SCEJ

$B2=3X9)3X2q(B $BBh(B81$BG/2q(B (2016)

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Microreactor2$B7o(B
Plasmon2$B7o(B
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26$BCfDxEYY{?eI=LL$K$*$1$kY{?e5sF0AjBPHf3SK!(B
($BJ!Eg9b@l(B) ($B@5(B)$B		moderate repellency
relative comparison
transient morphology
O
27$B%*%k%,%N%7%i%sM3Mh$NM-5!%7%j%+$N=L=E9g>r7o$HH/8=$5$l$kY{?e@-$NAj4X(B
($BJ!Eg9b@l@l962J(B($BJ*$B!&(B ($BJ!Eg9b@l(B) ($B@5(B)$B!{		water repellency
organic silica
poly-condensation condition
O
42$BH>F3BNI=LL$K7A@.$7$?MIF0@-?'AGJ,;RAX$N8wNe5/H?1~FC@-(B
($B6e9)Bg(B) ($B3X(B)$B!{$B!&(B $B9bDT(B $B5A9T(B$B!&(B $BB<>e(B $BD>Li(B$B!&(B ($B@5(B)$B=U;3(B $BE/Li(B		Photo-excited current
Photoacoustic spectroscopy,
Swingable molecular layer
P
171$B3&LL3IMp$K$h$kJ*
($B:eBg1!4p9)(B) ($B@5(B)$B!{H<(B $B5.I'(B$B!&(B $B1r(B $B:L9a(B		Maximum Entropy Production Principle
Marangoni Effect
Mass Transfer
O
236Unusual interfacial behavior of oil-water systems with surfactants under the influence of microwave irradiation
(U. Hyogo) ($B3$(B)$B!{(BHyde Anita$B!&(B (Curtin U.) ($B3$(B)Phan Chi$B!&(B (U. Hyogo) ($B@5(B)$BD+7'(B $BM52p(B		Interfacial tension
Microwave
Young-Laplace equation
O
321$BJ,2r@-%]%j%"%K%*%s$rMQ$$$?5!G=@-%?%s%Q%/
($B?@8MBg1!9)(B) ($B@5(B)$B!{4];3(B $BC#@8(B$B!&(B ($B3X(B)$BJ?2,(B $BN40l(B$B!&(B $B=.:j(B $BM50l(B		Layer-by-layer assembly
ultra thin film
degradable synthetic polymer
O
497$BEE>l0u2C;~$N%J%NN3;R$N;i
($B:eI\Bg9)(B) ($B3X(B)$B!{@%_7(B $B63J?(B$B!&(B ($B:eI\Bg1!9)(B) ($B@5(B)$BCgB<(B $B1QLi(B$B!&(B $B@6?e(B $B7rB@(B$B!&(B ($B@5(B)$BLJLn(B $BE/(B		nano-bio interface
nanoparticle
membrane permeation
P
530$BB?9&@-:xBNN3;R$K$*$1$k5[CeM65/9=B$JQ2=$H3H;6%a%+%K%:%`$N2rL@(B
($B5~Bg1!9)(B) ($B3X(B)$B!{Bg:j(B $B=$;J(B$B!&(B $B?9K\(B $BM:$B!&(B ($B@5(B)$BEOn5(B $BE/(B$B!&(B ($B@5(B)$BEDCf(B $B=($B!&(B ($B@5(B)$B5\86(B $BL-(B		Zeolitic imidazolate framework-8
Structural transition
Diffusion
O
563$B%W%i%:%b%K%C%/%3%"%7%'%kHyN3;R$NN.DL<09g@.$HFC@-I>2A(B
($B5~Bg9)(B) ($B@5(B)$B!{EOn5(B $BE/(B$B!&(B $BHxB<(B $B1Q><(B$B!&(B ($B@5(B)$BA0(B $B0lW"(B$B!&(B ($B@5(B)$B5\86(B $BL-(B		Microreactor
Plasmon
Core-shell particles
O
595$BJ,;R$r%W%m!<%V$H$7$?:Y9&I=LL$N%i%U%M%9I>2A(B
($B5~Bg9)(B) ($B3X(B)$B!{J?DM(B $BN6>-(B$B!&(B $B|bED(B $B7rEM(B$B!&(B ($B@5(B)$BEDCf(B $B=($B!&(B ($B@5(B)$B5\86(B $BL-(B		temperature programmed desorption
quantum effect
adsorption energy
O
624$B%l%$%d!<@QAX7?G[0LB?9&BN$,<($9B?CJ%2!<%H5[Ce8=>]$N7W;;2J3XE*8!F$(B
($B5~Bg9)(B) ($B3X(B)$B!{J?=P(B $BfFB@O:(B$B!&(B ($B3X(B)$B@P@n(B $BFACN(B$B!&(B ($B@5(B)$BEDCf(B $B=($B!&(B ($B@5(B)$B5\86(B $BL-(B		metal-organic framework
free energy analysis
structure determination
O
652$B%$%*%s1UBN6&B82<$N%j%]%=!<%`J#9g2=%;%k%i!<%<3h@-$K5Z$\$9;i
($B;38}Bg1!0e(B) ($B3X(B)$B;0JfLn(B $B3$(B$B!&(B $BBgDE(B $B9k;V(B$B!&(B ($B;38}Bg9)(B) $BBgC+(B $BIq(B$B!&(B ($B;38}Bg1!0e(B) ($B@5(B)$B!{5HK\(B $B@?(B$B!&(B $B>eB<(B $BL@CK(B		Liposomal cellulase
Phospholipid membranes
Ionic liquid
O
673$B%$%s%i%$%s8w3XB,Dj$r3hMQ$7$?6b%J%N%7%'%k7A@.%a%+%K%:%`$N2rL@(B
($B5~Bg9)(B) ($B3X(B)$B!{:Y@n(B $B=_Fs(B$B!&(B ($B@5(B)$BEOn5(B $BE/(B$B!&(B ($B@5(B)$BA0(B $B0lW"(B$B!&(B ($B@5(B)$B5\86(B $BL-(B		Plasmon
UV-vis
Microreactor
P
764$B%3%"%l%C%5!<7?L}?eJ,N%%W%m%;%9$K$*$1$kL}E)72$N9g0l5sF0$N2r@O(B
($B?@8MBg1!9)(B/$B@hC$B!&(B ($B@5(B)$B;0Ln(B $BBY;V(B$B!&(B ($BJ!2,Bg9)(B) ($B@5(B)$B?78M(B $B9@9,(B$B!&(B ($B?@8MBg1!9)(B/$B@hC>;3(B $B=(?M(B		Lattice Boltzmann method
two-phase flow
coalescing
P
840$B@"F0;}$K$*$1$k(BB4C$B%;%i%_%C%/%9$N3&LLH?1~$H%H%i%$%\%m%8!
($BL>Bg1!9)(B) ($B3X(B)$B!{1:Ln(B $B9890(B$B!&(B ($B@5(B)$B;32<(B $B@?;J(B$B!&(B ($B@5(B)$BKL(B $B1Q5*(B		boron carbide
tribology
Friction
P
888$B%"%k%3!<%k=$>~(BAOT$B%Y%7%/%k$ND4@=$J$i$S$K$=$N1~MQ(B
($B:eBg1!4p9)(B) ($B3X(B)$B!{4d:j(B $BJ8I'(B$B!&(B ($B@5(B)$B?{(B $B7C;L(B$B!&(B ($B@5(B)$B2,K\(B $B9T9-(B$B!&(B ($B@5(B)$BGO1[(B $BBg(B		vesicle
membrane property
interfacial reaction
O
893$B<+8JAH?%7O$r>l$H$7$??(G^H?1~!A(BL-Proline$B$N%j%]%=!<%`$N5[Ce$H?(G^H?1~!A(B
($B:eBg1!4p9)(B) ($B3X(B)$B!{W"@%(B $B@5E5(B$B!&(B ($B3X(B)$B@P>e(B $B6,98(B$B!&(B ($B@5(B)$B?{(B $B7C;L(B$B!&(B ($B@5(B)$B2,K\(B $B9T9-(B$B!&(B ($B@5(B)$BGO1[(B $BBg(B		L-Proline
liposome
reaction
P
903$BD6NW3&MOBN5^B.KDD%K!$rMQ$$$?%F%H%i%;%sGvKlAO@=$KBP$9$k4pHDI=LL>uBV$N1F6A(B
($B?.=#Bg1!M}9)(B) ($B3X(B)$B!{2FL\(B $B$B!&(B ($B?.=#Bg9)(B) ($B3X(B)$B>.NS(B $B5.5*(B$B!&(B ($B@5(B)$BFbED(B $BGn5W(B		RESS
Supercritical carbon dioxide
Dielectric surface conditions
P
953$B7V8wJ*e%"%_%N4p$N?75,DjNLJ}K!$N3+H/(B
($B?@8MBg1!9)(B) ($B@5(B)$B!{4];3(B $BC#@8(B$B!&(B $B1vED(B $B:L?%(B$B!&(B $B2$B!&(B ($B6eBg1!Lt(B) $B2&;RED(B $B>4IW(B$B!&(B ($B?@8MBg1!9)(B) $B@>Ln(B $B9'(B		amino group quantificationamino group quantification
fluorescent compound
surface functionalization
O
$B9V1i?=$79~$_0lMw(B($B%7%s%]%8%&%`HV9f!&9V1iJ,N`HV9fJL(B)
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$B2=3X9)3X2q(B $BBh(B81$BG/2q(B (2016)
(C) 2016 $B8x1W
Most recent update: 2016-05-19 11:21:01
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