ライフサイエンスコーパス: immiscible

1 tio, including those ratios considered to be immiscible according to the Co-Mo bimetallic phase diagr

2 approach is demonstrated in both inorganic (immiscible alloy and eutectic alloy) and organic materia

3 The immiscible alloy Cu-Ta has the potential for enhanced me

4 nderstanding of microstructural evolution in immiscible alloys and are valuable for tailoring the pro

5 highlights that the formation of superficial immiscible alloys could offer new insights into the unde

6 Precursory work on this family of immiscible alloys has previously highlighted their therm

7 Ru nanoparticles, forming Ru-In superficial immiscible alloys.

8 Because these lipids are immiscible and phase separate at room temperature, a nov

9 manner resulting in reversible, multiphasic, immiscible, and ternary condensates of different morphol

10 nit is filled with five consecutive plugs of immiscible aqueous and organic solutions; the aqueous sa

11 stribution of carbon nanotubes (CNTs) in two immiscible aqueous phases formed by the addition of poly

12 his polymer solution generally exists as two immiscible aqueous phases.

13 Using two immiscible aqueous polymer solutions, we generate transi

14 kis(4-carboxyphenyl)porphyrin (ZnTPPc) at an immiscible aqueous-organic interface.

15 he unexpected formation of thermodynamically immiscible Au-Pt alloy nanoparticles.

16 The bulk-immiscible AuRh/TiO2 system can serve as a model to unde

17 dy, we used two dynamic polymers, which have immiscible backbones but identical dynamic bonds, to mai

18 ed liquid threads sequentially printed in an immiscible bath locks into crystal-like lattices of drop

19 In contrast, immiscible binary mixture undergo a phase separation in

20 , we report the observation of the RTI in an immiscible binary superfluid consisting of a two-compone

21 The immiscible blocks lead to aggregation in polar and nonpo

22 h interior cavities and multiple layers with immiscible boundaries, containing patterned arrangements

23 Fusion of the aqueous droplet with the immiscible boundary effectively injects the droplet cont

24 then the droplet was fluidically moved to an immiscible boundary that isolates the CE channel (50 mic

25 surfactants that spontaneously separate into immiscible but predominantly aqueous phases-offer thermo

26 f two sets of aqueous solutions in a flow of immiscible carrier fluid within PDMS and glass microflui

27 o-phase slug is segmented from the others by immiscible carrier fluid.

28 ase boundary between aqueous plugs and water-immiscible carrier fluid.

29 mixture flows as discrete droplets inside an immiscible carrier liquid, prevents fouling by isolating

30 lets (1 pL to 10 nL volumes) dispersed in an immiscible carrier oil and enables the digital manipulat

31 ispersed into nanolitre-sized droplets by an immiscible carrier oil and then these droplets are trapp

32 e microfabricated on a PDMS chip that had an immiscible carrier phase (perfluorodecalin) pumped into

33 at forms droplets from aqueous samples in an immiscible carrier phase and encodes information about s

34 quester nanoliter to picoliter samples in an immiscible carrier phase and have gained notoriety for t

35 lume droplets surrounded by a continuous and immiscible carrier phase have attracted significant rece

36 nt resolution by incorporating an additional immiscible carrier solvent into the ink delivery system.

37 ulsions are simple to prepare and consist of immiscible chiral nematic liquid crystals (N*) and fluor

38 rane samples demonstrated the presence of an immiscible cholesterol domain with a unit cell periodici

39 esence of more prominent and highly ordered, immiscible cholesterol domains.

40 y of 34.0 A, consistent with the presence of immiscible cholesterol domains.

41 cles (NPs) is achieved by contacting Ag with immiscible Co NPs.

42 atics and base pairing can be used to create immiscible coacervates that partition various NS species

43 regates and the surrounding hydrogels as two immiscible complex fluids in the time scale comparable t

44 poly(ethylene oxide) and two hydrophobic but immiscible components (a polymeric hydrocarbon and a per

45 ll-known technique for mixing and dispersing immiscible components within a continuous liquid phase.

46 face chemistries partition orthogonally into immiscible condensates.

47 ectures can produce orthogonal (distinct and immiscible) condensates, which can be individually track

48 Adding 0.5 at % lithium to the immiscible Cu-Ta system changes the morphology of the na

49 luid front morphologies emerging during slow immiscible displacement are investigated in real time by

50 ) method, a series of three-dimensional (3D) immiscible displacement simulations are conducted and th

51 d weak wet conditions, pore-scale physics of immiscible displacement under intermediate-wet condition

52 ing CO(2)-water interface instability during immiscible displacement, and their size distribution can

53 xhibited Janus-like heterostructures made of immiscible domains sharing epitaxial interfaces.

54 onfirmed experimentally for a broad range of immiscible electrolyte displacements.

55 anic solvent across an interface between two immiscible electrolyte solutions (ITIES) and its diffusi

56 Studies at the interface between two immiscible electrolyte solutions (ITIES) are often perfo

57 g nanopipet-supported interfaces between two immiscible electrolyte solutions (ITIES) as tips.

58 The interface between two immiscible electrolyte solutions (ITIES) has become a ve

59 The interface between two immiscible electrolyte solutions (ITIES) is ideally suit

60 The interface between two immiscible electrolyte solutions (ITIES) plays vital rol

61 A nanoscale interface between two immiscible electrolyte solutions (ITIES) provides a uniq

62 zed electrode based on interface between two immiscible electrolyte solutions (ITIES) to achieve in v

63 lectrochemistry at the interface between two immiscible electrolyte solutions (ITIES) to investigate

64 et voltammetry with an interface between two immiscible electrolyte solutions (ITIES) to mimic the NE

65 g nanopipet-supported interfaces between two immiscible electrolyte solutions (ITIES) to quantitative

66 e micropipet-supported interface between two immiscible electrolyte solutions (ITIES) to reveal the i

67 he nanopipet-supported interface between two immiscible electrolyte solutions (ITIES) were carried ou

68 rring at the polarized interface between two immiscible electrolyte solutions (ITIES) with ion transf

69 t arrays of nanoscale interfaces between two immiscible electrolyte solutions (ITIES).

70 as investigated at the interface between two immiscible electrolyte solutions (ITIES).

71 of quinine (QN) at the interface between two immiscible electrolyte solutions (ITIES).

72 , at an array of microinterfaces between two immiscible electrolyte solutions (mu-ITIES).

73 Arrays of microscale interfaces between two immiscible electrolyte solutions (muITIES) were formed u

74 d at an array of microinterfaces between two immiscible electrolyte solutions (muITIES).

75 fusion at arrayed nanointerfaces between two immiscible electrolyte solutions (nanoITIES) was achieve

76 n transfer across nanointerfaces between two immiscible electrolyte solutions (nanoITIES); (2) combin

77 ubmicropipet-supported interface between two immiscible electrolyte solutions as an SECM probe not on

78 ical properties of the interface between two immiscible electrolyte solutions, 1,2-dichloroethane-H2O

79 pipet-supported ITIES (interface between two immiscible electrolyte solutions, also called a liquid/l

80 ormation about electron transfer between two immiscible electrolyte solutions, but to the best of our

81 ace mimics a liquid/liquid interface between immiscible electrolyte solutions, in which the ion trans

82 r nanopipet-supported interfaces between two immiscible electrolyte solutions.

83 e electroassisted anion transfer between two immiscible electrolyte solutions.

84 (IT) at the nanoscale interface between two immiscible electrolyte solutions.

85 c nanoparticles at the interface between two immiscible electrolyte solutions.

86 Herein, interfaces between two immiscible electrolytes (ITIESs) are used to study the e

87 ields can be applied at the interface of two immiscible electrolytic solutions (ITIES) in an electroc

88 us topologies by limiting the leakage of the immiscible element during dealloying.

89 positional domain structures enriched in the immiscible element, and (ii) diffusion-coupled growth of

90 (HEAs), especially those with intrinsically immiscible elemental combinations(1-4).

91 Bimetallic alloys made from immiscible elements are characterized by their tendency

92 vercome thermodynamic limits and incorporate immiscible elements into single phase ceramic nanoshells

93 butanol and ethanol) between the completely immiscible extractant and aqueous phases of the bioreact

94 densation and cooling of polymetallic melts (immiscible Fe-Al-Pu-U; and Pb Pu-U) within the detonatio

95 Here, we use a newly described method called immiscible filtration assisted by surface tension (IFAST

96 We have documented an LRP5-6 heteromer using immiscible filtration assisted by surface tension (IFAST

97 Using immiscible filtration assisted by surface tension (IFAST

98 The CEID employs immiscible filtration assisted by surface tension (IFAST

99 In the system, sample and immiscible fluid are pulled alternately from a well plat

100 izontally below the surface of an isoviscous immiscible fluid bath.

101 lls) without washing-centrifugation-assisted immiscible fluid filtration (CIFF).

102 tanding the pore-scale dynamics of two-phase immiscible fluid flow under intermediate-wet conditions.

103 to an array of preformed plugs carried by an immiscible fluid in a microchannel.

104 rapeutics that leverages surface tension and immiscible fluid interactions, to allow confined and foc

105 t has been verified that the presence of the immiscible fluid sandwich does not affect the repeatabil

106 ive withdrawal of one fluid through a second immiscible fluid to coat small particles with polymer fi

107 erest in segmented flow reactors that use an immiscible fluid to divide the reagent phase into discre

108 are manipulated as droplets separated by an immiscible fluid, is an intriguing format for high throu

109 de aqueous droplets (plugs) surrounded by an immiscible fluid.

110 samples in aqueous droplets segmented by an immiscible fluid.

111 tes initially saturated with a more viscous, immiscible fluid.

112 of microscale pressure measurement based on immiscible fluid/fluid interface is proposed.

113 alteration impacts the redistribution of two immiscible fluids and (ii) role of hydrodynamic transpor

114 by mushroom-shaped incursions appearing when immiscible fluids are forced together.

115 rstand the dynamics of interfaces separating immiscible fluids driven through heterogeneous environme

116 own (VB) in a lab-scale swirling flow of two immiscible fluids filling a vertical cylindrical contain

117 , we describe the conditions under which two immiscible fluids flow atop one another (viewed perpendi

118 of Ca, coflowing laminar streams of the two immiscible fluids formed.

119 cillation of adjacent interfaces between two immiscible fluids in a microfluidic platform, we discove

120 nt factor which controls the displacement of immiscible fluids in permeable media, with far reaching

121 Wetting properties control flow of immiscible fluids in porous media and fluids distributio

122 low and predicting the preferential paths of immiscible fluids in porous structures.

123 ometry and the rheological properties of the immiscible fluids used for encapsulation within the micr

124 The kinetic behaviours of miscible and immiscible fluids were investigated.

125 en streams, and (iii) segmented plug-flow of immiscible fluids within the same channel architecture.

126 ing one hydrotrope (such as ethanol) and two immiscible fluids, both being soluble in the hydrotrope

127 e need for time-intensive wash steps, use of immiscible fluids, or precise pinning geometries.

128 lament from the cusped interface between two immiscible fluids--is shown to be the precursor of air e

129 oir-on-Chip (RoC) micromodel filled with two immiscible fluids.

130 roplets carried through a microchannel by an immiscible fluorinated fluid.

131 nanoliter aqueous droplets surrounded by an immiscible fluorinated oil phase.

132 t lung, the airspace was filled with a water-immiscible fluorocarbon.

133 microfluidic system uses multiphase flows of immiscible fluorous and aqueous fluids to form plugs, wh

134 ganic liquid, such as methanol, can form two immiscible (gas and liquid) phases within a chromatograp

135 both sides from the principal flow stream by immiscible guard segments, typically a fluorocarbon (FC)

136 y bi-phase emulsion droplets fabricated from immiscible hydrocarbon and fluorocarbon liquids to form

137 Consequently, a variety of immiscible hydrocarbon fluids might facilitate carbon tr

138 Immiscible hydrocarbons occur in the ocean water column

139 ss microbeads from an aqueous sample into an immiscible hydrophobic solution to perform an efficient,

140 CHOL indicate that cerebroside and CHOL are immiscible in binary mixtures at temperatures less than

141 Fluorocarbon solvents are usually immiscible in organic solutions, and fluorous molecules

142 various degrees of open-gate state, with the immiscible interface setup being in the widely open conf

143 in hexane than in aqueous solution or at the immiscible interface.

144 f oppositely charged polyelectrolytes at the immiscible interface.

145 of the interaction of protein and molecular immiscible interfaces and the design of efficient indust

146 d the principles behind even the simplest of immiscible interfaces such as those of the liquid|liquid

147 incorporate height variations to subject the immiscible interfaces to gradients of confinement.

148 A second water-immiscible ionic liquid, 1-butyl-3-methylimidazolium bis

149 x sheets with surface tension separating two immiscible, irrotational, two-dimensional ideal fluids o

150 Here we show that immiscible isobutane forms in situ from partial transfor

151 e, facile, and low-cost method overcomes the immiscible issue and can produce various HENAs uniformly

152 transport coordinatively bound cargo between immiscible layers, including into solvents in which the

153 articles are coated with a binary mixture of immiscible ligands, ordered ribbon-like domains of alter

154 Micron-scale droplets isolated by an immiscible liquid can provide miniaturised reaction vess

155 y reconfigurable complex colloids comprising immiscible liquid crystals (LCs) and fluorocarbon oils.

156 e able to direct the aquaporin into specific immiscible liquid domains in giant vesicles.

157 for levitating and transporting droplets on immiscible liquid films at higher speeds than is possibl

158 ere the liquid being repelled slides over an immiscible liquid immobilized on a porous surface.

159 important implications for the formation of immiscible liquid in a crystal mush, the interpretations

160 bility to control molecular transport across immiscible liquid interfaces is critical for application

161 The resulting surface is hydrophobic, and no immiscible liquid layer remains on it upon cyclically dr

162 roplets of one liquid suspended in a second, immiscible liquid move through a microfluidic device in

163 In particular, two immiscible liquid phases are identified in bioadhesive f

164 and cholesterol form micron-scale domains of immiscible liquid phases for only a limited range of com

165 The formation of immiscible liquid phases or coacervates is a phenomenon

166 sides of the myelin bilayer form coexisting immiscible liquid phases similar to the liquid-ordered/l

167 ese mixtures produce two distinct regions of immiscible liquid phases that span all compositions stud

168 diagrams containing two distinct regions of immiscible liquid phases, whereas those with membrane-in

169 artitioning behavior of analytes between two immiscible liquid phases.

170 pin liquids to substrates, and overlaying an immiscible liquid prevents evaporation.

171 Both miscible and immiscible liquid systems have been studied.

172 Immiscible liquid-liquid interfaces are an attractive pl

173 The mechanism by which ions adsorb to immiscible liquid-liquid interfaces is central to our un

174 described how the physical properties across immiscible liquid-liquid interfaces should converge from

175 sorbed to the liquid-disordered phase during immiscible liquid-liquid phase coexistence, and the cont

176 o nanoparticles at the interface between two immiscible liquids affect the same results in jammed ass

177 g ion transfers at the interface between two immiscible liquids and homogeneous reactions in solution

178 on conditions, and (iii) the presence of two immiscible liquids and the interface between them that e

179 n this way, stable liquid boundaries between immiscible liquids are possible as long as the pressures

180 and polymerizations at the interface of two immiscible liquids are reviewed.

181 ynamic modeling of Fe-O-S liquids shows that immiscible liquids can exist at outer-core pressures (13

182 The separation of immiscible liquids has significant implications for magm

183 Systems comprised of immiscible liquids held in non-equilibrium shapes by the

184 of dihydrocholesterol and phospholipids form immiscible liquids in monolayer membranes at the air-wat

185 to confine and position the boundary between immiscible liquids inside microchannels leads to a broad

186 bubbles, and marbles are dispersions of two immiscible liquids or of a liquid and a gas stabilized b

187 presented that exploits the interactions of immiscible liquids with a structured surface.

188 sions do in the mutual spreading behavior of immiscible liquids, among which the liquid of lower surf

189 s the properties of interfaces between three immiscible liquids, and uses fluid flow through the tube

190 e tortuous, interconnected structures of two immiscible liquids, kinetically trapped by colloidal par

191 sing segmented flow in a two-phase system of immiscible liquids, which delivers aqueous droplets into

192 ing have been compared with the behaviors of immiscible liquids, which they closely resemble.

193 conformal thin films at the interface of two immiscible liquids.

194 enabling the control of the boundary between immiscible liquids.

195 he dispersion and distribution of NPs in two immiscible liquids.

196 provides large interfacial area between two immiscible liquids: oil and water.

197 ctural metallic materials with interfaces of immiscible materials provide opportunities to design and

198 and dynamic droplets of fluids in different immiscible media have been used as individual vessels to

199 which have a lower refractive index than the immiscible medium in which the droplets are immersed and

200 complement recent experimental evidence for immiscible methane-rich fluids at 600-700 degrees C and

201 drolysis of lipids was monitored directly in immiscible microdroplet environments using contained-ele

202 A combination of immiscible molecules in the ligand shell of a gold nanop

203 surface pressure pi of 30 mN/m, and forms an immiscible monolayer mixture with DPPC.

204 racterize colorimetric probes in other water immiscible nanomaterials.

205 collected at 7 s intervals, segmented by an immiscible oil and stored in a capillary tube.

206 ates into nanoliter droplets segmented by an immiscible oil at 4.5 samples/s and sequentially analyze

207 is of aqueous plugs segmented in a stream of immiscible oil is described.

208 ing crystal laden droplets segmented with an immiscible oil reducing sample waste and demonstrate dro

209 Parallel sample recovery in an immiscible oil stream offers the advantage of low sample

210 mum inner diameter LC column segmented by an immiscible oil such as perfluorodecalin.

211 ts are generated by vortexing a sample in an immiscible oil to create an emulsion.

212 with a sample volume of 8 nL segmented by an immiscible oil.

213 nt freezing points for aqueous solutions and immiscible oils, we froze a stream of aqueous droplets t

214 are dehydrated at the interface between two immiscible oils.

215 ed in an array of microwells, after which an immiscible organic (phenol-chloroform) phase was introdu

216 phase at the bottom of a sample vial, via an immiscible organic filter phase, into a 2 muL acceptor p

217 lize the underwater lossless manipulation of immiscible organic liquid droplets with a large volume.

218 Not a conventional glass cuvette, but water-immiscible organic liquid, is used as the container for

219 ion to measure densities of solids and water-immiscible organic liquids with accuracies ranging from

220 e basis of their isoelectric points, into an immiscible organic phase from an aqueous solution.

221 The wetted tips were immersed in an immiscible organic phase, acting as a filter to extract

222 liquid aqueous sample donor phase through an immiscible organic solvent layer acting as a filter phas

223 al library samples were dissolved in a water-immiscible organic solvent, butyl acetate, and added to

224 Then crude plasma samples and a water-immiscible organic solvent, methyl ethyl ketone, were se

225 n nanotube (SWNT) suspensions are mixed with immiscible organic solvents.

226 ining mechanisms responsible for bonding of "immiscible" pairs of Mg and Fe.

227 by reversibly penetrating and resealing the immiscible partition.

228 at strong electronic interactions within the immiscible Pd-Mn alloy are critical for locking intersti

229 f the system, enhanced by the presence of an immiscible phase (e.g., air), on the mixing efficiency.

230 an aqueous phase at equilibrium with a water-immiscible phase (lipid bilayers, phase transfer catalys

231 f the neutral assemblies formed in the water-immiscible phase are usually not well defined and the ca

232 Spontaneous formation of a third immiscible phase during liquid-liquid solvent extraction

233 e have investigated how lipid concentration, immiscible phase flow velocities and the device geometri

234 ements, which are highly fractionated by the immiscible phase separation that produces these carbonat

235 ay of chambers that have been primed with an immiscible phase.

236 cantly reduced by segmentation with a second immiscible phase.

237 ume aqueous droplet that is surrounded by an immiscible phase.

238 aptured on a solid phase through one or more immiscible-phase barriers that efficiently exclude the p

239 Rh(II)-based MOP can be transferred between immiscible phases by pH changes or by cation-exchange re

240 The transfer of nanoparticles between immiscible phases can be driven by externally triggered

241 The surface between two immiscible phases has an interfacial tension, generating

242 xide, helium and carbon dioxide can form two immiscible phases over extended composition ranges.

243 o reduce the interfacial tension between two immiscible phases to stabilize droplet interfaces.

244 rences can drive the formation of coexisting immiscible phases with tunable formation kinetics and ca

245 rs to quantify how species partition between immiscible phases without disrupting the equilibrium, of

246 used referring to systems consisting of two immiscible phases, one of which is finely dispersed into

247 quid-liquid partitioning process between two immiscible phases, respectively.

248 ted into "darker oily" and "lighter aqueous" immiscible phases.

249 ree energy (interfacial tension) between two immiscible phases.

250 using the liquid/liquid interfaces of three immiscible phases.

251 classes of binary, ternary and postconsumer immiscible polymer mixtures in situ.

252 spherical particles can be obtained by using immiscible polymer pairs and by employing surface treatm

253 By combining three mutually immiscible polymeric components in a mixed-arm star bloc

254 ular network polymer consisting of a pair of immiscible polymers, poly(butyl)methacrylate (PBMA) and

255 r knowledge the highest obtained for a water-immiscible product in aqueous medium.

256 stering the interfacial surface area between immiscible reagents and mass transfer of electroactive o

257 The epitaxy of immiscible refractory oxides is, therefore, an effective

258 bic oxide pairs fit the design principles of immiscible refractory photonics.

259 il, but its oxidation products are virtually immiscible, resulting in the formation of a viscous surf

260 cles in the presence of a small amount of an immiscible secondary liquid.

261 ur issues from a carbon anode immersed in an immiscible secondary molten salt electrolyte disposed ab

262 The motion of a conductive/nonconductive immiscible segmental interface in a capillary is followe

263 Block copolymers with chemically immiscible segments exhibit a variety of microphase-sepa

264 was less significant in the case in which an immiscible solute (pentane) was mixed with H(2)O.

265 u-EME) were formed as adjacent plugs of free immiscible solutions in narrow-bore polymeric tubing, an

266 st microreactors, to extract product into an immiscible solvent during reaction, and to use Leidenfro

267 tercurrent chromatography (CCC) using solely immiscible solvent systems allowed the fractionation of

268 ng metal cations or metal salts into a water-immiscible solvent usually operate in the inner coordina

269 rocedure, the HF is impregnated with a water-immiscible solvent, its lumen is filled with 5 muL of an

270 aqueous/nonaqueous and nonaqueous/nonaqueous immiscible solvent-based RFBs; laminar flow-based RFBs;

271 s, MXx(n-), or metal salts, MXx into a water-immiscible solvent.

272 artmentalization by operation in a system of immiscible solvents (here water and chloroform) results

273 The use of water-immiscible solvents is key and leads to a 1-3 orders of

274 This is commonly done by using two immiscible solvents such as water and chloroform for ext

275 gest retention values can be expected from W-immiscible solvents that fully remain in the bulk MP.

276 a is synthesized at an interface between two immiscible solvents under conditions leading to the form

277 e status of these assemblies in a mixture of immiscible solvents, these dendrimers were found to be k

278 re favoured by the low polarity of the water-immiscible solvents.

279 y the photoactivated transitions between two immiscible states of the polymer.

280 imensional map that divides the miscible and immiscible systems into distinctly clustered regions.

281 The classification of miscible and immiscible systems of binary alloys plays a critical rol

282 Furthermore, the use of immiscible systems, e.g., in emulsions, offers an easy m

283 hat allows interfacial reactions for the two immiscible systems.

284 r in a phase-transfer polymerization with an immiscible THF solution of monomer and initiator.

285 binary mixtures, we investigate the miscible-immiscible transition at finite temperature by means of

286 derstanding and predicting the flow paths of immiscible two-phase flow in rocky porous structures are

287 rst of the metals in the condensed state and immiscible under normal conditions.

288 Polystyrene dissolved in a water-immiscible, volatile solvent was deposited in a humid en

289 We find that these two OA types are immiscible, which informs our inference of the morpholog

290 partition into a concentrated phase that is immiscible with a dilute phase, is involved with fundame

291 eversed-phase LC conditions and is typically immiscible with a starting reversed-phase gradient mobil

292 phosphate (TFEP) organic electrolyte that is immiscible with aqueous Zn(TFSI)(2) -H(2) O bulk electro

293 x is miscible with DPPC and cholesterol, and immiscible with DOPC.

294 Remarkably, Nup98 condensates are immiscible with HP1 condensates, and they are required a

295 similar hydrocarbon makeup, the polymers are immiscible with one another.

296 ite IA-2) is dissolved in an organic solvent immiscible with the aqueous eluent.

297 pipette filled with an organic phase that is immiscible with the external aqueous solution was used a

298 f distinct physical properties, which can be immiscible with unmodified chromatin droplets, mimicking

299 tum cells, rendering them distinct from, and immiscible with, neighboring wing cells.

300 These two types of bonds are intrinsically immiscible without cosolvents.