ライフサイエンスコーパス: wettability

1 esized with the goal of obtaining adjustable wettability.

2 d may have a major influence on leaf surface wettability.

3 f caesium to sodium can markedly enhance the wettability.

4 t have two sides with distinct chemistry and wettability.

5 s on submerged substrates that vary in their wettability.

6 amic adjustments of optical transparency and wettability.

7 surfaces with desired temperature-dependent wettability.

8 e of the porous membranes and differences in wettability.

9 es from solution using heterogeneous surface wettability.

10 ular structures that significantly influence wettability.

11 carboxylate groups that exhibit pH-dependent wettability.

12 l, and architectural traits that reduce leaf wettability.

13 or special treatment to recover the original wettability.

14 y effected color, water absorbtion index and wettability.

15 thermal/mechanical stability and electrolyte wettability.

16 y and are in accordance with the increase of wettability.

17 t role in maintaining long-term stability of wettability.

18 articles under 212mum had the lowest rate of wettability (83.40s).

19 of bulk and surface properties including the wettability, acid-base properties, adsorption, electric

20 Colloidal particles of suitable wettability adsorb strongly to liquid-liquid and liquid-

21 trapped ganglia morphology showed that this wettability allowed CO2 to create large, connected, gang

22 The PEM-coated microchannels have excellent wettability, allowing facile filling of the channels.

23 t water, have a significant influence on the wettability alteration (less oil wet) of calcite surface

24 The hypothesized cause of wettability alteration by an adsorbed organic layer on s

25 We studied pore-scale wettability and wettability alteration in scCO(2)-silica-brine systems u

26 led drainage and imbibition curves show that wettability alteration resulted from scCO2 exposure over

27 osity, can protect the surface from a strong wettability alteration.

28 ggesting a generalizable strategy to control wettability and an explanation for the success of so-cal

29 llizable diblock copolymers with appropriate wettability and chemical reactivity, and demonstrate the

30 The surface tension of matrices, and the wettability and diffusion of water and oil, were studied

31 with high acrylate content, have a moderate wettability and employ integrin alpha(v)beta(3) and alph

32 atterning on surfaces, have enhanced surface wettability and enabled control of the liquid film thick

33 Using high speed cameras, we analyzed the wettability and fluid flow dynamics of a droplet on the

34 ophilic surface of the biosensor in terms of wettability and geometry, taking into account the overal

35 An anionic surfactant was used to increase wettability and hydrophilicity of graphene; thereby faci

36 ids from the corneal surface to maintain the wettability and integrity of the ocular surface.

37 Controlling surface wettability and liquid spreading on patterned surfaces i

38 The MZO surface-wettability and morphology are controlled, offering high

39 scopy were preformed to characterize surface wettability and morphology.

40 te was replaced with methanol to improve the wettability and permeability of electrolytes in the TiO2

41 contact angle is governed by an interplay of wettability and pore geometry and can be predicted on th

42 vorable surface properties, such as improved wettability and protein resistance.

43 ion coatings with improved moisture barrier, wettability and surface adhesion onto fruit surfaces wer

44 Correlation of material properties such as wettability and surface roughness with cyst attachment r

45 wetting can be expressed as a sum of surface wettability and surface topography contributions, thus p

46 eractions that can be controlled--especially wettability and the presence of trace impurities, even o

47 drophobicity, high transparency, and tunable wettability and transmittance.

48 We studied pore-scale wettability and wettability alteration in scCO(2)-silica

49 urface chemistry (type of functional groups, wettability) and adsorbate concentration (i.e., lateral

50 niques of interfacial materials with special wettability, and assesses the environmental applications

51 anging the air/water ratio at fixed particle wettability, and has not been observed in the correspond

52 the electrode conductivity and their surface wettability are relatively small and in the range of ITO

53 organosilica Janus particles with asymmetric wettability are synthesized through a one-step compartme

54 Stomatal plugs decrease leaf wettability by preventing the formation of a continuous

55 Controlling wettability by varying surface chemistry and roughness o

56 The photo-induced wettability change of our surfaces enables external mani

57 es are of great interest due to their unique wettability change upon ultraviolet light illumination.

58 ing contact-line pinning mechanisms at sharp wettability changes to create viable dry regions in the

59 transport processes that are impacted by the wettability characteristics of formation solid phases in

60 This adhesion can significantly alter the wettability characteristics of the mineral surface and c

61 ust be sufficiently small for a simultaneous wettability characterization (from the contact angle mea

62 The mechanical, wettability, colour, light transmission, antioxidant and

63 molecule or salt that significantly altered wettability compared with controls.

64 subjects, rhinitis secretions had decreased wettability (contact angle on Teflon 100 degrees versus

65 This wettability contrast allows directed water shredding fro

66 This SDSM operates by harnessing the wettability contrast and the geometry of the patterns to

67 Surfaces with patterned wettability contrast are important in industrial applica

68 Wettability contrast between the hydrophobic polymer dot

69 We characterize the wettability contrast using local surface energy measurem

70 (from about 100 to 500 mum), morphology, and wettability contrast, respectively.

71 odification of non-porous materials, surface wettability control of porous materials, particularly si

72 The wettability detection has been carried out by a mobile c

73 This study offers wettability-engineered surfaces as a new approach to man

74 ubstrate during specimen preparation: higher wettability favours coiled conformations, whereas lower

75 The sophisticated control of surface wettability for target-specific applications has attract

76 s are rapidly assembled by combining surface-wettability-guided assembly and microdroplet-array-based

77 Interfacial materials with special wettability have become a burgeoning research area in ma

78 Surfaces with patterned domains of extreme wettability (high or low) are fabricated and implemented

79 l characterization including surface charge, wettability, hydrodynamic size, and tolerance to a wide

80 ed to be influenced significantly when water wettability in hydrophobic biological nanopores is sensi

81 Very little information on wettability in supercritical CO(2) (scCO(2))-mineral-bri

82 red hybrid membrane shows controlled surface wettability in terms of ethanol wetting and ethanol remo

83 c changes in interfacial properties, such as wettability, in response to an electrical potential.

84 Wettability is an important factor which controls the di

85 old or silicon, but not glass, for which the wettability is dominated by short-range chemical bonding

86 For the nonclays, the wettability is impacted by the pH at the point of zero c

87 3D) porous functional materials with special wettability is in urgent demand.

88 guous, and a scalable metric for quantifying wettability is needed, especially given the emergence of

89 measurement) and appropriately large so that wettability is not influenced by the presence of the wor

90 Wettability is the affinity of a liquid for a solid surf

91 The degree of wettability is then captured by the contact angle where

92 Intermediate wettability leads to various interfacial movements which

93 due to the improved light absorption, better wettability, local ordering structure, and the improved

94 Our findings indicate in general how silica wettability may be manipulated by electrolyte concentrat

95 rease bubble nucleation via roughness and/or wettability modification to increase performance.

96 er including moisture content, bulk density, wettability, morphology, encapsulation efficiency were e

97 case of the honeycomb geometry and material wettability must be considered in practical dosage form

98 compared to GNs alone is due to the improved wettability of BCNs and the ionization of liquids.

99 ned on and off, apparently because the water wettability of CNTs changed.

100 d to investigating the intrinsic and passive wettability of graphene and graphene hybrid composites.

101 role of liquid-substrate interactions on the wettability of graphene by varying the area fraction of

102 Wettability of graphene is adjusted by the formation of

103 The dependence of the wettability of graphene on the nature of the underlying

104 The wettability of graphene on various substrates has been i

105 suggest that previously reported data on the wettability of graphitic surfaces may have been affected

106 solid electrolytes can improve the interface wettability of Li metal and reduce the interfacial resis

107 We show that they additionally tune the wettability of liquid precursors of CaCO3, which is a cr

108 50 degrees C, and one of the reasons is poor wettability of liquid sodium on the surface of beta alum

109 le-based micro-/nanosonar to probe the local wettability of liquid-solid interfaces.

110 indicate that CO2-induced alteration in the wettability of mineral surfaces may significantly influe

111 The relative wettability of oil and water on solid surfaces is genera

112 lative to the walls results in an asymmetric wettability of opposing surfaces (Janus interface).

113 tions under a bias voltage that can tune the wettability of poly(3-hexylthiophene) via oxidation or r

114 Wettability of reservoir minerals and rocks is a critica

115 The wettability of selective interconnected channels is cont

116 Controlled by the wettability of the bead matrix two distinct displacement

117 By systematically varying the wettability of the flow cell over a wide range of contac

118 The wettability of the graphene surface bearing various anio

119 on, we have conducted studies to explore the wettability of the hydrophobic interiors of individual n

120 The layer increases the wettability of the liquid metal placed on oxygen-termina

121 Moreover, even a small degree of unequal wettability of the particles by the two liquids can lead

122 g whose duration can be tuned by varying the wettability of the particles, and secondly, during very

123 The wettability of the self-assembled monolayers can be modu

124 the interface to promote increased Li-metal wettability of the solid electrolyte surface and reduce

125 d desorbing charged surfactants to alter the wettability of the surface, thereby affecting nucleation

126 r oxidation without disrupting the intrinsic wettability of the surface.

127 lateral capillary forces; patterning of the wettability of the surfaces of the objects directs these

128 the shapes of the assembling objects and the wettability of their surfaces determining the structure

129 are screened by the graphene monolayer, the wettability of which is primarily determined by short-ra

130 icular conformation observed depends on the "wettability" of the substrate during specimen preparatio

131 Moreover, tunable wettability offers straightforward means to control mine

132 urface, their morphological characteristics, wettability, oil water separation efficiency and photo-c

133 owed a gated behavior due to change of water wettability on hydrophobic surface upon small temperatur

134 type of media and pore fluids, the effect of wettability on multiphase flow continues to challenge ou

135 results demonstrate the powerful control of wettability on multiphase flow in porous media, and show

136 Here, we study the impact of wettability on viscously unfavorable fluid-fluid displac

137 5.2mN/m) of banana peels, and exhibited good wettability onto banana surfaces.

138 a polyurethane elastomer film, we show that wettability patterns on both flat and curved surfaces ca

139 coatings, textured surfaces with controlled wettability, pharmaceutical and food substance printing

140 The wettability properties of the new polyfluorinated diuret

141 gative correlation between particle size and wettability (r(2)=-0.75) and positive correlation betwee

142 tion of heterogeneous surfaces with distinct wettability regions.

143 suggest that the O antigen improves surface "wettability" required for swarm colony expansion, that t

144 favours coiled conformations, whereas lower wettability results in more extended molecules.

145 uding microfluidic devices with customizable wettability, solar-driven oil-water clean-up and demulsi

146 ded microcapsules like morphology, moisture, wettability, solubility, flowability properties, swellin

147 ion suggests that differences in topography, wettability, surface charge and protein adsorption of th

148 Surface properties including wettability, surface potential, and surface charge densi

149 Jumping is governed by the surface wettability, surface temperature, hydrogel elasticity, a

150 Material properties including wettability, surface topography, surface chemistry and i

151 face micromixers (SDSM) relying on patterned-wettability technology provide an elegant solution for l

152 erties of interfacial materials with special wettability that enable innovative environmental applica

153 X-ray micro-tomography to image the in situ wettability, the distribution of contact angles, at the

154 thermal/mechanical stability and electrolyte wettability, the latter of which further improves the io

155 en may serve a role in swarming by promoting wettability, the loss of O antigen blocks a regulatory p

156 oils was developed, and the film's optical, wettability, thermal, total phenol and antioxidant chara

157 supramolecular coding system and its surface wettability to demonstrate the system's complexity, whic

158 f an insect, the palm beetle; the other uses wettability to move a particle along a trajectory.

159 ized TiO2 surface can selectively change the wettability towards contacting liquids upon visible ligh

160 Understanding the drivers of leaf wettability traits can provide insight into the effects

161 The wettability transition is due to the reaction between Li

162 rious surface engineering problems requiring wettability-tuning.

163 On surfaces with different wettability, we snapshot different condensation modes (n

164 perties such as its nucleation site density, wettability, wickability and heat transfer area.