$B:G=*99?7F|;~!'(B2014-03-05 16:19:01
database monitoring (1$B7o(B) | ||||
---|---|---|---|---|
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 6-d (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
171 | $B%=%U%H%;%s%5!<$K$*$1$k%G!<%?%Y!<%94IM}$N$?$a$N<+F0E*%Q%i%a!<%?A*Br(B | 6-d | soft sensor database monitoring process control | 12/24 10:14:23 |
DC electric field (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 13-b (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
78 | $BD>N.EE>l$rMxMQ$7$?1UCfHyN3;R6E=85;=Q$N3+H/(B | 13-b | DC electric field slurry flocculation | 12/18 11:40:06 |
DCFC (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 9-e (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
463 | $BHyJ4C:%A%c!<$rD>@\G3NA$H$9$k%P%V%j%s%07?%@%$%l%/%H%+!<%\%sG3NAEECS$N3+H/(B | 9-e | DCFC Char Bubbling | 12/26 19:27:48 |
DCFC(direct carbon fuel cell) (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 9-c (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
335 | $BD>@\C:AGG3NAEECS(B(DCFC)$BMQG3NA$H$=$NH/EEFC@-(B | 9-c | DCFC(direct carbon fuel cell) carbonate carbonaceous fuel | 12/26 10:51:25 |
decane oxidation activity (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 5-a (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
219 | $BM-5!2=9gJ*E:2C$7$FD4@=$7$?C4;}(BPt$B?(G^$N%G%+%s;@2=3h@-(B | 5-a | Pt catalyst Myristic Acid decane oxidation activity | 12/24 17:31:29 |
decellularized liver (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 7-e (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
727 | $BC&:YK&2=4NB!Cr7?$H$7$?4N:YK&G]M\5Z$S(Bex vivo$B$K$h$k5!G=I>2A(B | 7-e | liver decellularized liver functional evaluation | 12/27 17:55:49 |
DECONTAMINATION (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 13-b (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
783 | $B<'@-%a%=%]!<%i%9C:AG$K$h$kJ| | 13-b | DECONTAMINATION CARBON COMPOSITE MAGNETIC SEPARATION | 12/27 19:58:20 |
degradation (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 9-e (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
532 | $B;@2=4T85J70O5$$K$*$1$k8GBN;@2=J*7AG3NAEECS$NEE6KEE2r | 9-e | solid oxide fuel cell cation diffusion degradation | 12/27 11:47:05 |
dehydration (4$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 4-a (3$B7o(B), 4-c (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
211 | SAPO-18$BKl$N9g@.$H?e(B/$B?];@F)2aJ,N%@-G=$N8!F$(B ($BAaBg@h?JM}9)(B/$BAaBgM}9)Am8&(B/JST-CREST) ($B@5(B)$B>>J}(B $B@5I'!&(B | 4-a | SAPO-18 membrane vapor permeation dehydration | 12/24 16:57:01 |
256 | $B%V%?%sMOG^Cj=P>xN1C&?eK!$K$h$k%P%$%*%(%?%N!<%k$N9b8zN(>J%(%MC&?e$K4X$9$k;n837k2L(B | 4-c | distillation dehydration bio-ethanol | 12/25 12:03:41 |
654 | IPA$BC&?eMQ%<%*%i%$%HKl$N3+H/>u67(B | 4-a | Zeolite membrane Dehydration Isopropyl achohol | 12/27 16:09:05 |
766 | $B9bF)2aEY$J;Y;}BN>e$X$N(BNaY$B7?%<%*%i%$%HKl@=Kl | 4-a | NaY zeolite Membrane Dehydration | 12/27 19:15:15 |
Dehydration and drying rate (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 9-f (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
810 | $B1xE%BOHn2=4%Ag%W%m%;%9$K$*$1$kC&?e!&4%AgB.EY$N?d;;(B | 9-f | Sludge Composting dry Dehydration and drying rate | 12/27 21:37:29 |
dehydration of hydrogel (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 12-e (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
240 | $B2sE>N.F0AX$K$h$k4^?e@-%2%k>uJ* | 12-e | dehydration of hydrogel functional porous media rotating fluidized bed | 12/25 09:46:11 |
dehydration of propane (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 4-a (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
45 | $B%W%m%Q%s$NC&?eAGMQ%G%s%I%i%$%H(BPd$BKlH?1~4o$N3+H/(B | 4-a | Pd membrane dehydration of propane dendritic structures | 12/12 13:48:13 |
Dehydration Response Curves (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 7-h (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
758 | $BLn:Z4%Ag9)Dx$N%a%$%i!<%IH?1~5!9=$r@_7W$9$k(B | 7-h | Consecutive Reaction Model Dehydration Response Curves Effective Water Diffusivity | 12/27 18:49:47 |
Dehydrogenation of propane (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 5-a (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
11 | Cr$B7O%Z%m%V%9%+%$%H7?;@2=J*$N%W%m%Q%sC&?eAGFC@-(B | 5-a | Dehydrogenation of propane Perovskite Steam | 11/26 13:32:22 |
DEM simulation (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 2-c (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
722 | $BL5 | 2-c | Fluidized bed DEM simulation Nondimensionalization | 12/27 17:46:20 |
dendritic polymer (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 12-e (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
454 | Multi-arm star block copolymer$B$N%$%*%s2M66%a%+%K%:%`$N2rL@(B | 12-e | dendritic polymer hydrogel ion-crosslinking | 12/26 18:44:19 |
dendritic structures (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 4-a (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
45 | $B%W%m%Q%s$NC&?eAGMQ%G%s%I%i%$%H(BPd$BKlH?1~4o$N3+H/(B | 4-a | Pd membrane dehydration of propane dendritic structures | 12/12 13:48:13 |
Dendron (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B F-1 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
440 | $BC1J,;65e>u%J%NN3;RI=LL$X$N%G%s%I%m%s=$>~$K$h$k%J%N%U%k%$%I$ND4@=$H%J%NAH?%9=B$2r@O(B | F-1 | Nanofluid Dendron Self-Organization | 12/26 17:53:08 |
Dense Gas Dispersion (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 10-e (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
86 | $B1U2=E7A3%,%9$N3$>eO3$($$$K$*$1$k%,%93H;6M=B,$K4X$9$k8&5f(B | 10-e | Liquefied Natural Gas Hazard Analysis Dense Gas Dispersion | 12/19 11:44:48 |
Density (3$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 1-a (3$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
125 | $B9b299b05%"%k%3!<%k?eMO1U$NL)EY!&G4EYB,Dj$*$h$S?d;;K!$N9=C[(B | 1-a | Density Viscosity alcohol+water mixture | 12/20 13:23:30 |
421 | 293.15 K$B$K$*$1$k%8%a%A%k%(!<%F%k(B+$B%(%?%N!<%k7O$NBN@Q5sF0$KBP$9$k05NO8z2L(B | 1-a | dimethyl ether density high pressure | 12/26 17:19:07 |
459 | $B%8%0%i%$%`$NFs;@2=C:AGMO2rEY$K5Z$\$9%j%A%&%`1v8z2L(B | 1-a | CO2 solubility diglyme density | 12/26 18:58:48 |
Density Functional Theory (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 9-e (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
354 | $B%"%k%+%j7AG3NAEECS$NEE2r | 9-e | Molecular Dynamics Anion Exchange Membrane Density Functional Theory | 12/26 13:28:48 |
deposition (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 8-e (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
238 | $BD6NW3&Fs;@2=C:AG$rMxMQ$7$?%]%j%$%_%IGvKl$N:n@=(B | 8-e | supercritical carbon dioxide polyimide deposition | 12/24 23:43:56 |
842 | $B%(%"%m%>%kN3;R$N2YEE$H8GBNI=LL$X$ND@Ce@)8f(B | 2-f | aerosol charging deposition | 12/28 14:01:47 |
Depressurized distillation (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 4-c (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
5 | $B%P%$%*%(%?%N!<%kG;=L>xN1%W%m%;%9$N8:057O(BHIDiC$B2=(B | 4-c | Depressurized distillation Bioethanol HIDiC | 11/15 14:58:43 |
design (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 7-f (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
27 | $B@8J*3XE*4pK\%M%C%H%o!<%/$NAH$_N)$F$K$h$k%@%$%J%_%C%/%b%G%k$N9gM}E*@_7W(B | 7-f | design network dynami model | 12/1 10:35:03 |
Desulfurization (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 5-c (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
246 | $B@EEEHyN32=K!$rMQ$$$??75,C&N2%W%m%;%9$N3+H/(B | 5-c | Electrostatic Spray Desulfurization Exhaust Gas Treatment | 12/25 10:59:03 |
dewatering (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 8-c (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
433 | $B1U2=(BDME$B$rMQ$$$?4;5L2LHi$*$h$SMU$+$i$N?e$HM-2AJ*$NF1;~Cj=P(B | 8-c | liqufied DME citrus peel dewatering | 12/26 17:41:51 |
Diabatic Distillation (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 4-c (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
4 | Performance Evaluation of Horizontal Diabatic Distillation | 4-c | Horizontal Distillation Diabatic Distillation Rate-Based Model | 11/15 10:55:20 |
Diafiltration (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 4-a (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
436 | $B%@%$%"%U%#%k%H%l!<%7%g%s$K$h$kN3;RKlJ,5i(B | 4-a | Membrane Classification Diafiltration | 12/26 17:46:51 |
diagnosis (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B F-3 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
167 | [$B>7BT9V1i(B]$B9b29@_Hw$N?GCG$H | F-3 | remaining life estimation diagnosis boiler | 12/24 08:57:51 |
dialysis (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 7-e (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
648 | $BF)@OK!$rMQ$$$?%R%H(BiPS$B:YK&7|ByG]M\G]CO$N%j%5%$%/%kMxMQ(B | 7-e | human induced pluripotent stem cells dialysis suspension culture | 12/27 16:03:31 |
diamond (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 5-h (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
396 | $B%Q%k%9(BDC$B%W%i%:%^(BCVD$BK!$K$h$k%@%$%d%b%s%I@.D9B.EYHf(B([100]/[111])$B$N@)8f(B | 5-h | pulsed DC plasma-assisted chemical vapor deposition diamond growth rate ratio | 12/26 15:50:01 |
dielectric barrier discharges (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B K-2 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
95 | [$B>7BT9V1i(B]Removal of diesel PM by dielectric barrier discharges | K-2 | diesel PM dielectric barrier discharges removal | 12/19 14:09:13 |
dielectric constant (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 2-f (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
159 | $BM6EEN($K$h$kHyN3;R%3%s%]%8%C%H:`NAFb%U%#%i! | 2-f | dielectric constant composite material dispersion state | 12/23 12:40:55 |
dielectrophoresis (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 4-b (2$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
183 | $B%+!<%\%s%J%N%A%e!<%VEE6K$rMQ$$$?%J%NN3;R$NM6EE1KF0J,N%5;=Q$N3+H/(B | 4-b | dielectrophoresis particle separation carbon nanotube | 12/24 12:42:33 |
829 | $B%+!<%\%s%J%N%A%e!<%V$rEE6K$KMxMQ$7$?HyN3;R$NM6EE1KF0J,N%(B | 4-b | dielectrophoresis particle carbon nanotube | 12/27 22:56:52 |
diesel PM (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B K-2 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
95 | [$B>7BT9V1i(B]Removal of diesel PM by dielectric barrier discharges | K-2 | diesel PM dielectric barrier discharges removal | 12/19 14:09:13 |
diffusion (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 12-h (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
529 | $B1UBN5Z$SD6NW3&>uBVCf$K$*$1$k6bB0:xBN$N3H;678?t$NB,Dj(B | 8-b | diffusion metal complex chromatography | 12/27 11:36:22 |
818 | $BGvKl%(%^%k%7%g%sEINA$N0l | 12-h | rheology particle accumulation diffusion | 12/27 21:59:21 |
Diffusion coefficient (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 1-a (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
175 | $BD6NW3&Fs;@2=C:AGCf$K$*$1$k3F | 1-a | Diffusion coefficient Metal complex Supercritical | 12/24 10:30:26 |
diglycolamic acid (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 4-f (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
247 | $B%8%0%j%3!<%k%"%_%I;@$N4D>u2=$HCj=PJ,N%$K5Z$\$91F6A(B | 4-f | diglycolamic acid calixarene lanthanide | 12/25 11:04:29 |
diglyme (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 1-a (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
459 | $B%8%0%i%$%`$NFs;@2=C:AGMO2rEY$K5Z$\$9%j%A%&%`1v8z2L(B | 1-a | CO2 solubility diglyme density | 12/26 18:58:48 |
Dimensionless number (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 2-a (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
155 | $B3J;R%\%k%D%^%sK!$K$h$kC10l1_Cl>c32J*$r2#@Z$k(BCarreau$B%b%G%kN.BNN.$l$N?tCM2r@O(B | 2-a | Lattice Boltzmann method Carreau model Dimensionless number | 12/22 20:49:59 |
dimethyl ether (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 1-a (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
421 | 293.15 K$B$K$*$1$k%8%a%A%k%(!<%F%k(B+$B%(%?%N!<%k7O$NBN@Q5sF0$KBP$9$k05NO8z2L(B | 1-a | dimethyl ether density high pressure | 12/26 17:19:07 |
Diquaternary ammonium cations (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 12-i (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
629 | $BM-5!9=B$5,Dj:^$H$7$F%U%l%-%7%V%k$J%8;M5i%8%"%s%b%K%&%`%+%A%*%s$rMQ$$$?%<%*%i%$%H$N9g@.(B | 12-i | Morphology control MFI-type zeolite Diquaternary ammonium cations | 12/27 15:34:17 |
direct alcohol fuel cell (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B F-2 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
618 | $BD>@\%"%k%3!<%kG3NAEECS$N9b=PNO2=$K8~$1$?%J%N9=B$?(G^$H?(G^AX9=B$$N8!F$(B | F-2 | composite carbon nanofiber direct alcohol fuel cell catalyst layer structure | 12/27 15:14:47 |
Direct carbon fuel cell (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 9-e (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
474 | $BC10l%+!<%\%sN3;R$rMQ$$$?%@%$%l%/%H%+!<%\%sG3NAEECS$K$*$1$k%"%N!<%IH?1~5sF0$N2rL@(B | 9-e | Direct carbon fuel cell anode reaction single carbon | 12/26 21:09:01 |
direct formic acid fuel cell (3$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 9-e (3$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
346 | $BD>@\%.;@7AG3NAEECS$N=PNODc2<5sF0$K$*$h$\$9J* | 9-e | Direct formic acid fuel cell Mass transport Over potential | 12/26 12:26:54 |
347 | $B?75,?(G^C4BN$K$h$kD>@\%.;@7AG3NAEECS$N?(G^HoFG$NM^@)(B | 9-e | direct formic acid fuel cell carbon nanofiber catalyst support | 12/26 12:26:55 |
617 | $BD>@\%.;@7AG3NAEECS$NEE6K2aEE055sF0$K$*$h$\$9H/EE29EY$N1F6A(B | 9-e | Direct Formic Acid Fuel Cell Mass Transport Electrode structure | 12/27 15:10:49 |
Direct fuel cell (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 9-e (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
303 | $BD>@\G3NAEECS$KMQ$$$k%J%N%U%!%$%P!(G^$K$*$1$k%U%!%$%P!<9=B$$H3h@-$N4X78(B | 9-e | Direct fuel cell Electrocatalyst Carbon nanofiber | 12/25 18:19:41 |
Direct Methanol Fuel Cell (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 9-e (2$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
304 | $B%A%?%K%"=$>~(BCNF$BC4BN$rMQ$$$?%a%?%N!<%k;@2=EE6K?(G^(B | 9-e | TiO2 modified CNF support Electrode catalyst Direct Methanol Fuel Cell | 12/25 18:20:54 |
659 | $B:Y9&%U%#%j%s%0EE2r | 9-e | direct methanol fuel cell pore-filling membrane alkaline fuel cell | 12/27 16:24:39 |
direct numerical simulation (4$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 4-a (2$B7o(B), 12-i (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
134 | $BMO | F-1 | dispersion direct numerical simulation solute adsorption | 12/20 16:39:47 |
151 | $BC1=cQrCG>l$K$*$1$k%J%NN3;R6E=8BN$N2r:U%7%_%e%l!<%7%g%s(B | 12-i | direct numerical simulation shear flow breakup of aggregates | 12/22 18:22:27 |
649 | Phase field$BK!$HD>@\?tCM%7%_%e%l!<%7%g%s$NO"7H$HN3;RJ,;67O$NKl:Y9&F)2a$X$NE,MQ(B | 4-a | Microfiltration Direct numerical simulation Phase field method | 12/27 16:05:21 |
692 | $B9bJ,;RMO1U$NAjJ,N%$HHyN3;RJ,;61UN.$l$NO"7H%7%_%e%l!<%7%g%s$K$h$k:Y9&F)2a5sF0$N8!F$(B | 4-a | microfiltration direct numerical simulation phase field method | 12/27 17:00:19 |
Discharge Product (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 9-e (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
191 | $B%j%A%&%`6u5$EECS%+%=!<%I$K$*$1$k(BLi2O2$B$N3H;6$K4X$9$kBh0l86M}J,;RF0NO3X7W;;(B | 9-e | Li O2 Battery First Principles Molecular Dynamics Discharge Product | 12/24 13:38:02 |
discontinuity (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 6-d (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
181 | $BITO"B3A`:nNL$rM-$9$k%W%i%s%H$KBP$9$k@)8f4o$N@_7W(B | 6-d | controller design discontinuity limit cycle | 12/24 12:07:48 |
discrete element method (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 2-f (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
264 | $BId9fIU5wN%4X?t$rMQ$$$?N%;6MWAGK!$NJI6-3&%b%G%k$N3+H/$H;:6H1~MQ(B | 2-f | discrete element method signed distance function granular flow | 12/25 13:58:08 |
discussion (3$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B F-7 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
699 | $BF$O@(B | F-5 | discussion chemical industry petrochemical technology | 12/27 17:08:23 |
849 | $BAm9gF$O@(B | F-7 | invited discussion fukushima | 12/30 10:35:06 |
854 | $BAm9gF$O@(B | F-1 | nanofluid discussion | 1/7 15:11:20 |
dispersibility (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 7-a (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
292 | $BFq?eMO@-J*C2=%Z%W%A%IJ#9gBN$ND4@=$H?eG^BNCf$G$N9=B$(B | 7-a | solubility dispersibility bioavailability | 12/25 17:19:56 |
dispersion (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 8-b (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
134 | $BMO | F-1 | dispersion direct numerical simulation solute adsorption | 12/20 16:39:47 |
728 | $BJ,;66E=85sF0$K$h$kL55!%J%NN3;R$HMOG^$H$N?FOB@-$K4X$9$k8!F$(B | 8-b | nanoparticles dispersion aggregation | 12/27 17:56:18 |
Dispersion and aggregation (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B F-1 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
745 | $BM-5!=$>~L55!%J%NN3;R$NJ,;6!&6E=85sF0$K4X$9$k?tCM7W;;(B | F-1 | organic-modified nanoparticles numerical simulation Dispersion and aggregation | 12/27 18:20:26 |
dispersion polymerization (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 8-e (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
397 | $BD6NW3&Fs;@2=C:AGCf$K$*$1$k(BPMMA$BHyN3;R$N9g@.(B | 8-e | supercritical carbon dioxide dispersion polymerization particle | 12/26 15:58:24 |
dispersion state (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 2-f (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
159 | $BM6EEN($K$h$kHyN3;R%3%s%]%8%C%H:`NAFb%U%#%i! | 2-f | dielectric constant composite material dispersion state | 12/23 12:40:55 |
dispersion-filtration process (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 12-i (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
195 | $B%+!<%\%s%J%N%A%e!<%V!&%U%l%-%7%V%kEE6K!&G[@~$N%m%9%U%j! | 12-i | carbon nanotubes flexible electrodes and wirings dispersion-filtration process | 12/24 14:04:25 |
Dissolution behavior (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 12-g (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
172 | $B%/%m%`(B($B-7(B)$B%$%*%sB8:_2<$G$NN2;@%+%j%&%`7k>=$NMO2r5sF0(B | 12-g | Dissolution behavior Additives Potassium Sulfate Crystal | 12/24 10:17:53 |
Dissolved ozone concentration (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 2-d (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
802 | $B%^%$%/%m%P%V%kJ,;6$K$*$1$k?e$X$N%*%>%s5[<}(B | 2-d | Micro-bubble dispersion Ozone absorption Dissolved ozone concentration | 12/27 21:25:14 |
distillation (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 1-a (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
256 | $B%V%?%sMOG^Cj=P>xN1C&?eK!$K$h$k%P%$%*%(%?%N!<%k$N9b8zN(>J%(%MC&?e$K4X$9$k;n837k2L(B | 4-c | distillation dehydration bio-ethanol | 12/25 12:03:41 |
504 | $B5$1UJ?9U$K$*$1$k(BNRTL$B<0$N5sF0(B | 1-a | vapor-liquid equilibrium distillation NRTL equation | 12/27 10:16:04 |
Distillation column diameter (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 4-c (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
6 | HIDiC $B%7%9%F%`$NE,MQ@-$HEc7B$N4X78$K$D$$$F(B | 4-c | HIDiC Distillation column diameter Internal heat transfer area | 11/15 15:33:25 |
DMAFC (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 4-a (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
652 | PVA$B7OEE2r | 4-a | DMAFC PVA Polymer electrolyte | 12/27 16:06:59 |
DNA (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 12-j (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
513 | DNA$BJ#9g2=J,;RG'<1%2!<%HKl$N3+H/(B | 12-j | molecular recognition DNA gating membrane | 12/27 10:52:44 |
DNA aptamer-enzyme conjugate (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 7-b (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
482 | DNA$B%"%W%?%^! | 7-b | Terminal deoxynucleotidyl transferase Microbial transglutaminase DNA aptamer-enzyme conjugate | 12/27 01:36:02 |
DNA-enzyme conugate (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B K-3 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
8 | [$B>7BT9V1i(B] Protein Assembly Design by Enzymatic Conjugation and Scaffolding | K-3 | Protein assembly Enzymatic protein modification DNA-enzyme conugate | 11/19 11:22:44 |
dolomite (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 5-g (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
233 | Co$B$rC4;}$7$?%I%m%^%$%H5Z$S3-3L$K$h$k%?%k$N?e>x5$2~ | 5-g | Cobalt catalyst dolomite tar reforming | 12/24 21:58:59 |
dominant factor (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 13-a (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
379 | Influence of cyanobacteria forming mechanism on the eutrophication of shallow lakes | 13-a | cyanobacteria lake eutrophication dominant factor | 12/26 14:41:24 |
Dot Matrix Analysis (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 6-f (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
17 | $B%I%C%H%^%H%j%C%/%9K!$K$h$k%W%i%s%H1?E>%G!<%?$+$i$NO":?%"%i!<%`$NCj=P(B | 6-f | Alarm System Sequential Alarms Dot Matrix Analysis | 11/28 11:29:12 |
Double emulsions (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 12-b (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
128 | $B8wB$7AK!$K$h$k(B3$B | 12-b | Microfluidics Double emulsions Stereolithography | 12/20 14:32:20 |
draft tube (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 2-c (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
255 | $B%I%i%U%H%A%e!<%VIU$-J.N.AX$NN.F0FC@-$KM?$($k%A%e!<%V7A>u$HN3;RJ*@-$N1F6A(B | 2-c | spouted bed draft tube annulus gas flow rate | 12/25 11:53:09 |
Drag reduction (3$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 2-g (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
36 | $B%^%$%/%m%P%V%k0lMME:2C$K$h$k>e>:%A%c%M%kMpN.HsDj>o5sF0$NJQ2=(B | 2-e | Microbubbles Turbulence modulation Drag reduction | 12/10 12:10:54 |
187 | $BG12sBJ1_7A>u$rM-$9$kEE@~$NDcIw052=%a%+%K%:%`$K4X$9$k?tCM2r@O(B | 2-g | Spiral elliptic wire Drag reduction Numerical simulation | 12/24 13:16:15 |
381 | $BN.BNF)2a@-$rM-$9$kB?9& | 2-a | Porous media Turbulent channel flow Drag reduction | 12/26 14:49:36 |
dredged soil (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 13-f (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
446 | $B@u>lB$@.$X$NMxMQ$r;V8~$7$?@=9]%9%i%0$N8G2=M^@)(B | 13-f | steel slag dredged soil shear stress | 12/26 18:24:20 |
Dripping-Jetting Transition (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 2-e (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
16 | $B1U1U7O!"1UE)@8@.$K$*$1$k(BDripping-Jetting$BA+0\(B | 2-e | Ohnesorge Number Front-tracking Dripping-Jetting Transition | 11/28 09:33:33 |
droplet shape (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 2-a (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
428 | $B?6F0>l$K$*$1$kHy>.1UE)$N;0Aj@\?(@~$,5$1U3&LL7A>u$K5Z$\$91F6A(B | 2-a | dynamic surface tension contact line droplet shape | 12/26 17:35:57 |
drug delivery (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 7-e (2$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
666 | $B%J%N%3!<%F%#%s%0%-%c%j%"$K$h$kLtJ*$N:YK&Fb%G%j%P%j!<$H%Z%W%A%I=$>~$N8z2L(B | 7-e | drug delivery emulsion peptide | 12/27 16:31:39 |
741 | $B%R%"%k%m%s;@%J%N%2%k$rMQ$$$?93$,$s:^=yJ|%7%9%F%`$N3+H/(B | 7-e | Drug Delivery Hyaluronan Peritoneal metastasis | 12/27 18:14:56 |
Drug derivery system (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 7-e (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
583 | Smart$B;i | 7-e | Membranome Smart Lipid Drug derivery system | 12/27 13:58:08 |
drug discovery (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B K-3 (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
13 | [$B>7BT9V1i(B] Reconstitution of in vivo-like blood vasculature for drug evaluation | K-3 | 3D culture drug discovery | 11/27 12:54:09 |
Dry anaerobic digestion residue (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 13-a (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
605 | $B4%<0%a%?%sH/9Z;D^V$r;\MQ$7$?B?<}JF;tNA%$%M?eED$K$*$1$kCbAG<};Y$NI>2A(B | 13-a | Dry anaerobic digestion residue Paddy field nitrogen dynamics | 12/27 14:38:01 |
Dry reforming (2$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 5-a (2$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
535 | $BC4;}(BNi$B?(G^>e$G$N%a%?%s$N%I%i%$%j%U%)!<%_%s%0H?1~$K$*$1$kC4BN8z2L(B | 5-a | Dry reforming Support effect Carbon deposition | 12/27 11:49:58 |
719 | Effect of Reaction Temperature and CO2 Flowrate on Dry Reforming of Tetradecane Using Preoxidized SUS304 as Catalyst | 5-a | SUS304 Tetradecane Dry Reforming | 12/27 17:44:44 |
Dry thermophilic methane fermentation (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 13-b (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
556 | $BFZ$U$sG"$H2O@nI_$N%P%$%*%^%9$H$N9b294%<0%a%?%sH/9ZFC@-$N2rL@(B | 13-b | Dry thermophilic methane fermentation swine wastewater biomass | 12/27 13:15:36 |
dry-etching (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 5-h (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
163 | $B%(%C%A%s%0@O=PK!$K$h$k(BCo-C$B:.9gKl$+$i$NGvAX%0%i%U%'%s$NM6EEBN4pHD>eD>@\7A@.(B | 5-h | graphene crystal growth dry-etching | 12/23 14:44:28 |
drying (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 12-i (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
227 | $B?tCM%7%_%e%l!<%7%g%s$rMQ$$$?(B2$BN3;R7OMO1U$N4%Ag2aDx$K$*$1$kLS4I05NO$N1F6A$N8!F$(B | 12-i | drying capillary pressure colloidal ink | 12/24 19:16:45 |
Drying and desorption (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 3-d (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
413 | $B9b4^?e%<%*%i%$%H= | 3-d | Packed bed Numerical simulation Drying and desorption | 12/26 16:50:43 |
durability (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 5-a (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
245 | $B9bBQ5W@-F(G^$N9b29%a%?%N!<%k?e>x5$2~ | 5-a | Cu catalyst hydrogen durability | 12/25 10:49:31 |
Dutch woven mesh (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 2-f (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
252 | $B?tCM%7%_%e%l!<%7%g%s$K$h$k>v?%6bLV$N$m:`9=B$$,05NOB;<:$K5Z$\$91F6A$N8!F$(B | 2-f | Dutch woven mesh Lattice Boltzmann method Pressure drop | 12/25 11:36:38 |
dynami model (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 7-f (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
27 | $B@8J*3XE*4pK\%M%C%H%o!<%/$NAH$_N)$F$K$h$k%@%$%J%_%C%/%b%G%k$N9gM}E*@_7W(B | 7-f | design network dynami model | 12/1 10:35:03 |
dynamic surface tension (1$B7o(B) | ||||
$B$3$N%-!<%o!<%I$,$h$/;H$o$l$F$$$k%7%s%]%8%&%`!&9V1iJ,N`!'(B 2-a (1$B7o(B) | ||||
$B | $B9V1iBjL\!?H/I=$B%-!<%o!<%I(B | $B | | |
428 | $B?6F0>l$K$*$1$kHy>.1UE)$N;0Aj@\?(@~$,5$1U3&LL7A>u$K5Z$\$91F6A(B | 2-a | dynamic surface tension contact line droplet shape | 12/26 17:35:57 |