ライフサイエンスコーパス: wettability

1 stem pressure, surface roughness, and liquid wettability.

2 y effected color, water absorbtion index and wettability.

3 thermal/mechanical stability and electrolyte wettability.

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

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

6 esized with the goal of obtaining adjustable wettability.

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

8 f caesium to sodium can markedly enhance the wettability.

9 t have two sides with distinct chemistry and wettability.

10 s on submerged substrates that vary in their wettability.

11 amic adjustments of optical transparency and wettability.

12 surfaces with desired temperature-dependent wettability.

13 e of the porous membranes and differences in wettability.

14 es from solution using heterogeneous surface wettability.

15 ular structures that significantly influence wettability.

16 surface roughness, chemical composition, and wettability.

17 carboxylate groups that exhibit pH-dependent wettability.

18 solubility, and Hi-Cap 100 reported the best wettability.

19 n films on various substrates with different wettability.

20 guide fluid flow into desired areas of high wettability.

21 nd correlated with surface morphology and/or wettability.

22 ear, which are the main factors of change in wettability.

23 es that varied in both surface roughness and wettability.

24 oring of a wide range of bio-inspired liquid wettability.

25 ydrophobic cuticle, thereby lowering surface wettability.

26 external instrumentation to pattern channel wettability.

27 pin crossover (SCO), redox, temperature, and wettability.

28 , most rocks display spatially heterogeneous wettability.

29 proximity, resulting in substantially lower wettability.

30 ion between material icephobicity and liquid wettability.

31 tropy to the scale geometry, compliance, and wettability.

32 or special treatment to recover the original wettability.

33 l, and architectural traits that reduce leaf wettability.

34 nt in PDA with various surfaces of different wettabilities.

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

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

37 )-responsive shell that allows for on-demand wettability adjustments.

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

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

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

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

42 Wettability alteration and bubble-oil pinch-off were ide

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

44 rtiary oil recovery impedes the potential of wettability alteration for additional oil recovery.

45 Wettability alteration from a more oil-wetting to a more

46 the high salinity water, ii) how continuous wettability alteration impacts the redistribution of two

47 c two-phase flow, hydrodynamic transport and wettability alteration in a 2D domain were carried out u

48 is found to be an insufficient condition for wettability alteration in carbonate minerals.

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

50 bial enhanced oil recovery (MEOR) processes, wettability alteration is considered a crucial mechanism

51 literature, and the underlying mechanism of wettability alteration is controversial.

52 To understand the full picture of wettability alteration of a rock by injection of low sal

53 sodium hydroxide up to 2000 mg/L led to the wettability alteration of the reservoir rock from oil-we

54 ct of low IFT at the oil-water interface and wettability alteration on surfactant-enhanced oil displa

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

56 despite greater interfacial tensions, due to wettability alteration towards water-wet conditions and

57 Subsequently, wettability alteration was the dominant mechanism during

58 possible mechanisms of low-salinity-induced wettability alteration, including rock/oil charge repuls

59 To induce the wettability alteration, low salinity water should be tra

60 tive indicator - but not the root cause - of wettability alteration.

61 the formation brine (high salinity water) in wettability alteration.

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

63 We also monitor the micro-wettability alterations of gold surface of the QCM owing

64 The wettability analysis of the nanofibers showed hydrophili

65 P for different fluids under various surface wettabilities and ambient pressures.

66 Here, we report on the role of solid wettability and adhesion on these transitions.

67 However, poor wettability and agglomeration of self-assembled molecule

68 roposing a generalizable strategy to control wettability and an elucidation for the profitability of

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

70 sue integration with significantly increased wettability and changes in thermal stability and element

71 of channel permeability, whereby the surface wettability and charge can be tuned by metal ions and DN

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

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

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

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

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

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

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

79 factants, and salt solutions, to modify rock wettability and improve conditions for enhanced oil reco

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

81 rogravity, such as bubble formation, surface wettability and liquid evaporation.

82 Controlling surface wettability and liquid spreading on patterned surfaces i

83 Understanding wettability and mechanisms of wetting transition are imp

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

85 scopy were preformed to characterize surface wettability and morphology.

86 us, and independent tailoring of both liquid wettability and other relevant physical properties.

87 g an insight into the impact of the particle wettability and particle concentration.

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

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

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

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

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

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

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

95 ion were studied previously to examine PET's wettability and the SE.

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

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

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

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

100 marked dynamical heterogeneity, interfacial wettability, and asymmetric salt-bridging propensity.

101 protocols resulted in changes in roughness, wettability, and chemical composition, but GCHL, SC, TiB

102 er, the high salt cost, high viscosity, poor wettability, and environmental hazards remain a great ch

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

104 water uptake and permeability, improved the wettability, and increased the biodegradability in seawa

105 Janus colloidal surfactants with opposing wettabilities are receiving attention for their practica

106 ic framework (COF) membranes with asymmetric wettability are developed to construct triphase interfac

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

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

109 ent modalities on PEEK's surface morphology, wettability (as measured by contact angle), and shear bo

110 ast, we studied (3) the effect of UV/O(3) on wettability at different timeframes and addressed (4) ho

111 ritical CO(2) injection rate and the surface wettability at the reservoir temperature and pressure.

112 the liquid in real time revealed distinctive wettability behaviour associated with specific potential

113 he membrane properties and the difference in wettability between its two faces.

114 HFG compounds display wettability between the extremes of pure FG with contact

115 ion by energy dispersive X-ray spectroscopy, wettability by meniscus technique, and roughness by an o

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

117 Controlling wettability by varying surface chemistry and roughness o

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

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

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

121 ine interfaces were measured to characterize wettability changes within the pore space and calculate

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

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

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

125 ing pectin (which may confer flexibility and wettability); chloroplasts within the vascular cylinder;

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

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

128 ssues such as high viscosity and sub-optimal wettability, compromise their suitability for commercial

129 ne in stagnant regions created heterogeneous wettability conditions at the pore scale, which led to r

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

131 This wettability contrast allows directed water shredding fro

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

133 Surfaces with patterned wettability contrast are important in industrial applica

134 Wettability contrast between the hydrophobic polymer dot

135 We characterize the wettability contrast using local surface energy measurem

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

137 rfaces generally involve the generation of a wettability contrast.

138 Wettability control of carbonates is a central concept f

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

140 ed with surface modifications by silanes for wettability control.

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

142 polymer surfaces resulted in more comparable wettability, effectively masking the initial polymer pro

143 ently, the Iranian plaster displays enhanced wettability, enabling its direct use for water-based dec

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

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

146 The colorimetric and water wettability features of as-synthesized AgNRs are found t

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

148 at can explain the alteration of the surface wettability from adjusting the design parameters of the

149 more IFT reduction and altering the surface wettability from oil-wet to strongly water-wet.

150 could significantly change the glass surface wettability from oil-wet to water-wet, which showed a be

151 surfaces (PaLS) that combine the controlled wettability from patterning with the ultrasmoothness of

152 reservoir properties including pore surface wettability, gas sorption capacity, and transport proper

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

154 ion while simultaneously controlling surface wettability, has been lacking.

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

156 show that certain spatial configurations of wettability heterogeneity at the microscale, e.g. being

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

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

159 nhances oil recovery by altering the mineral wettability in carbonate reservoirs.

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

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

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

163 In particular, the role of wettability in the macroscopic observables of boiling is

164 he role of the interfacial tension (IFT) and wettability in the microfluidic device was simulated usi

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

166 or customizing different bio-inspired liquid wettability including superhydrophobicity, superamphipho

167 species possessing super and special liquid wettability inherently comprises of distinctly patterned

168 multiscale simulations reveal that the dual-wettability interface modulates local hydration and char

169 coatings or membrane separation technology, wettability is a key parameter affecting the applicabili

170 Wettability is an important factor which controls the di

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

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

173 3D) porous functional materials with special wettability is in urgent demand.

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

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

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

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

178 though fresh camel milk powder had very poor wettability, it displayed very high dispersibility and s

179 Intermediate wettability leads to various interfacial movements which

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

181 hem in food packaging, such as inappropriate wettability, low barrier properties, low mechanical prop

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

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

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

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

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

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

188 m and thin films because of the poor surface wettability of fabrics.

189 Here we show how harnessing the wettability of ferrofluids allows for controlled reconfi

190 the wettability of the lubricant; increasing wettability of glycerol makes removal of liquid from the

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

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

193 Wettability of graphene is adjusted by the formation of

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

195 The wettability of graphene on various substrates has been i

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

197 ion to particle surface resulting in varying wettability of IF powders.

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

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

200 50 degrees C, and one of the reasons is poor wettability of liquid sodium on the surface of beta alum

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

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

203 mployed were amenable to differentiating the wettability of MPS segments, affording access to diblock

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

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

206 We changed the wettability of PLA substrates and demonstrated the funct

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

208 rus regime is determined by the porosity and wettability of pores.

209 ts in their composition, resulted in reduced wettability of powders.

210 Wettability of reservoir minerals and rocks is a critica

211 The wettability of selective interconnected channels is cont

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

213 By modifying the wettability of the catalyst, the hydrogenation of aldehy

214 ng the hydrophobic Cy5 head and altering the wettability of the CRISPR reaction solution.

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

216 The wettability of the graphene surface bearing various anio

217 the contact angle results, we found that the wettability of the graphene surface increased gradually

218 estigate the impact of microbial activity on wettability of the hydrogen/brine/rock system, using the

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

220 upled to the stability, local structure, and wettability of the interfacial region.

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

222 ion from ML to BL regime is dominated by the wettability of the lubricant; increasing wettability of

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

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

225 l role in determining the hydrophobicity and wettability of the particles.

226 e sodium-carbonate concentration altered the wettability of the reservoir rock to neutral.

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

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

229 tructure is not directly correlated with the wettability of the surface and different interfacial mec

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

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

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

233 Biofilms can potentially alter the wettability of the system and, consequently, impact the

234 ighted differences in the hydrophobicity and wettability of their pores and vestibule interiors.

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

236 ward, critical challenges in quantifying the wettability of these hydrophobic porous surfaces and sol

237 effects of ambient organic compounds on the wettability of titanium dioxide ( TiO2 ) surfaces is rel

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

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

240 Moreover, tunable wettability offers straightforward means to control mine

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

242 ies have focused on the effect of homogenous wettability on fluid flow dynamics; however, most rocks

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

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

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

246 leverages on the design of patterned hybrid wettability on surfaces that selectively creates a spati

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

248 5.2mN/m) of banana peels, and exhibited good wettability onto banana surfaces.

249 polyelectrolyte layers, rather than surface wettability or surface charge, determines the anti-wetti

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

251 Five different heterogeneous wettability patterns were used in this study.

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

253 Our results reveal the range of wettability possible within the ostensibly identical cav

254 The wettability properties of the new polyfluorinated diuret

255 Although assays based on droplets' wettability provide promising options in some cases, the

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

257 tion of heterogeneous surfaces with distinct wettability regions.

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

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

260 especially at high rates, mainly due to poor wettability, sluggish ionic transport, or low interfacia

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

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

263 her droplet mode shapes are discovered and a wettability spectrometer is invented.

264 as -O-H...O hydrogen bonds and/or alter the wettability state of the solid surface from initially wa

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

266 ility of the technique to tailor the surface wettability, surface friction, and electrical conductivi

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

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

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

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

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

272 For a higher wettability, the contact can either remain attached to t

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

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

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

276 ing morphologic features, surface roughness, wettability, thermal stability, elemental analysis, and

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

278 interactions ([Formula: see text]), surface wettability (theta), and nanotube size (R) using a propo

279 opographical templates of controlled surface wettability through which nanoscale forces are engineere

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

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

282 Besides, the hydrophilic properties and good wettability toward electrolyte of MoB can facilitate ele

283 ignificantly reduce contact angles and shift wettability towards a strongly water-wet condition, a cr

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

285 Alteration in wettability towards hydrophilicity expands hydrogen bond

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

287 ns, asphaltene deposition, and induced water wettability transition at micro scale.

288 ction from 37 to 20 C that induces a surface wettability transition from hydrophobic to hydrophilic.

289 The wettability transition is due to the reaction between Li

290 rious surface engineering problems requiring wettability-tuning.

291 Their improved wettability was confirmed using capillary flow experimen

292 ion of Ti-LLZTO by Li-metal, the interfacial wettability was improved and a mixed ion-electron conduc

293 e effect of alkaline surfactant on reservoir wettability was investigated by quantitative measurement

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

295 ructed on the flexible substrate with hybrid wettability, which can be applied to non-conductive subs

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

297 ated, which shows a dramatic modification in wettability with garnet SSE.

298 By combining tunable wettability with robust photothermal performance, these

299 t plasma exposure increases the seed's water wettability, with some studies reporting increased water

300 at rational tuning of coating compliance and wettability works synergistically with microtexture to e