 | thermosensitive polymer temperature swing adsorption | 5/13 11:25:57 |
thermosensitivity (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-36 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
398 | $B1v?eCf$G$N(Bpoly[oligo(ethylene glycol) methyl ether methacrylate] $B%2%kN`$N4629FC@-(B | S-36 | thermosensitivity poly[oligo(ethylene glycol) methyl ether methacrylate] gels swelling behavior | 5/11 12:45:37 |
thermosensitivity gel (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-34 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
592 | NIPA-PVA-semi-IPN$B%2%k$X$N6bB0%$%*%s$N5[C&CeFC@-(B | S-34 | thermosensitivity gel metal ion adosoption | 5/13 13:40:44 |
thermostable enzyme (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-11 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
63 | [$B>7BT9V1i(B] $BBQG.@-9ZAG%b%8%e!<%k$K$h$k(BIn vitro $BBe | S-11 | in vitro metabolic engineering thermostable enzyme on-demand bioprocess | 5/2 17:12:56 |
Thin film (3$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-37 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
143 | SOFC$B$K$*$1$k(BGd0.5Sr0.5CoO3$B;@AG6KGvKl$NFC@-I>2A(B | S-4 | SOFC GSCO Thin film | 5/8 18:50:06 |
198 | $BD6NW3&N.BN%;%l%s2=!&N22=K!$K$h$k(BCZTS$B7OB@M[EECSMQ2=9gJ*H>F3BNGvKl$N:n@=(B | S-14 | Solar Cell Supercritical Fluid Thin Film | 5/9 16:07:01 |
952 | [$B>7BT9V1i(B] $BM6F3<+8JAH?%2=$K$h$k%V%m%C%/%3%]%j%^!<$NH>F3BN@=B$9)Dx$X$N1~MQ(B | S-37 | DSA Thin film Block copolymer | 5/13 20:55:53 |
thin films design (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-35 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
467 | $BD6NW3&MOBN5^B.KDD%K!$K$h$k%"%s%H%i%;%sGvKlAO@=$N2aK0OBEY$K4p$E$$$?GvKl@_7W5;=Q(B | S-35 | RESS technique anthracene thin films thin films design | 5/13 01:40:23 |
469 | $BD6NW3&MOBN5^B.KDD%K!$rMxMQ$7$?%k%V%l%sGvKl$NAO@=%a%+%K%:%`$N2rL@$HGvKl@_7W5;=Q(B | S-14 | RESS technique rubrene thin film production thin films design | 5/13 01:51:04 |
thin-film transistor (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-7 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
856 | $B%Z%W%A%I%"%W%?%^!<$NFC@-$rMxMQ$7$?%+!<%\%s%J%N%A%e!<%VGvKl%H%i%s%8%9%?$N:n@=(B | S-7 | peptide aptamer thin-film transistor carbon nanotube | 5/13 19:12:47 |
three dimension (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-17 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
3 | [$B>7BT9V1i(B] $B;0F3BN$N:#8e$N1~MQE83+(B | S-17 | three dimension semiconductor | 4/22 11:20:16 |
through-plane measurement (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-4 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
260 | $B8GBN9bJ,;R7AG3NAEECS$N(Bthrough-plane$BKlEAF3EYB,DjK!$N3NN)(B | S-4 | ion exchange membranes through-plane measurement conductivity | 5/10 13:16:57 |
Timing and Speed of implementation (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-15 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
827 | $BH/EE5;=Q$NFC@-$r9MN8$7$?5;=QF3F~%7%J%j%*$N@_7W(B | S-15 | Photovoltaic power generation Load following capability Timing and Speed of implementation | 5/13 18:37:31 |
Tin (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-17 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
382 | Sn$B$a$C$-Ii6K:`$N9=B$@)8f$K$h$k%J%H%j%&%`%$%*%sEECS$N%5%$%/%kFC@-I>2A(B | S-17 | Na-ion battery Tin electrodeposition | 5/10 20:04:30 |
TiO$2$ (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-2 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
622 | $B%"%k%3!<%kE:2C$K$h$kD6NW3&N.BN$rMQ$$$?(BTiO2$BKl7A@.(B | S-2 | Supercritical fluid deposition TiO$2$ alcohol | 5/13 14:24:33 |
TiO$2$ embedded carbon nanofibersupport (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-4 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
296 | Pt$BC4;}(BTiO2$B4^M-(BCNF$B?(G^$K$*$1$k%(%?%N!<%k;@2=H?1~(B | S-4 | Ethanol oxidation reaction Pt nanoparticles TiO$2$ embedded carbon nanofibersupport | 5/10 15:46:47 |
TiO$2$/SiO$2& (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-5 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
320 | $B%A%?%K%"!?%7%j%+8w?(G^$K$h$k4^CbAGO;0w4DG@Lt$NJ,2r(B | S-5 | Photocatalyst TiO$2$/SiO$2& Agricultural chemicals | 5/10 16:56:56 |
TiO2 (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-31 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
483 | TiO2$B8w?(G^$K$h$kCO2Z8&5f(B | S-31 | hexavalent chromium TiO2 groundwater | 5/13 09:00:31 |
TiO2 modified CNF support (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-4 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
291 | $B%A%?%K%"=$>~(BCNF$BC4BN$rMQ$$$?%"%k%3!<%k;@2=EE6K?(G^(B | S-4 | TiO2 modified CNF support Electrode catalyst Direct Alcohol Fuel Cell | 5/10 15:31:50 |
tiped-kneading disk (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-21 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
849 | $BFs<4%9%/%j%e2!=P5!$N?75,:.N}%(%l%a%s%H(B:$B79 2A(B | S-21 | twin screw extruder tiped-kneading disk rheology | 5/13 19:06:07 |
Tissue Engineering (4$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-6 (3$B7o(B), S-9 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
173 | $BEE5$2=3XE*:YK&C&N%$N$?$a$N<+8JAH?%2=%*%j%4%Z%W%A%I$N@_7W(B | S-6 | Tissue engineering Zwitterionic oligoepeptide Electrochemistry | 5/9 12:25:53 |
343 | $B:YK&@\Ce@-%O%$%I%m%2%k%U%!%$%P!<$rMQ$$$?4N>.MUMMAH?%$N:n@=K!$N3+H/(B | S-6 | Tissue engineering Hydrogel Hepatic tissue | 5/10 18:08:31 |
455 | $B%^%$%/%mN.BN%G%P%$%9$rMQ$$$?Hy>.9|3J6ZAH?%$N9=C[(B | S-6 | BioMEMS Tissue Engineering Skeletal muscle | 5/12 16:10:02 |
527 | $B<+8JAH?%2=%Z%W%A%I$rMQ$$$?G]M\;.I=LL$N@_7W(B | S-9 | Tissue engineering Zwitterionic oligoepeptide Electrochemistry | 5/13 11:05:08 |
Titania-Zirconia oxide (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-28 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
404 | $B=E | S-28 | Heavy oil Titania-Zirconia oxide Catalytic cracking | 5/11 14:05:02 |
titanium carbide (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-2 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
946 | $B3F | S-2 | titanium carbide hard coating chemical vapor deposition | 5/13 20:50:00 |
titanium compound (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-45 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
334 | $B%9%H%m%s%A%&%`=|5n$N$?$a$N%+%A%*%s8r49%0%i%U%HA!0]$X$N%A%?%s2=9gJ*7+JV$7@O=PC4;}(B | S-45 | multi-coating strontium removal titanium compound | 5/10 17:53:27 |
Titanium dioxide (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-34 (2$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
311 | $B%a%+%K%+%k%3!<%F%#%s%0K!$K$h$k4D6->t2=J#9g8w?(G^GvKl$N@-G=I>2A(B | S-34 | photocatalyst titanium dioxide methylene blue | 5/10 16:39:08 |
873 | TiO2$B8w?(G^$rMQ$$$??eCf$NM-5!J*J,2r$K$*$1$k(BCa$B%$%*%s$N1F6A(B | S-34 | Water purification Photocatalyst Titanium dioxide | 5/13 19:23:50 |
Titanium Oxide (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-4 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
979 | P3HT/ICBA$BM-5!B@M[EECS$NH/EEFC@-$H;@2=%A%?%sKl$N7k>=@-$H$N4X78(B | S-4 | Titanium Oxide organic solar cell crystallinity | 5/13 21:25:21 |
Titanium silicalite-1 (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-28 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
396 | $B%7%j%+%i%$%HHoJ$(BTS-1$B%<%*%i%$%H?(G^$N9g@.$H1UAj;@2=H?1~(B | S-28 | Zeolite Oxidation Titanium silicalite-1 | 5/11 11:28:31 |
Topology optimization (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-18 (2$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
73 | $BO"B39=B$BN$N%H%]%m%8!<:GE,2=$G$N%A%'%C%+!<%\!<%ILdBj(B | S-18 | Structure Topology optimization SIMP | 5/6 16:45:11 |
74 | $B%H%]%m%8!<:GE,2=$GF@$i$l$kO"B39=B$BN$N0l0U@-(B | S-18 | Structure Topology optimization SIMP | 5/6 16:48:35 |
transcutaneous immunization (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-6 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
610 | $BL}Cf%J%NJ,;62=5;=Q$rMQ$$$?8z2LE*$J$,$sLH1VNEK!$N3+H/(B | S-6 | transcutaneous immunization cancer vaccine nano dispersion | 5/13 14:11:14 |
Transdermal delivery (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-6 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
714 | $BN>?FG^@-%"%_%N;@;i | S-6 | Supramolecular gel Oil-in-Water Emulsion Transdermal delivery | 5/13 16:53:49 |
transesterification rate (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-50 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
653 | $B%P%$%*%G%#!<%<%k@=B$$K$*$1$kYxYBAe$rMQ$$$?%(%9%F%k8r49H?1~B.EY(B | S-50 | biodiesel production transesterification rate countercurrent multistage reactor | 5/13 15:37:40 |
Transfer efficiency (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-48 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
933 | $B9bB.2sE>%Y%k%+%C%WEIAu5!$K$*$1$kJ.L8N3;R7B$,EICe8zN($K5Z$\$91F6A$N8!F$(B | S-48 | Rotary bell cup atomizer Transfer efficiency Computational fluid dynamics | 5/13 20:24:40 |
transgenic chicken bioreactor (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-6 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
662 | $BD;N`B?G=@-44:YK& | S-6 | pluripotent stem cells genetically modified feeder cells transgenic chicken bioreactor | 5/13 15:48:58 |
transient expression (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-6 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
621 | $B:+Cn:YK&$rMQ$$$?0l2a@-H/8=$K$h$k5!G=@-93BN%?%s%Q%/ | S-6 | insect cell transient expression antibody | 5/13 14:24:27 |
transition behavior (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-36 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
287 | Adsorption behavior of various cations and anions on zwitterionic sulfobetaine gels | S-36 | sulfobetaine transition behavior adsorption | 5/10 15:22:56 |
384 | $BN>@-%$%*%s@-%9%k%[%Y%?%$%s%]%j%^!<$N1vMO1UCf$K$*$1$kE>0\5sF0(B | S-34 | sulfobetaine polymer transition behavior UCST | 5/10 20:39:30 |
transmembrane pressure (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-45 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
337 | Membrane bioreactor$B$K$*$1$k99?77?D94|Kl:905M=B,%b%G%k$N3+H/(B | S-31 | Membrane bioreactor transmembrane pressure fouling | 5/10 17:58:18 |
800 | $BDjB.$m2a$K$*$1$kHyN3;RJ,;67O$NKl:Y9&FbF)2a$K4X$9$kD>@\?tCM%7%_%e%l!<%7%g%s(B | S-45 | transmembrane pressure direct numerical simulation immesed boundary method | 5/13 18:10:48 |
Transmittance (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-34 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
872 | Li2B4O7-BaO-P2O5-Al2O3$B7OL51tJ4Kv%,%i%9$N9=@.@.J,(BAl2O3$B$,@\CeNO!"F)2a@-!"9=B$FC@-$K5Z$\$91F6A(B | S-34 | Lead-free Transmittance Sealing | 5/13 19:23:44 |
transparent conductive film (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-33 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
844 | $B%&%'%C%H%W%m%;%9$K$h$k%U%CAG%I!<%W;@2=%9%:F)L@F3EEKl$N9=B$@)8f(B | S-33 | SnO2:F transparent conductive film spray deposition | 5/13 19:00:45 |
transport phenomena (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-2 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
899 | $B%a%?%s$r86NA$H$9$k2=3X5$Aj?;F)K!$K$h$kC:AGA!0]6/2=C:AGJ#9g:`NA@=B$2aDx$NHsDj>o%7%_%e%l!<%7%g%s(B | S-2 | reaction kinetics transport phenomena CVD | 5/13 19:49:09 |
Traveling liquidus-zone method (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-48 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
443 | $BHy>.=ENO2<$K$*$1$k(BTLZ$BK!$K$h$k(BSiGe$BC17k>=@.D9%W%m%;%9$N?tCM%7%_%e%l!<%7%g%s(B | S-48 | SiGe crystal growth Traveling liquidus-zone method Numerical simulation | 5/11 23:58:00 |
triazole derivatives (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-5 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
993 | $B%H%j%"%>!<%k%*%sM6F3BN$NG.J,2r5sF0$HJ,2r5!9=$N8!F$(B | S-5 | triazole derivatives thermal decomposition molecular orbital calculation | 5/13 21:49:13 |
Trichoderma reesei (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-6 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
745 | $B%;%k%i!<%<@8;:6]$N%;%k%i!<%<3h@-$K5Z$\$94p | S-6 | Trichoderma reesei cellulase cellulose | 5/13 17:19:06 |
trident molecule (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-43 (2$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
267 | $B%j%s;@7O41G=4p$rM-$9$k;05S>uJ,;R$K$h$k4uEZN`$NCj=P(B | S-43 | Extraction Trident molecule Rare earths | 5/10 13:40:35 |
640 | $B%"%_%I$*$h$S%&%l%"7?;05S>uJ,;RCj=P;nLt$rMQ$$$?5.6bB0%$%*%s$NCj=PFC@-I>2A(B | S-43 | precious metal trident molecule preorganized effect | 5/13 15:11:48 |
Tryptophan (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-8 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
103 | $B%+%A%*%s8r497?%_%C%/%9%b!<%I= | S-8 | Tryptophan mixed-mode resin protein separation | 5/8 10:19:01 |
TSA (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-44 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
624 | $B>x5$C&Ce7?(BTSA$B%W%m%;%9$K$h$k(BCO2$BJ,N%$N2DG=@-8!F$(B | S-44 | CO2 Separate TSA Steam Regeneration | 5/13 14:31:42 |
TSV (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-17 (2$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
565 | $BEE5$F<$a$C$-$K$h$j:n@.$7$?(BTSV$BG[@~$NG.@~KDD%78?tDc8:(B | S-17 | TSV Copper thermal expansion coeffcient | 5/13 12:37:53 |
726 | $B9b%"%9%Z%/%HHf(BTSV$B$N%7!<%IKl$N:n@=(B | S-17 | High Aspect Ratio Cu seed TSV | 5/13 17:03:18 |
TSV packaging (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-2 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
356 | [$B>7BT9V1i(B] TSV$B | S-2 | Si-DRIE Scallop-free TSV packaging | 5/10 18:47:55 |
TUAT hybrid cycle (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-1 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
318 | TUAT$B%O%$%V%j%C%I%5%$%/%k$K$h$kHnNAMQ%"%s%b%K%"?e$N@=B$$K4X$9$k8&5f(B | S-1 | Ammonia synthesis TUAT hybrid cycle Reaction Rate | 5/10 16:51:04 |
tungsten extraction (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-44 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
244 | $B:.9g%"%k%+%j?e;@2=J*MOM;1v$rMQ$$$?;HMQ:QC&>K?(G^$+$i$N%?%s%0%9%F%s!"%P%J%8%&%`$NDc29Cj=P(B | S-44 | tungsten extraction vanadium extraction De-NOx catalyst | 5/10 11:46:43 |
Tungsten trioxide (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-28 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
165 | $B%RAG2=9gJ*$N8w;@2=$N$?$a$NG.E*$K0BDj$J(BTi-W$BJ#9g8w?(G^$N9g@.(B | S-28 | Photooxidation Ionic liquid Tungsten trioxide | 5/9 09:56:07 |
Turbulent flow (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-18 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
105 | $B$;$sCG1~Ez@-$rM-$9$kEIKl$NMpN.Dq93Dc8:8z2L(B | S-18 | Turbulent flow Shear stress response Numerical simulation | 5/8 10:30:07 |
Turbulent Mixing (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-21 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
150 | [$BE8K>9V1i(B] $B%U%i%/%?%k7A>u$rMQ$$$?%_%-%7%s%0$N8&5f(B | S-21 | Turbulent Mixing Fractal Impeller CFD | 5/8 20:32:49 |
turning (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-50 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
638 | $B%3%s%]%9%H2=$K$*$1$k@Z$jJV$7$HHy@8J*AQA+0\(B | S-50 | composting turning microbial succession | 5/13 15:06:36 |
twin screw extruder (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-21 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
849 | $BFs<4%9%/%j%e2!=P5!$N?75,:.N}%(%l%a%s%H(B:$B79 2A(B | S-21 | twin screw extruder tiped-kneading disk rheology | 5/13 19:06:07 |
Two-phase flow (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-45 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
106 | v2-f$B%b%G%k$K$h$kHy:Y%_%9%HNd5Q$NJ.L8N.2r@O(B | S-48 | Fine mist cooling Two-phase flow High heat flux | 5/8 11:26:30 |
560 | $BJ?HD7?(BMF$BKl$K$*$1$k%1!<%/AX8|$5$N@)8f(B | S-45 | two-phase flow microfiltration membrane aeration | 5/13 12:23:24 |
Two-phase system (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B S-6 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
737 | $B%+%F%3!<%k@8;:%W%m%;%9$KMQ$$$kHy@8J*FsAjG]M\7O$N2~A1$K4X$9$k8&5f(B | S-6 | Hydrophobic bioproduction Two-phase system Catechol | 5/13 17:11:43 |