ライフサイエンスコーパス: colloidal

1 Colloidal 3-mercaptopropionic acid (3-MPA) capped lead s

2 Particulate colloidal aggregate food ingredients were prepared by co

3 e viewed as an effective and well-accessible colloidal amphiphile.

4 sembly is only sparsely used in synthetic or colloidal analogues.

5 on is a high-resolution non-invasive tool in colloidal analysis shown to successfully identify asphal

6 l with prominent electrostatic interactions, colloidal and biological membranes share many of the sam

7 iform particles to form a vast collection of colloidal arenes and colloidenes, the spontaneous dissoc

8 Those systems include nanoparticle and colloidal assemblies driven by DNA-mediated interactions

9 at potential for the development of multiple colloidal assemblies within different research fields.

10 Programmable colloidal assembly enables the creation of mesoscale mat

11 through patterning), and macroscale (through colloidal assembly), ultimately resulting in a controlla

12 unction, have not been widely used to direct colloidal assembly.

13 We here report the use of colloidal bimetallic nanocrystals to produce catalysts w

14 The fuel-mediated assembly of colloidal building blocks presented here opens new avenu

15 e categorized into the four major themes for colloidal capsule formation, i.e. the Pickering-emulsion

16 The varying fields of colloidal capsule research are then further categorized

17 Finally, a special section is dedicated to colloidal capsules for biological applications, as a div

18 efforts are devoted to the synthesis of such colloidal capsules, by which the integration of modular

19 e. the Pickering-emulsion based formation of colloidal capsules, the colloidal particle deposition on

20 e successfully synthesized and characterized colloidal carotene carbon nanoparticle (C(3)-NP), in whi

21 nding of the role of ligand or adsorbates in colloidal catalysis and photocatalysis and have importan

22 Here, we introduce the process of colloidal catalysis, in which clusters of particles cata

23 ns-styryl sulfone by visible-light-absorbing colloidal CdS quantum dots (QDs), without a sacrificial

24 Potentiometry is also reported for colloidal CdSe NCs, which show more negative conduction-

25 printable high-refractive index material and colloidal CdSe/CdS quantum dots (QDs) for applications i

26 One such material is colloidal CeO2 (ceria), whose applications include catal

27 route to simply 'pull' flexible granular and colloidal chains out of a dispersion by combining field-

28 ENM suspensions in cell culture media; (ii) colloidal characterization of suspended ENMs, particular

29 ved for the soot (1.4 x 10(-20) J) using the colloidal chemistry approach.

30 linear defects-disclinations in a lyotropic colloidal cholesteric liquid crystal: a continuous helic

31 and theoretically, cooperative chirality in colloidal cinnabar mercury sulfide nanocrystals that ori

32 programmed the self-assembly of micron-sized colloidal clusters with structural information stemming

33 g new directions in self-assembly of complex colloidal clusters.

34 Infrared spectral analyses showed that the colloidal complexes resulting from ligand exchange betwe

35 Using a solution with an optimized colloidal concentration, devices that reach current-volt

36 for films prepared from solutions with lower colloidal concentrations are observed.

37 Prior immobilization of HSA on the colloidal crystal allows formation of molecularly imprin

38 Our method utilizes double-layer colloidal crystal templates in conjunction with site-spe

39 A colloidal crystal templating with optimized electrochemi

40 DNA-guided nanoparticle colloidal crystallization allows for the formation of mi

41 eliberately synthesize hundreds of different colloidal crystals spanning dozens of symmetries, but th

42 s been used to prepare hundreds of different colloidal crystals, but almost invariably with the restr

43 mbly is a powerful approach for constructing colloidal crystals, where spheres, rods or faceted parti

44 erstructures, including cubic and tetragonal colloidal crystals, with no known atomic analogues, as w

45 ethod that allows partial cation exchange in colloidal CsPbBr3 NCs, whereby Pb(2+) is exchanged for s

46 y, we develop an in situ doping approach for colloidal CsPbBr3 perovskite NCs with heterovalent Bi(3+

47 Colloidal CsPbX3 (X = Br, Cl, and I) perovskite nanocrys

48 cation exchange is still underdeveloped for colloidal CsPbX3 NCs.

49 d small angle neutron scattering data of the colloidal dispersion.

50 Colloidal dispersions of amine bound nanocrystals (CdSe-

51 tons in a fluid chiral ferromagnet formed by colloidal dispersions of magnetic nanoplates.

52 These drops differ from typical evaporating colloidal drops primarily due to their concentration-dep

53 y different from the conventional (single or colloidal) dye molecules and quantum dots.

54 uW, a very low threshold for any laser using colloidal emitters.

55 The method relies on colloidal engineering to produce a printable "metallized

56 minant phases: organically complexed Fe, and colloidal Fe (oxy)hydroxides, stabilized by surface inte

57 nd zeta potential, decreased the fraction of colloidal Fe, and improved NOM removal.

58 , we report the direct solution synthesis of colloidal few-layer TMD alloys, MoxW1-xSe2 and WS2ySe2(1

59 ll infiltration of the construct through the colloidal-filled tunnels.

60 lf-de-bonding sol-gel films, and even drying colloidal films, along with this study, share the same p

61 modified electrostatic, dispersion and other colloidal forces.

62 ain the nanoplastic portion, we isolated the colloidal fraction of seawater.

63 we introduce a method, which we refer to as colloidal fusion, for fabricating functional patchy part

64 tural and mechanical properties of composite colloidal gels and opens up new avenues for practical ap

65 These injectable and moldable colloidal gels are able to withstand substantial compres

66 Composite colloidal gels are formed by the pH-induced electrostati

67 y scattering experiments on lens tissue show colloidal gels of S-crystallins at all radial positions.

68 up new avenues for practical application of colloidal gels.

69 Here, we use a colloidal glass as the model system to directly study th

70 he rapid solidification induced softening of colloidal glass is observed to originate from fewer immo

71 to monitor the stress-bearing properties of colloidal glass.

72 ated on video microscopy data of hard-sphere colloidal glasses.

73 ity was 10-fold higher than the conventional colloidal gold based strip biosensor.

74 Colloidal gold nano-particles (GNP) were prepared and us

75 membranes and is able to self-assemble into colloidal gold nanoclusters or membranes in a controlled

76 that utilized protein-induced aggregation of colloidal gold nanostars (AuNS) to rapidly detect EV71 w

77 A range of different labels (colloidal gold, carbon black and magnetic nanoparticles)

78 We used colloidal gold-palladium nanoparticles, rather than the

79 and effective tool for in situ monitoring of colloidal growth.

80 hyrin iron(III) chloride (FeTPP) catalyst by colloidal, heavy metal-free CuInS2/ZnS quantum dots (QDs

81 discussed in light of possible formation of colloidal HgS(s) passing the 0.22 mum filters used to de

82 ss observed in artificial supramolecular and colloidal homologues.

83 Here we designed and synthesized new colloidal hybrid silica nanoparticles passivated with a

84 systems, we report a supramolecular polymer-colloidal hydrogel (SPCH) composed of 98 wt % water that

85 Naringin-carrying CHC-beta-GP-glycerol colloidal hydrogel can be used to inhibit induction of e

86 However, how chirality of colloidal inclusions affects these long-range interactio

87 without the aid of topological objects like colloidal inclusions.

88 In the past couple of decades, colloidal inorganic nanocrystals (NCs) and, more specifi

89 njectable mesoporous silica formulations are colloidal instability, hemolysis and inefficient drug lo

90 force arises from hierarchical molecular and colloidal interactions.

91 imultaneous control of particle motility and colloidal interactions.

92 ously to monitor oxidation of highly uniform colloidal iron nanoparticles, enabling the reconstructio

93 ncentration and surface quenching effects in colloidal lanthanide-doped nanocrystals, and that inert

94 molecular level and nanofibril formation at colloidal-length scale.

95 f iridescent, vividly colored materials from colloidal liquid crystal suspensions of cellulose nanocr

96 of suspended particles (pulp) dispersed in a colloidal liquid medium (serum).

97 rees C into a stable and homogeneous aqueous colloidal (<100 nm) suspension.

98 ring bioreduction was likely associated with colloidal magnetite nanoparticles.

99 eveloping means of generating reconfigurable colloidal materials.

100 tex beam propagation in engineered nonlinear colloidal medium.

101 represent the first example of a reversible colloidal membrane, but it also can be controlled by a d

102 ted with scalloped edges, demonstrating that colloidal membranes have positive Gaussian modulus.

103 chiral symmetry breaking can be used to fold colloidal membranes into 3D shapes.

104 onodisperse rod-like particles assemble into colloidal membranes, which are one-rod-length-thick liqu

105 olecular twisted ribbons and two-dimensional colloidal membranes.

106 the discovery of stable, atomically precise, colloidal metal nanoclusters.

107 The growth of colloidal metal nanocrystals typically involves an autoc

108 and versatile approach for the synthesis of colloidal metal nanocrystals.

109 talytic process involved in the synthesis of colloidal metal nanocrystals.

110 Multispectral colloidal metasurfaces are fabricated that exhibit great

111 Ionic colloidal molding is a simple yet effective approach of

112 This ionic colloidal molding method stabilizes hydroxyapatite precu

113 Unlike 3D edgeless bilayer vesicles, colloidal monolayer membranes form open structures with

114 tor assembly' by manipulating particles on a colloidal monolayer substrate with optical tweezers.

115 f filamentous viruses can self-assemble into colloidal monolayers with thermodynamically stable rafts

116 els and charging potentials of free-standing colloidal n-type ZnO nanocrystals possessing between 0 a

117 rmodynamic stability of these 'magic-number' colloidal nanoclusters as a function of their atomic-lev

118 In situ microscopy of colloidal nanocrystal growth offers a unique opportunity

119 Here we show that colloidal nanocrystal quantum dots (QDs) can serve as ef

120 The mechanical properties of colloidal nanocrystal superlattices can be tailored thro

121 and long (>400 mus) emission lifetimes in a colloidal nanocrystal system opens promising new opportu

122 tic polarons (DBMPs) in 2.8-nm diameter CdSe colloidal nanocrystals (NCs).

123 d inexpensive solution-processable materials.Colloidal nanocrystals are a promising material for easy

124 s into the luminescence of copper-containing colloidal nanocrystals are reviewed in the context of th

125 Our results show that colloidal nanocrystals are suitable for compact and effi

126 Crystallization of colloidal nanocrystals into superlattices represents a p

127 ent population inversion and optical gain in colloidal nanocrystals realized with direct-current elec

128 Here, we demonstrate a nanolaser using colloidal nanocrystals that exhibits a threshold input p

129 mong the various postsynthesis treatments of colloidal nanocrystals that have been developed to date,

130 spite its universal role in the synthesis of colloidal nanocrystals, it is still poorly understood an

131 We report on using a colloidal nanographene to form a molecular complex with

132 Fabricated using three-dimensional colloidal nanolithography and atomic layer deposition, t

133 ights lead toward rational design of diverse colloidal nanomachines.

134 Two-dimensional colloidal nanomaterials are running into renaissance aft

135 ificial solids and thin films assembled from colloidal nanomaterials give rise to versatile propertie

136 g opportunities and remaining challenges for colloidal nanomaterials in electronic applications, ther

137 the field-effect transistor - as a platform, colloidal nanomaterials in three electronic material cat

138 Polyelectrolyte (PE) wrapping of colloidal nanoparticles (NPs) is a standard method to co

139 adopted a modular design approach that uses colloidal nanoparticles as substrates to create a multiv

140 g of the three-dimensional (3D) evolution of colloidal nanoparticles in solution is essential for und

141 erstanding of many fundamental properties of colloidal nanoparticles in which the total structures (c

142 Adding colloidal nanoparticles into liquid-crystal media has be

143 trolling the shapes and surface chemistry of colloidal nanoparticles, spatial control of nanoparticle

144 25-300 nm red amorphous Se(0) aggregates of colloidal nanoparticles.

145 of single-phase all-inorganic materials from colloidal nanoparticles.

146 Colloidal nanoplatelets are atomically flat, quasi-two-d

147 Non-magnetic colloidal nanostructures can demonstrate magnetic proper

148 The synergetic effect of nickel, colloidal nickel hydroxide islands, and the enhanced sur

149 ilization of surfactant-assisted synthesized colloidal noble metal nanoparticles (NPs, such as Au NPs

150 In addition, the versatile chemistry of colloidal NRs enables the formation of semiconductor het

151 ntaneous assembly of micro-compartmentalized colloidal objects capable of controlled interactions off

152 ent progress in the chemical construction of colloidal objects comprising integrated biomimetic funct

153 pment of new materials based on consortia of colloidal objects, and provide a novel microscale engine

154 tional order of nearest neighbor clusters in colloidal packings by statistically analyzing the angula

155 n based formation of colloidal capsules, the colloidal particle deposition on (sacrificial) templates

156 Our system is a micron-scale colloidal particle in water, in a virtual double-well po

157 ribution around a pair of such heated/cooled colloidal particles agrees quantitatively with the theor

158 At equilibrium, colloidal particles always gather at the bottom of any a

159 itions, as demonstrated in recent studies of colloidal particles and glass-forming metallic systems.

160 ent, separation mechanism for mum and submum colloidal particles and organelles, taking advantage of

161 Synthetic patchy colloidal particles are often poor geometric approximati

162 microcapsules with shells of densely packed colloidal particles closer to application in fields such

163 Colloidal particles disturb the alignment of rod-like mo

164 wever, in other respects, the nonequilibrium colloidal particles do not behave as monopoles: They can

165 Colloidal particles endowed with specific time-dependent

166 Utilizing colloidal particles for the assembly of the shell of nan

167 scillatory micromotor system in which active colloidal particles form clusters, the size of which cha

168 Spherical colloidal particles generally self-assemble into hexagon

169 Artificial self-propelled colloidal particles have recently served as effective bu

170 bined with Maxwell's equations, suggest that colloidal particles heated or cooled in certain polar or

171 ation gradient to drive autonomous motion of colloidal particles in the highly confined space, and th

172 Here, the silica colloidal particles interact with each other and the por

173 We show that chirality of colloidal particles interacts with the nematic elasticit

174 the sole mechanism that enables transport of colloidal particles into or out of the channels, but it

175 The self-organization of colloidal particles is a promising approach to create no

176 he monopole-like fields around heated/cooled colloidal particles is crucial because the experimental

177 d transition in a 2D crystal of paramagnetic colloidal particles is induced by a magnetic field [Form

178 erated by the dissociation of carbonic acid, colloidal particles move either away from or towards the

179 This method separates colloidal particles of comparable density by mass.

180 Patches on the surfaces of colloidal particles provide directional information that

181 Colloidal particles subject to an external periodic forc

182 lf-spinning objects such as chiral grains or colloidal particles subject to torques.

183 nk contains bubbles stabilized by attractive colloidal particles suspended in an aqueous solution.

184 o immiscible liquids, kinetically trapped by colloidal particles that are irreversibly bound to the o

185 LCA) to a multicomponent system of spherical colloidal particles to enable the rational design and pr

186 merical determination of forces between such colloidal particles would be complicated by the presence

187 conjunction with the structural rigidity of colloidal particles, we demonstrate the parallel self-as

188 s that are driven by changes in the shape of colloidal particles.

189 re, we studied electronic impurity doping of colloidal PbSe quantum dots (QDs) using a postsynthetic

190 We show that in squid, patchy colloidal physics resulted from an evolutionary radiatio

191 and application of reversibly reconfigurable colloidal plasmonic nanomaterials based on the actuation

192 nt, which can be cured and purified to yield colloidal polyhedra.

193 e (ca. 11.0 g per batch) and low-temperature colloidal processing route for Bi2 Te2.5 Se0.5 hollow na

194 sinase from Trichoderma reesei to modify the colloidal properties of protein particles in order to im

195 particle systems having similar chemical and colloidal properties.

196 The demonstrated electrical control of the colloidal QD emission provides a new approach for modula

197 is the most creative and critical aspect of colloidal qdots.

198 Dynamic emission control of colloidal QDs in an optoelectronic device is usually ach

199 Colloidal quantum dots (CQDs) feature a low degeneracy o

200 Recently, doped colloidal quantum dots (CQDs) have been demonstrated to

201 Emission control of colloidal quantum dots (QDs) is a cornerstone of modern

202 radiative processes are usually quenched in colloidal quantum dots by Auger and other nonradiative d

203 e their various potential applications, InAs colloidal quantum dots have attracted considerably less

204 ccount of copper doping into atomically flat colloidal quantum wells (CQWs).

205 Here, the authors combine colloidal quantum wells with a photonic-crystal cavity i

206 These new colloidal routes present a promising general method to p

207 We report colloidal routes to synthesize silicon@carbon composites

208 Assessing the heterogeneity of a colloidal sample in terms of its molecular functionaliza

209 esize shape-shifting patchy particles on the colloidal scale is described.

210 l synergy between DNA origami technology and colloidal science, in which the former allows for rapid

211 ar-reaching consequences for the fundamental colloidal science, opening new directions in self-assemb

212 have important implications in both applied colloidal science, such as in separation and fractionati

213 as done by combining DNA nanotechnology with colloidal science.

214 Furthermore, colloidal self-assembly has been utilized to help manufa

215 As colloidal self-assembly increasingly approaches the comp

216 of gold triangular nanoprisms, we show that colloidal self-assembly is analogous to polymerization i

217 Here, colloidal self-assembly is used to organize polystyrene-

218 Inspired by these natural materials, colloidal self-assembly provides a convenient way to pro

219 caused by chiral springs and helices on the colloidal self-organization in a nematic liquid crystal

220 , charge transport and catalysis between the colloidal semiconductor and molecular components, the ac

221 of the fundamental physics and chemistry of colloidal semiconductor nanocrystal quantum dots (QDs) h

222 Colloidal semiconductor nanocrystals have emerged as pro

223 Doping lanthanide ions into colloidal semiconductor nanocrystals is a promising stra

224 at band edge positions of lead sulfide (PbS) colloidal semiconductor nanocrystals, specifically quant

225 te that double heterojunctions designed into colloidal semiconductor nanorods allow both efficient ph

226 Electronic doping of colloidal semiconductor nanostructures holds promise for

227 al synthesis and optimized light emission by colloidal semiconductor quantum dots (qdots).

228 Colloidal semiconductor quantum dots are attractive mate

229 ve uric acid detection using a simple, rapid colloidal SERS approach without the need for complex dat

230 Furthermore, the Raman measurements from colloidal SERS were more sensitive in probing the aggreg

231 he potential between monodisperse, spherical colloidal silica particles using salt and surfactant add

232 d of silicon NPs has been deposited from the colloidal solution generated by laser ablation.

233 A colloidal solution is a homogeneous dispersion of partic

234 s as a result of the laser action on a mixed colloidal solution is observed.

235 We report a superoxide colloidal solution route for preparing a LBSO electrode

236 adsorbed on the silica surface, and aqueous colloidal solutions of the core-shell particles are used

237 ated via spin-casting of Ti3 C2 Tx nanosheet colloidal solutions, followed by vacuum annealing at 200

238 mimicking experimentally realized artificial colloidal spin ice systems, and show how defect lines ca

239 , was optimally PEGylated not only to ensure colloidal stability (no change in size by DLS between 0

240 n, the C-dots (2.8+/-0.8nm) possessed a good colloidal stability and exhibited a positive surface cha

241 As a result, the colloidal stability and foaming properties were improved

242 protein particles in order to improve their colloidal stability and foaming properties.

243 synthesized colloids is the key to achieving colloidal stability and high affinity to biomolecules as

244 covery provides a novel method for enhancing colloidal stability and opens a novel opportunity for en

245 many solute-solvent combinations shows that colloidal stability can be traced to the strength of che

246 tation of some of the 2DMs is their moderate colloidal stability in aqueous media.

247 ase did not have effect on zeta-potential or colloidal stability of either protein, but it impaired f

248 entrations studied (0-10 mg/ml) and improved colloidal stability of MSNR.

249 influence of electrolytes and aqueous pH on colloidal stability of these NPs was investigated by mea

250 QD inks, because of several issues: 1) poor colloidal stability, 2) use of high-boiling-point solven

251 Changes to nanoparticle surface charge, colloidal stability, and hydrodynamic properties induced

252 with polyethylenimine-coating provides high colloidal stability, enhanced cellular uptake, and distr

253 oporous silica nanorods (MSNR) on hemolysis, colloidal stability, mitoxantrone (MTX) loading, in vitr

254 ultaneously maintaining the shape, size, and colloidal stability.

255 hirality that exhibit significantly improved colloidal stability.

256 In contrast, colloidal stabilization in solvents with low polarity, s

257 nderstanding of the driving forces for their colloidal stabilization is very limited.

258 s to the complex landscape of nonequilibrium colloidal structures, guided by biological design princi

259 usly shown to accumulate plutonium (Pu) in a colloidal subfraction and is hypothesized to contain cut

260 d into chained, branched, zigzag, and cyclic colloidal superstructures in a highly site-specific mann

261 ic elasticity to predefine chiral or racemic colloidal superstructures in nematic colloids.

262 tetrahedra and spheres, obtaining a class of colloidal superstructures, including cubic and tetragona

263 d using ultralow cross-linked microgels, the colloidal suspension displays viscous behavior on the sa

264 parating suspended particles by exposing the colloidal suspension to CO2.

265 These nanoparticles remain a stable colloidal suspension under a wide range of buffers and i

266 sed by elaborately restricting the drying of colloidal suspension using a flow-enabled self-assembly

267 o single-walled carbon nanotubes (SWCNTs) in colloidal suspension.

268 and conjugations to be performed within the colloidal suspensions (i.e., Protein A and antibody bind

269 Viscoelastic phase separation of colloidal suspensions can be interrupted to form gels ei

270 Dense colloidal suspensions can propagate and absorb large mec

271 ble in groups of sperm, Japanese tree frogs, colloidal suspensions of magnetic particles, and other b

272 cal vortex solitons propagating in nonlinear colloidal suspensions with exponential saturable nonline

273 med in ideal lossless media and in realistic colloidal suspensions with losses, provide a detailed de

274 report two unique observations; first, that colloidal suspensions, at sufficiently high volume fract

275 uid crystal phase transitions in anisotropic colloidal suspensions.

276 dimensional nanocrystal superlattices during colloidal synthesis at high temperatures (more than 230

277 We report the colloidal synthesis of approximately 5.5 nm inverse spin

278 We report the nontemplated colloidal synthesis of single crystal CsPbBr3 perovskite

279 We report a low-temperature colloidal synthesis of single-layer, five-atom-thick, be

280 To stabilize a colloidal system against coalescence and aggregation, th

281 othesis when pectinase effectively disrupted colloidal system and precipitated lycopene.

282 we adapt this raster/vector concept to a 2D colloidal system and realize 'vector assembly' by manipu

283 of the transition is [Formula: see text] Our colloidal system provides an experimental test bed to pr

284 Here, we present a novel colloidal system that shows transient clustering driven

285 along with other excipients to stabilize the colloidal system.

286 We use microscopy to study colloidal systems as they approach their glass transitio

287 strates a versatile strategy for engineering colloidal systems for use in materials science and biote

288 Here we report a class of colloidal systems in which solute particles (including m

289 xert a disproportionately large influence on colloidal systems owing to their greater surface area; h

290 open different routes to creating emulsions, colloidal systems, and emulsion-based materials.

291 In nanoscale colloidal systems, however, less is known about the phys

292 A number of colloidal systems, including polymers, proteins, micelle

293 ched disordered out-of-equilibrium many-body colloidal systems, there are important distinctions betw

294 er condensed matter phenomena have come from colloidal systems, whose micron-scale particles mimic ba

295 ic melts offer opportunities for introducing colloidal techniques to solid-state science and engineer

296 demonstrate the approach using preassembled colloidal tetrahedra and spheres, obtaining a class of c

297 e lattices to triangular lattices in tunable colloidal thin films with single-particle dynamics by vi

298 UV-irradiation of aqueous, colloidal TiO2 nanoparticles in the presence of methanol

299 atomic-level insights into the structures of colloidal TMD alloy nanostructures that were previously

300 A four-step colloidal total synthesis was developed, where the key s