ライフサイエンスコーパス: liquid phase

1 nsfer between fixed positions in the gas and liquid phases).

2 ity of zeolites and stability of zeolites in liquid phase.

3 mercury is mainly retained as Hg(2+) in the liquid phase.

4 ng immiscible components within a continuous liquid phase.

5 ssipation changes during adsorption from the liquid phase.

6 rovide evidence that supports roaming in the liquid phase.

7 magnetic quantum phase transition by a Fermi liquid phase.

8 pontaneously transform into a higher-density liquid phase.

9 GUVs showed no detectable Gag binding to the liquid phase.

10 that can visualize nanoscale objects in the liquid phase.

11 complexes are difficult to determine in the liquid phase.

12 are oriented preferentially toward the bulk liquid phase.

13 imultaneously extracted using one-step solid-liquid phase.

14 the hydrogel, as compared to the surrounding liquid phase.

15 lid matrix and rising red emission in molten liquid phase.

16 r investigating biomolecular interactions in liquid phase.

17 n has prevented any measurements of the bulk liquid phase.

18 e (SH-SAW) sensors operating directly in the liquid phase.

19 and mixing of the gas-phase analyte with the liquid phase.

20 tially promotes isopropanol oxidation in the liquid phase.

21 ty arising from the inherent property of the liquid phase.

22 processibility and permanent porosity in the liquid phase.

23 relevant to understand the reactivity in the liquid phase.

24 be in a high-density gas or in a low-density liquid phase.

25 ctural disorder can stabilize a quantum spin liquid phase.

26 mulation techniques and peptide synthesis in liquid phase.

27 d as minimal inhibitory concentration in the liquid phase.

28 the nucleolus represent distinct, coexisting liquid phases.

29 behavior of analytes between two immiscible liquid phases.

30 ults in the formation of a particle with two liquid phases.

31 ly unidentified route to realizing non-Fermi liquid phases.

32 itions where they exhibit coexistence of two liquid phases.

33 trivial process, especially for amorphous or liquid phases.

34 arameters controlling the interface, gas and liquid phases.

35 particle with still empty pores in the dense liquid phase a significant challenging.

36 sing static headspace-gas chromatography for liquid phase analysis, we identify acetaldehyde as a min

37 ding the localization of other lipids during liquid-phase analyte derivatization.

38 charge transfer processes occurring in both liquid phase and in vacuum.

39 We postulate that atoms percolate in the liquid phase and that the percolating cluster becomes ri

40 ived from the enthalpies of formation in the liquid phase and the enthalpies of vaporization, at T =

41 , depending on molecular interactions in the liquid phase and the investigated element.

42 use SEF exists as an equilibrium between the liquid phase and the particle surface, the process is al

43 as the aerobic oxidation of alcohols in the liquid phase and the preferential oxidation of carbon mo

44 has often been applied to adsorbates from a liquid phase and, also, to samples with structure in the

45 the free-energy surface, that two metastable liquid phases and a stable crystal phase exist at the sa

46 lling porosity in crystalline, amorphous and liquid phases and also describe the state-of-the-art met

47 a variety of structures that are soluble in liquid phases and therefore amenable to homogeneous cata

48 lts suggest different mechanisms between the liquid-phase and gas-phase reactions, correlating well w

49 size of platinum nanoparticles for both the liquid-phase and gas-phase reactions.

50 e door for the development of new classes of liquid-phase and solid-phase ordered porous materials.

51 rcome this hurdle by avoiding the gaseous or liquid phase, and directly converting glass into a singl

52 rate constants, and VTST in the solid phase, liquid phase, and enzymes.

53 arated into two coexisting phases: one was a liquid phase, and the other appeared to be a phosphatidy

54 of the existence of gapped topological spin liquid phases, and the Yang-Mills gap conjecture, concer

55 irst-order kinetics for the removal from the liquid phase; and (iii) higher amounts in the solid phas

56 The liquid phase apparently served as the medium through whi

57 ed on these rigid features, for both gas and liquid phase applications.

58 Volumetric data for each liquid phase are converted into a dynamic real-time disp

59 -dependence of the viscosity of the evolving liquid phase, as well as the distribution and longevity

60 These species remain stable in the liquid phase at room temperature but convert to gels upo

61 tive to FeOH(2+) in the highly acidic "quasi-liquid" phase at 30% RH.

62 ElecFET are electrochemical microsensors in liquid phase, based on two elements: (i) a pH-sensitive

63 ographene-based transistors fabricated using liquid-phase-based process.

64 ial emphasis is given to ruthenium-catalyzed liquid phase batch hydrogenation of benzene.

65 els toward the stomata in both the vapor and liquid phases before exiting the leaf as vapor.

66 one anatomy based technology in the field of liquid phase bioseparations, particularly in capillary e

67 und radiation and further separation of both liquid phases by centrifugation.

68 requires a structural reorganization of the liquid phase, called stress-driven ageing.

69 Micron-scale coexisting Lo and Ld liquid phases can appear in lipid bilayers composed of a

70 ateral demixing of membranes into coexisting liquid phases can organize proteins and lipids on micron

71 We report a liquid-phase, capture-based sequencing and bioinformatic

72 For liquid-phase catalytic cyclohexanol dehydration, these S

73 find that the ultrafast formation of a dense liquid phase causes the crystallization to accelerate bo

74 loped setup compared favorably with previous liquid-phase cavity enhanced studies and approaches the

75 self-referenced luminescent sensor for solid-liquid phase change, viscosity, and temperature, with gr

76 nolayers and/or slow long-range diffusion of liquid-phase charge carriers.

77 ivated THz modes that play a central role in liquid-phase chemistry.

78 Adsorption isotherms and liquid-phase chromatographic measurements indicate a ret

79 ehyde-modified OSCs by ultrahigh-performance liquid phase chromatography coupled with tandem mass spe

80 regioselectivity is also observed during the liquid-phase chromatography of the ethyltoluene and cyme

81 was analyzed by using ultra-high-performance liquid-phase chromatography with tandem mass spectrometr

82 id-disordered phase during immiscible liquid-liquid phase coexistence, and the contrast persisted thr

83 uire cholesterol's ability to support liquid-liquid phase coexistence.

84 in the viral membrane do not require liquid-liquid phase coexistence.

85 The tie lines determined in the two-liquid-phase coexistence region are found to be not para

86 ays formed at low-energy grain boundaries by liquid-phase compaction in Bi(0.5)Sb(1.5)Te3 (bismuth an

87 ve oil extraction, allows the formation of a liquid phase containing a high concentration of phenolic

88 We propose that a dense liquid phase (containing 4-7 H2O per CaCO3 unit) forms i

89 The organization of SVs into a liquid phase could explain how SVs remain tightly cluste

90 For the alcohols, undefined processes in the liquid phase create additional PSIEs.

91 The process utilizes templated liquid-phase crystal growth that results in user-tunable

92 useful technological tool for the control of liquid phase deposition of 2D materials.

93 We evaluated electrospray deposition of liquid-phase derivatization agents as a means of on-tiss

94 -concentration detection limit compared with liquid phase detection.

95 Quantitative analysis reveals liquid-phase dewetting of the thin-film, followed by hyd

96 Liquid phase diffusion plays a critical role in phase tr

97 For liquid-phase diffusion we encounter a situation in which

98 echniques to detect nanoscopic and modulated liquid phase domains in a mixture composed entirely of n

99 pid membranes phase separate into coexisting liquid phases, domains in each monolayer leaflet of the

100 cleolus and other nuclear bodies behave like liquid-phase droplets and appear to condense from the nu

101 reading of an intermediate CH3NH3PbI3xCH3NH2 liquid phase during this unusual perovskite-gas interact

102 concept: the coupling between the vapor and liquid phases during evaporation.

103 ained on the evolution of both the solid and liquid phases during the crystallization process.

104 dge the gap in our understanding of gas- and liquid-phase dynamics.

105 ytic reactions under harsh conditions in the liquid phase (e.g., temperatures of 250 degrees C and po

106 tion problems inherent to the widely adopted liquid-phase electrolyte batteries.

107 Here, by using in situ liquid-phase electron microscopy to visualize the nuclea

108 and Ni(111) surfaces, between a gaseous and liquid phase environment, results from a repulsion betwe

109 us feedstock solutions using electrochemical liquid phase epitaxy (ec-LPE) at low temperatures (T </=

110 ganic frameworks (IRMOFs) exhibit true vapor-liquid phase equilibria where the effective critical poi

111 sed on a core-shell nanosphere composed of a liquid-phase eutectic gallium-indium core and a thiolate

112 st photo switching behavior of thin films of liquid phase exfoliated MoS2, when excited with a contin

113 Here, we demonstrate the first liquid phase exfoliated WS2-Nafion nanocomposite based e

114 n shown to be the most effective solvent for liquid phase exfoliation and dispersion of a range of 2D

115 hene ink is produced via ultrasonic assisted liquid phase exfoliation in isopropyl alcohol (IPA) usin

116 gle and few-layer graphene films prepared by liquid phase exfoliation of graphite.

117 ence, can be produced in large quantities by liquid phase exfoliation under ambient conditions in sol

118 cleavage based on the scotch tape approach, liquid-phase exfoliation (LPE) methods are becoming more

119 We then describe a variety of successful liquid-phase exfoliation methods by categorizing them in

120 an inexpensive and scalable method based on liquid-phase exfoliation of graphite (LPE) holds potenti

121 nes can be used to improve the efficiency of liquid-phase exfoliation of graphite, with the photochro

122 The liquid-phase exfoliation of tin(II) sulfide to produce S

123 d phase comparative genome hybridization and liquid phase exome capture followed by next-generation s

124 Our results are consistent with vapor and liquid phases extending over many MOF unit cells.

125 dure designed to aggregate the advantages of liquid phase extraction (extract homogeneity, fast, and

126 needle-based sampling approach coupled with liquid-phase extraction (NBS-LPE) was developed and appl

127 g status of bound biomolecules to readout of liquid-phase FETs fabricated with graphene or other two-

128 gonal allyl acrylamide building blocks and a liquid-phase fluorous support for the de novo design and

129 amorphous nanoclusters within the metal-rich liquid phase, followed by crystallization of these amorp

130 D s significantly increases when CO2 became liquid phase for samples with low D s .

131 thout strongly altering the ratio of the two liquid phases found below Tc.

132 with key advantages over strategies based on liquid phase (fusion) sintering that requires both oxide

133 d stretchable microelectronics composed of a liquid-phase Gallium-Indium alloy with micron-scale circ

134 aney Ni catalysts exhibits different trends, liquid-phase HDH of mixed HACs over Pd/C and Raney Ni ca

135 Liquid-phase HDH of single and mixed halobenzenes/4-halo

136 For liquid-phase HDH of single HACs, hydrogenolytic scission

137 0 nm gold particles supported on silica with liquid-phase hydrogen and deuterium peroxides at multipl

138 ergy generation, utilizing the conversion of liquid-phase hydrogen to usable hydrogen gas (H2), is de

139 tural and electronic factors controlling the liquid phase hydrogenation of cinnamaldehyde and related

140 -promoted Pt/C catalyst (NanoSelect) for the liquid-phase hydrogenation of nitrobenzene under standar

141 the inhibited one: (i) more removal from the liquid phase; (ii) deviation from first-order kinetics f

142 beta-citronellene molecule from the external liquid phase in a pore opening where it reacts with etha

143 stallization from a redox-sensitive metallic liquid phase in the deep mantle.

144 h the formation of an Al-OSDA complex in the liquid phase in which the Al is octahedrally coordinated

145 ion to separate contributions from solid and liquid phases in limited volumes.

146 ose to a miscibility critical point, the two liquid phases in the membrane are bicontinuous.

147 A core-level ionized water molecule in the liquid phase, in addition to a local Auger process, rela

148 d growth of the enriched solid phase and the liquid phase into the alloy.

149 Heterogeneous catalysis performed in the liquid phase is an important type of catalytic process w

150 (3D) growth of a quasicrystal from a parent liquid phase is lacking.

151 Exchange of Mn atoms between the solid and liquid phase is rapid, reaching dynamic equilibrium in 2

152 ed in monatomic and molecular systems if the liquid phase is slow enough to induce viscoelastic phase

153 ndent charged surfaces, Al2O3 membranes, and liquid-phase isolation.

154 means of a rapid prototyping method based on liquid-phase lithography.

155 the measured HLCs, the formaldehyde overall liquid-phase mass transfer coefficients (KOLs) were dete

156 ttachment kinetics of atomic clusters in the liquid phase, melting is instead barrier-less and limite

157 odification offer considerable potential for liquid-phase membrane separations and related separation

158 anchor, which is partially diffused into the liquid-phase membrane.

159 ueous samples using hollow fiber based solid-liquid phase microextraction (HF-SLPME) combined with fl

160 ound-assisted ionic liquid dispersive liquid-liquid phase microextraction (UA-IL-DLLME) method for pr

161 Electromembrane extraction (EME) and liquid-phase microextraction (LPME) were combined in a s

162 n this work, the potential of a hollow-fibre liquid-phase microextraction (LPME)-based method has bee

163 y exfoliation of graphite in the presence of liquid-phase, microwave-assisted methods.

164 during this replacement, in which patterned liquid phase morphologies are observed on giant unilamel

165 Using wide Q-range liquid-phase neutron diffraction, we elucidate the mecha

166 Dynamics of liquid phase nitrous (N2O) and nitric oxide (NO) concent

167 composition into solute-rich and solute-poor liquid phases, nucleation of amorphous nanoclusters with

168 and preferential partitioning of BTs to the liquid phase of a melting snowpack leads to early peaks

169 Here we demonstrate a liquid phase of actin filaments in the presence of the p

170 at the determination of additive only in the liquid phase of legume or artichoke bottles is not suita

171 chemical composition of both the gas and the liquid phase of red wines.

172 dynamic distribution of these metals in the liquid phase of the anaerobic system and kinetics of res

173 The liquid phase of the bridges allows local reorganization

174 The liquid phase of the MC solution was viscous enough to ad

175 that the VBC phase melts into a valence bond liquid phase of the RVB (resonating valence bond) type.

176 ssful measurements of NEMS resonators in the liquid phases of helium.

177 nal effects generated by the presence of the liquid phase often required in practical applications su

178 grapes followed by alcoholic fermentation in liquid phase or in solid phase.

179 igh selectivity to ethanol by distinguishing liquid-phase or vapor-phase ethanol (C2H6O) from water (

180 Materials synthesis in the liquid phase, or wet-chemical synthesis, utilizes a solu

181 P-driven molecular interactions give rise to liquid phase organelles with tunable properties.

182 ct to other solid catalysts for this type of liquid phase organic reactions and pointing out that the

183 ificantly alter the rates and selectivity of liquid-phase organic reactions, often hindering the deve

184 criminate between molecules freely moving in liquid phase outside the zeolite and molecules adsorbed

185 ication of beta-citronellene with ethanol in liquid phase over acid zeolite beta is revealed by in si

186 f both technological and chemical aspects of liquid phase oxidation chemistry in continuous-flow micr

187 Continuous-flow liquid phase oxidation chemistry in microreactors receiv

188 The liquid-phase patterning byproduct is readily removed by

189 Physical separation between the solid and liquid phases permitted only homopolymerization of monom

190 e pH sensor arrays was realized by multistep liquid-phase photolithography from oligoethylene glycol

191 a high degree of lipid ordering within their liquid-phase plasma membranes.

192 ominent role in industry as gaseous, and now liquid-phase, precursors to semi-conducting films; furth

193 ttom-up solution synthesis of long (>200 nm) liquid-phase-processable GNRs with a well-defined struct

194 the system fluctuates freely between the two liquid phases rather than crystallizing.

195 ectrolyte, solid catalyst, and gas-phase and liquid-phase reactants and products.

196 cess, which provides an easy way to localize liquid-phase reaction and realize selective synthesis an

197 d is in general much higher than that of the liquid-phase reaction which is largely insensitive to th

198 ncreasing application as solid catalysts for liquid phase reactions leading to the synthesis of fine

199 anic compounds synthesized via gas-phase and liquid-phase reactions were characterized by high-perfor

200 trogen species (RNS) are strongly coupled in liquid-phase reactions: NO3 is an important precursor fo

201 In these vesicles, the liquid phase recruited PHPLCdelta1 regardless of PI(4,5)

202 t approaches, gas phase radical grafting and liquid phase reductive grafting, provide routes to a ran

203 at reactions taking place in the atmospheric liquid phase represent a potentially significant source

204 Correlative light microscopy and liquid-phase scanning transmission electron microscopy (

205 The morphology of liquid-liquid phase separated aerosols has a strong impact on t

206 etermine the equilibrium structure of liquid-liquid phase separated aerosols through free energy mini

207 se set of single-component particles, liquid-liquid phase separated particles (core-shell morphology)

208 ly probe the dynamic architecture within FUS liquid phase-separated assemblies.

209 s disordered secondary structure even in the liquid phase-separated state.

210 ary biophysical properties to undergo liquid-liquid phase separation (LLPS) in cells.

211 disease-related RBP hnRNPA1 undergoes liquid-liquid phase separation (LLPS) into protein-rich droplet

212 Liquid-liquid phase separation (LLPS) is thought to contribute

213 Liquid-liquid phase separation (LLPS) of RNA-binding proteins p

214 ments resulting from crowding-induced liquid/liquid phase separation (LLPS) on the dynamic spatial or

215 Recent evidence suggests that a liquid-liquid phase separation (LLPS) process may drive their f

216 n undergo phase transitions including liquid-liquid phase separation (LLPS) while responding to chang

217 and tendency of the system to undergo liquid-liquid phase separation (LLPS).

218 encapsulate I3C and DIM by a combined liquid-liquid phase separation and ionic gelation method.

219 form liquid droplets in vitro through liquid-liquid phase separation and liquid-like non-membrane-bou

220 They can be assembled by ternary liquid phase separation by microfluidics, but the contro

221 lay particles with droplets formed by liquid-liquid phase separation could provide a physical mechani

222 With a few notable exceptions, liquid-liquid phase separation in bulk proceeds through the con

223 n, theory has been developed to model liquid-liquid phase separation in bulk systems.

224 Liquid-liquid phase separation in giant unilamellar vesicles (G

225 Here we show that liquid-liquid phase separation in monolayer membranes composed

226 g recent results on the inhibition of liquid-liquid phase separation in nanoscale particles and studi

227 s are compared to previous studies of liquid-liquid phase separation in supermicrometer particles and

228 ed atmospheric aerosols with internal liquid-liquid phase separation is inferred.

229 Intracellular liquid-liquid phase separation is thought to drive the formatio

230 Liquid-liquid phase separation is ubiquitous in suspensions of

231 While liquid-liquid phase separation may drive RNP granule assembly,

232 ining the polyethylene glycol-induced liquid-liquid phase separation measurements and the phenomenolo

233 c strategy for fundamental studies of liquid-liquid phase separation mediated by CO2 as well as scree

234 ed by the polyethylene glycol-induced liquid-liquid phase separation method.

235 Liquid-liquid phase separation of intrinsically disordered prot

236 embrane-less organelle formed through liquid-liquid phase separation of its components from the surro

237 logy and in biomaterials development, liquid-liquid phase separation of proteins remains poorly under

238 The morphology, mineralogy, and solid-liquid phase separation of the Cu and Zn precipitates fo

239 n undergo a phase transition in which liquid-liquid phase separation results in the formation of a pa

240 hydrophobic, disordered, and undergo liquid-liquid phase separation upon self-assembly.

241 ically disordered proteins to achieve liquid-liquid phase separation, and we demonstrated that galect

242 membraneless organelles originate via liquid-liquid phase separation, but how their distinct structur

243 Liquid-liquid phase separation, driven by collective interactio

244 Remarkably, ABs form not by liquid-to-liquid phase separation, implicated in RNA-seeded granul

245 We suggest that consideration of liquid-liquid phase separation, leading to complete or partial

246 as RNA granules that assemble through liquid-liquid phase separation.

247 n-protein interactions analogous to a liquid-liquid phase separation.

248 t these compartments assemble through liquid-liquid phase separation.

249 brium activity might impact classical liquid-liquid phase separation.

250 of a dense liquid precursor phase via liquid-liquid phase separation.

251 ated that galectin-3 can also undergo liquid-liquid phase separation.

252 exhibit dynamics that are characteristic of liquid phase-separation, including sensitivity to the di

253 Perturbations that alter liquid-liquid phase separations (LLPS) driven by intrinsically

254 on of pressure gradients on-chip for driving liquid phase separations in submicrometer deep channels.

255 Liquid-phase separations of similarly sized organic mole

256 le product is transported to a thin-film gas-liquid phase separator and directed to an inductively co

257 ail, structures remain widely unknown in the liquid phase since many of these techniques could only b

258 of one phase (solute) in a second, typically liquid, phase (solvent).

259 aphene was synthesised from graphite through liquid phase sonication and then mixed with zinc acetate

260 its vicinity from the liquid-ordered to the liquid phase spanning a distance almost twice its core r

261 idic platform has been developed for the all liquid-phase synthesis of heterogeneous nanomaterial arr

262 reactivity, which is often masked in typical liquid-phase synthesis.

263 Here, the authors combine liquid-phase TEM and single particle tracking to observe

264 of olive oil waste (alperujo) led to a final liquid phase that contained a high concentration of simp

265 results provide insights into the non-Fermi liquid phase that is observed in films for which the MIT

266 ferent routes: direct crystallization of the liquid phase, the Bergeron process, and Ostwald ripening

267 of C2 emitted by different vegetable oils in liquid phase, the characteristics of each organic media.

268 Once absorbed in the liquid phase, the entrained analyte molecules induce agg

269 Because they are liquid-phase, these alloys can alter the electrical and

270 liquid transition, a phase transition of one liquid phase to another with the same composition, provi

271 CO(2) phase transition from supercritical or liquid phase to gas phase.

272 nsition between either one of the coexisting liquid phases to a microemulsion.

273 d and released from the solid support to the liquid phase, to be sequenced via single-step tandem mas

274 ty acids were observed in wines fermented in liquid phase, together with a decrease in fusel alcohols

275 Here we develop a hybrid solid-liquid phase transcription method and automated robotic

276 een two distinct liquid states, and a liquid-liquid phase transformation between these states, in the

277 lt suggests that pressure causes a liquid-to-liquid phase transition in this metallic alloy supercool

278 Ultrafast crystal-to-liquid phase transition induced by femtosecond pulse las

279 We investigated the putative liquid-liquid phase transition using the Water potential from A

280 witchable adhesion when it undergoes a solid-liquid phase transition.

281 Liquid-liquid phase transitions in complex mixtures of proteins

282 mental understanding of ultrafast crystal-to-liquid phase transitions, enabling quantitative a priori

283 Liquid-phase transmission electron microscopy imaging an

284 ng on the fundamental mechanisms of gas- and liquid-phase transport, membrane fabrication techniques

285 The throughput of existing liquid phase two-dimensional separations is generally li

286 mit, we report the observation of coexisting liquid phases using fluorescence microscopy.

287 ative trapping of the gaseous mercury in the liquid phase was achieved with 11.5 muM KMnO4 in 2% HNO3

288 the amount of the compound remaining in the liquid phase was determined by SPME-GC-MS.

289 The liquid phase was extracted and fractionated chromatograp

290 A liquid phase was required to initiate degradation in the

291 volatile elements or species between gas and liquid phases was performed in the real propylene sample

292 atalyzed by metal nanoparticles (NPs) in the liquid phase were studied.

293 Likewise, Gag bound to the liquid phase when PI(4,5)P2 had DO-acyl chains.

294 ere fabricated by bottom-up synthesis in the liquid phase, where structure, width, and edge planarity

295 s thermalizing the system in the supercooled liquid phase, where the thermalization time may be extre

296 increase, the alloy reenters the supercooled liquid phase, which forms the room-temperature glass pha

297 Rh(I) metal complex resides in the original liquid phase, while the product of hydrogen addition is

298 allite particulates immersed in a continuous liquid phase with no long-range order.

299 It was based on isotope dilution (ID) in the liquid phase with the (202)Hg enriched certified referen

300 from reactions in gas phase to reactions in liquid phase, with the solvent active role fully taken i