ライフサイエンスコーパス: colloidal

1 and silver deposit at room temperature onto colloidal 1T-WS(2), 2H-WS(2), 2H-MoSe(2), 2H-WSe(2), 1T'

2 tion of densely-packed quasi-spherical Au/Ag colloidal aggregates.

3 upstream), pore blocking (inside the pores), colloidal aggregation (downstream) and colloidal streame

4 In these colloidal alloy phases, PAEs occupy lattice positions, w

5 hytochemicals with various physico-chemical, colloidal and interfacial properties.

6 Salient features include exclusion of colloidal and molecular solutes, and characteristic ligh

7 ement with experimental observations on both colloidal and noncolloidal suspensions.

8 ter exhibiting high brightness and excellent colloidal and optical stability.

9 These also retained the colloidal and phase stability, as well as showed near un

10 ronic devices has been hampered by issues of colloidal and photophysical instability.

11 that this coating approach imparts enhanced colloidal and photophysical stability to the nanocrystal

12 by a simple and economical route of one-pot colloidal and sputtering technique.

13 he optimization of nanoparticles grown via a colloidal approach with a chemical reducing agent or syn

14 covery is ligand self-association into large colloidal assemblies that nonspecifically inhibit target

15 ent an approach for selective and controlled colloidal assembly at lipid membranes, opening routes to

16 dy we present the modification of conductive colloidal atomic force-scanning electrochemical microsco

17 model glass-former that describes granular, colloidal, atomic and molecular glasses by changing the

18 ate the phase behavior of differently curved colloidal bananas using confocal microscopy.

19 Colloidal based films have been widely developed for a w

20 vestigate stochastic transport properties of colloidal beads in antiparallel networks of overlapping

21 bonding taking place at an atomic level and colloidal bonding occurring at the length scale two orde

22 ing, whereas electrostatic repulsion between colloidal bonds governs CM symmetry.

23 e behaviors, but so far, using zeolites as a colloidal building block to construct ordered superstruc

24 s calcium and phosphate into 70-100 nm-sized colloidal calciprotein particles (CPPs).

25 of the casein micelles, and modifying their colloidal calcium phosphate and the ratio of soluble to

26 ight-gated protocell model made of plasmonic colloidal capsules (CCs) assembled with bacteriorhodopsi

27 performed on a hybrid material consisting of colloidal CdSe/CdS QDs, magnetite Fe(3)O(4) NPs, and SU-

28 This highlights the important role of colloidal chemistry in the discovery of new materials an

29 Using colloidal chemistry to exquisitely control nanoparticle

30 nabled by single walled carbon nanotubes and colloidal clays, ii) the molecular level integration of

31 lk gland suggested that posterior gland silk colloidal complexes transition into a nanofibrous morpho

32 The colloidal complexes yielding the highest concentration o

33 parate materials, ranging from polymeric and colloidal compounds to high-transition-temperature super

34 e surfaces after an acidic pretreatment, and colloidal CoP nanoparticles.

35 Cation exchange reactions of colloidal copper sulfide nanoparticles are widely used t

36 Here, we describe the design of "colloidal crystal alloys" by combining gold PAEs of two

37 d realizing complex, integrated devices with colloidal crystal components, and this approach provides

38 Colloidal crystal engineering with DNA has emerged as a

39 ore, increase the scope of possibilities for colloidal crystal engineering with DNA.

40 Colloidal crystal engineering with nucleic acid-modified

41 tudy of the periodic plasma created from the colloidal crystal.

42 dynamical processes of interstitials in a 2D colloidal crystal.

43 tation and shock wave propagation inside the colloidal crystal.

44 een chemical bonds and entropic bonds in the colloidal crystallization of hard hexagonal nanoplates.

45 mineralization, templating, pharmaceuticals, colloidal crystallization, and geochemistry.

46 We also find that by using monolayer colloidal crystals as templates, a variety of eutectic m

47 de an attractive alternative for stabilizing colloidal crystals engineered with DNA and make them pot

48 ase pairs in DNA bonds that, in part, define colloidal crystals engineered with DNA.

49 ing of elastic monopoles to a zoo of unusual colloidal crystals formed by high-order multipoles like

50 Colloidal crystals have emerged as promising candidates

51 Here we form ionic colloidal crystals in water through an approach that we

52 A versatile method for the design of colloidal crystals involves the use of DNA as a particle

53 dal particles and commercial polymers, ionic colloidal crystals isostructural to caesium chloride, so

54 Displacive transformations in colloidal crystals may offer a pathway for increasing th

55 X-ray diffraction measurements of excited colloidal crystals may then lead towards a better unders

56 Two-dimensional colloidal crystals of submicrometer microspheres provide

57 new materials and methods provide access to colloidal crystals that incorporate particles with the w

58 method for synthesizing and photopatterning colloidal crystals via light-responsive DNA is developed

59 oparticles on centimeter-scale thin films of colloidal crystals, allowing them to be photopatterned i

60 This discovery defines a new property of colloidal crystals-metallicity-that is characterized by

61 dral clusters with retracted sticky patches, colloidal cubic diamond can be self-assembled using patc

62 PRAS was rapidly formed by the addition of a colloidal decanoic acid suspension to tetrahydrofuran (T

63 However, self-assembly of colloidal diamond is challenging.

64 y time dynamics of spin coating concentrated colloidal dispersions, which can disrupt the formation o

65 ved size spectra of ultrafiltration-isolated colloidal DOM show that peak-C related fluorophores (E(x

66 WS mean-square displacements (MSDs) in dense colloidal emulsions.

67 Our results further show that while colloidal Fe(III) (in this work, particles >0.025 mum) i

68 ble annealing protocol based on a controlled colloidal flow above the carpet that enables complete cr

69 vides a useful guide to prepare ZIF-8 in its colloidal form, covering the published studies on the sy

70 t our system exhibits the characteristics of colloidal gelation, leading to nonsticky gels.

71 e of the particles, which can even result in colloidal gelation, the mechanics of the suspension can

72 Colloidal gels can be used to interrogate the angiogenic

73 entally probe these phases of matter using a colloidal glass.

74 Anti-LMG-colloidal gold conjugate was immobilized onto the conjug

75 bromide (MTAB) self-assembled monolayers on colloidal gold nanospheres (AuNSs) with diameters from 1

76 trast enhancement is demonstrated first with colloidal gold particles and then in representative cryo

77 Here, a colloidal graphene quantum dot (GQD)-based nanosurfactan

78 a shape whose synthesis is challenging in a colloidal growth environment.

79 osahedra was used to develop a corresponding colloidal growth solution by tailoring a weak reducing a

80 the rotational motion predicted by classical colloidal hydrodynamics.

81 with a tris(amino)arsenic precursor to yield colloidal InAs quantitatively and at gram scale.

82 Among these materials, colloidal InAs quantum dots (QDs) stand out as an infrar

83 ral, with five different 2D COFs prepared as colloidal inks and subsequently spray-coated onto a dive

84 mon subsurface nanomaterial failures include colloidal instability (aggregation) and sticking to mine

85 serve as a designer toolkit for engineering colloidal interaction and self-assembly, potentially exc

86 Colloidal interactions in nematic liquid crystals can be

87 olution of defect configurations, as well as colloidal interactions, by tuning the preferred tilt ang

88 es conventional colloids to be used as model colloidal ions, primed for crystallization.

89 80, Tween), on the size and stability of the colloidal ketoprofen (KTP)-rich phase generated by liqui

90 lass of such nanomaterials is represented by colloidal lanthanide-doped semiconductor nanocrystals (L

91 of solution-processable electrically-driven colloidal lasers.

92 o prepare uniform and finely size-controlled colloidal lead halide perovskite QDs for various optoele

93 We now demonstrate that individual colloidal lead halide perovskite quantum dots (PQDs) dis

94 The successful growth of colloidal lead halide perovskite quantum dots (PQDs) has

95 -generating microtubule bundles in a passive colloidal liquid crystal to form a three-dimensional act

96 he understanding of UV plasmon resonances in colloidal liquid-metal EGaIn nanoparticle suspensions.

97 The limited gamut of currently available colloidal LnSNCs is unfortunate, given the tremendous te

98 view, we provide an overview of the field of colloidal LnSNCs, while distilling the lessons learnt in

99 hway to combine quasi-3D nanostructures with colloidal materials-based optoelectronics and access a n

100 like configurations are an emerging class of colloidal materials.

101 at chiral rod-like inclusions dissolved in a colloidal membrane of opposite handedness assemble into

102 rolling the shapes and related properties of colloidal metal nanocrystals are key to the realization

103 The colloidal microstructure in stable suspensions evolves c

104 investigate the crystallization of a binary colloidal mixture with single-particle resolution.

105 which exine-like patterns were generated in colloidal mixtures by self-assembly, without any genomic

106 structure of self-assembling, multicomponent colloidal mixtures.

107 scopic studies of the dynamics of melting in colloidal model systems.

108 contrary to their bulk powder counterparts, colloidal MOF particles can additionally be dispersed, s

109 gs of functional groups are used to assemble colloidal molecules (CMs); however, high-yield generatio

110 nd assembly of specific colloids such as the colloidal molecules as defined by van Blaaderen in 2003

111 esents a versatile platform for constructing colloidal molecules with multiple components having cust

112 rategy for the fabrication of multicomponent colloidal "molecules" with controllable complex morpholo

113 We apply oscillatory shear to solid colloidal monolayers and study their particle trajectori

114 The ongoing interest in colloidal nanocrystal solids for electronic and photonic

115 Unfortunately, colloidal nanocrystal solids generally possess very low

116 otodetectors, and light-emitting diodes) and colloidal nanocrystals (e.g., in liquid crystal displays

117 l work has been devoted to understanding why colloidal nanocrystals (NCs) self-assemble into such a d

118 The bottom-up assembly of colloidal nanocrystals is a versatile methodology to pro

119 Electroluminescence of colloidal nanocrystals promises a new generation of high

120 Lead halide perovskite colloidal nanocrystals provide an interesting proving gr

121 ing particle size and particle loading using colloidal nanocrystals, we reveal the opposite process a

122 extend our synthesis scheme to Pb(4)S(3)I(2) colloidal nanocrystals, whose structure matches the one

123 er than previously reported values among all colloidal nanocrystals.

124 by simply spinning, brushing or dip coating colloidal nanoink onto a substrate with minimum error (e

125 s between microfluidic reactor engineers and colloidal nanomaterial chemists.

126 ms have yet to be extensively adopted by the colloidal nanomaterial community.

127 of fluidic platforms in recent high-priority colloidal nanomaterial studies and their potential for i

128 chniques may affect the surface chemistry of colloidal nanomaterials.

129 composition-controlled synthesis of various colloidal nanomaterials.

130 cal measurements of both electrochemical and colloidal nanoparticle growth.

131 trategy to precisely arrange any anisotropic colloidal nanoparticle onto a substrate using a shallow-

132 The first colloidal nanoparticle synthesis of the copper selenopho

133 Ligands are of tremendous importance for colloidal nanoparticles (NPs) in terms of surface protec

134 Here, we use colloidal nanoparticles assembling into supracrystals as

135 of high quality and biocompatible plasmonic colloidal nanoparticles has fostered numerous and expand

136 ent nanopatterning techniques for functional colloidal nanoparticles have been dreamed about by scien

137 access the hydration shell structures around colloidal nanoparticles in scattering experiments.

138 technique that can print various functional colloidal nanoparticles into arbitrarily defined pattern

139 Rational synthesis of colloidal nanoparticles with desirable properties relies

140 lving unsupported metal nanoparticles (i.e., colloidal nanoparticles).

141 w of the past and present literature on both colloidal nanostructures and multilayered compounds, emp

142 ixing of two liquid crystalline solutions: a colloidal nematic phase comprised of graphene oxide plat

143 , which is likely applicable to many charged colloidal or macromolecular systems in which the structu

144 ing in the liquid phase, catalyzed by either colloidal or supported metal NPs.

145 and P and that this leads to the release of colloidal P and iron (Fe).

146 We find that dry colloidal packings, as characterized by contact number a

147 structural and geometric information of dry colloidal packings.

148 In addition, neutralization kept a stable colloidal particle size for pHs decreased to pH 9,8 and

149 lization created casein aggregates of larger colloidal particle size than primary casein micelle in c

150 reproduced by either biopolymer networks or colloidal particle systems alone.

151 ants, and these typically bound tighter to a colloidal particle, while the only mutant it stabilized

152 y diffusing in all directions, they resemble colloidal particles and atoms, self-assembling into crys

153 he non-invasive trapping and manipulation of colloidal particles and biological cells(1,2).

154 Using a variety of colloidal particles and commercial polymers, ionic collo

155 opole-to-quadrupole reconfiguration of these colloidal particles by unstructured light, which resembl

156 Colloidal particles covered with chemically-active patch

157 BCC) crystals and their liquid using charged colloidal particles in an electric bottle.

158 Self-assembling colloidal particles in the cubic diamond crystal structu

159 The colloidal particles in the self-assembled cubic diamond

160 The dynamical arrest of attractive colloidal particles into out-of-equilibrium structures,

161 teraction, which enables the manipulation of colloidal particles on solid substrates with optical sca

162 quid crystalline behavior can be probed with colloidal particles that are macro-aggregates of biomole

163 r strategy uses motors in the form of active colloidal particles that constantly propel forward.

164 Here, we use shape anisotropy of colloidal particles to introduce chiral rollers with act

165 scalable bulk synthesis of customized chiral colloidal particles with geometric and compositional chi

166 We develop model "banana-shaped" colloidal particles with tunable dimensions and curvatur

167 l science, where the main goal is to develop colloidal particles(2,3) that mimic and exceed the diver

168 es with payloads, into stable suspensions of colloidal particles, and the different means for trigger

169 unexpected, charge-dependent accumulation of colloidal particles, which occurs in a common-flow confi

170 he binding selectivity of cargo-transporting colloidal particles.

171 y using robust diamond-coated spheres, i.e., colloidal particles.

172 ers, bimetallic nanorods, as well as passive colloidal particles.

173 The controlled anisotropic growth of colloidal plasmonic nanostructures and their dynamic mod

174 We solved the structures of individual colloidal platinum nanocrystals by developing atomic-res

175 that precise control of the heteroepitaxy of colloidal polyhedral nanocrystals enables ordered grain

176 ary of suitable polymerization reactions for colloidal polymer derived porous carbon spheres.

177 nt U was interpreted as occurring within the colloidal pool of U.

178 ensor by using the recently established soft colloidal probe (SCP) technique.

179 detect binding of proteins to functionalized colloidal probe particles by monitoring the associated c

180 dependence of altered surface charges of the colloidal probe.

181 Positively biased PDA-coated colloidal probes revealed adhesion forces of 6.0 +/- 1.1

182 observed for negatively biased PDA-modified colloidal probes.

183 The fundamental colloidal properties of pristine graphene flakes remain

184 We report ultrasmall and monodisperse colloidal PtP(2) nanocrystals that achieve H(2)O(2) prod

185 nt a promising device platform for realizing colloidal QD laser diodes.

186 Colloidal QDs can be integrated in devices using solutio

187 s, assembly, and photophysical properties of colloidal QDs that have captured scientific imagination

188 ated to inspire further research on In-based colloidal QDs.

189 g of integrated optoelectronic devices using colloidal QDs.

190 ity and tunable surface ligand properties of colloidal quantum dot (QD) perovskites now enable unprec

191 This Article describes the design of a colloidal quantum dot (QD) photosensitizer for the Pd-ph

192 The emerging technology of colloidal quantum dot electronics provides an opportunit

193 local optoelectronic property variations in colloidal quantum dot solar cells due to film defects, p

194 Colloidal quantum dots (CQDs) are of interest in light o

195 tegration of 3D nanophotonic structures with colloidal quantum dots (CQDs) faces several technologica

196 This Perspective describes some ways that colloidal quantum dots (QDs) address the limitations of

197 Colloidal quantum dots (QDs) are nanoscale semiconductor

198 Colloidal quantum dots (QDs) have shown promise over the

199 s like organic semiconductors and lead based colloidal quantum dots face certain fundamental challeng

200 wever, the rapid spin relaxation observed in colloidal quantum dots limits their functionality.

201 Here we show that colloidal quantum dots serve as visible-light chromophor

202 esonators fabricated from solution-processed colloidal quantum dots.

203 -quantum-well superlattices comprised of the colloidal quantum wells of lead halide perovskites, with

204 odulation of the carrier temperature in such colloidal quantum wells.

205 embrane and find that, in the achiral limit, colloidal rafts acquire complex structural properties an

206 embrane of opposite handedness assemble into colloidal rafts, which are finite-sized reconfigurable d

207 ompartments was observed even when inanimate colloidal rods were used to mimic rod-shaped bacteria, s

208 ments addressing the topic of catalysis with colloidal ruthenium metal nanoparticles through the last

209 sity, and size distribution determination of colloidal samples.

210 f experiments on lipid vesicles supported by colloidal scaffolds and theoretical work, we demonstrate

211 , each scale-invariant and achievable at the colloidal scale.

212 hat is both programmable and compatible with colloidal-scale physics.

213 reconfigurable and autonomous robots at both colloidal scales and macroscales.

214 h, ranging from supramolecular chemistry and colloidal science to robotics and automation.

215 one of the most complex challenges of modern colloidal science, and current strategies often fail to

216 In colloidal science, where the main goal is to develop col

217 Directed colloidal self-assembly at fluid interfaces can have a l

218 Here, we demonstrate a general colloidal self-assembly method to control uniformity of

219 nable, size-controlled emission wavelengths, colloidal semiconductor quantum dots (QDs) are attractiv

220 Colloidal semiconductor quantum dots (QDs) are attractiv

221 Colloidal semiconductor quantum wells have emerged as a

222 ons on: a) the characterization of solid and colloidal SERS substrates by correlative electron and op

223 iscoelastic fluid comprising biopolymers and colloidal silica to enhance adherence and retention of p

224 in the physiologically relevant range using colloidal silver nanoparticles in ethanolic solutions an

225 ill depend on the reactivity of the dominant colloidal size fraction (likely controlled by nanopartic

226 mics and microscopic structure of disordered colloidal solids during plastic deformation.

227 w that our method can be used to process the colloidal solution into 2D and 3D COF shapes as well as

228 ect ratios (ARs) in a chemically-synthesized colloidal solution of Gold Nano Rods (GNRs) is an import

229 Thin films were obtained by spin coating of colloidal solutions made by PNIPAm and PAAc nanogels.

230 synthetic method that yields stable aqueous colloidal solutions of sub-20 nm crystalline imine-based

231 e perovskite QDs reveal impressive water and colloidal stabilities as the surface of QDs is intimatel

232 unable size and exceptionally high water and colloidal stabilities is presented.

233 The high colloidal stability achieved with this long-chain zwitte

234 ime, however, resulted in the improvement of colloidal stability and decrease in turbidity ascribed t

235 cteristics of the particle suspension (i.e., colloidal stability and filterability).

236 e of ligands is of utmost importance for the colloidal stability and function of the nanoparticles.

237 Both hybrids showed improved colloidal stability compared to pure AgNPs, and both sho

238 artially coated with silica to enhance their colloidal stability in aqueous solutions while also main

239 ly used to assess protein conformational and colloidal stability in solution, with the aim to underst

240 ol) surface ligands, allowing them to retain colloidal stability in the precursor solution and to see

241 In particular, a graphene ink with superior colloidal stability is demonstrated by GQD nanosurfactan

242 organic surface coatings with regard to the colloidal stability of engineered manganese oxide nanopa

243 trostatic repulsion has been found to govern colloidal stability of MoS(2) and WS(2) while the van de

244 , grafting density, and configuration on the colloidal stability of organic-coated NPs.

245 ations, which provide direct evidence of the colloidal stability of side-to-side nanorod clusters.

246 Colloidal stability of the protein suspensions steadily

247 QDs (R = 1.17 nm) of up to 111 meV while the colloidal stability of the QDs is maintained.

248 Higher colloidal stability values were achieved by neutral endo

249 Biocompatibility and colloidal stability were confirmed by in vitro assays.

250 al behaviors of CNTs in aqueous media (e.g., colloidal stability, adsorption, and photochemistry) as

251 eir chemical structure, physical properties, colloidal stability, and reactivity.

252 s demonstrated that TMNP exhibited excellent colloidal stability, biocompatibility and drug retaining

253 polymers and proteins, resulting in enhanced colloidal stability, extended blood circulation, and red

254 dual drug-loaded micelles exhibited improved colloidal stability, prolonged drug release and remarkab

255 vents and nanoparticles and thus improve ink colloidal stability.

256 h new properties as well as provide enhanced colloidal stability.

257 rticle size uniformity, and a high degree of colloidal stability.

258 Colloidal stabilization enables detailed structural anal

259 In this study, we demonstrate from a colloidal standpoint that such a blindfolded intracellul

260 res), colloidal aggregation (downstream) and colloidal streamer fouling (downstream).

261 new facts on the relationship between honey colloidal structure and H(2)O(2) production that change

262 reveal a unique route to build self-healing colloidal structures assembled from simple metal nanopar

263 oving the self-assembly of a large number of colloidal structures.

264 y depositing metal seeds onto the surface of colloidal substrates and then selectively passivating th

265 self-aligned with respect to the surface of colloidal substrates.

266 A bonds as a chemical approach for actuating colloidal superlattices.

267 Such colloidal surfactants are found to be able to stabilize

268 Janus colloidal surfactants with opposing wettabilities are re

269 esign and synthesis of two-dimensional Janus colloidal surfactants, which could be utilized in biomed

270 When a colloidal suspension is dried, capillary pressure may ov

271 that the presence of unbound/free ligand in colloidal suspension plays a pivotal role in determining

272 suitable conditions for this are realized in colloidal suspensions and complex plasmas.

273 In this work, colloidal suspensions of boronate-ester-linked 2D COFs a

274 However, MXene oxidation in aqueous colloidal suspensions when stored in water at ambient co

275 We combine experiments on critical Casimir colloidal suspensions, numerical simulations, and analyt

276 ct mechanical measure for these type of soft-colloidal suspensions.

277 ingle crystals by preparing COF particles as colloidal suspensions.

278 ct the design of chromatic patchy particles, colloidal swimmers, and chiral optical materials, as wel

279 l method relative to combinatorial design of colloidal syntheses have the potential to accelerate the

280 Conventional colloidal syntheses of this class of hybrid structures r

281 Finally, measurements of colloidal syntheses were employed as guides for the dire

282 try method was used to translate an existing colloidal synthesis for corrugated palladium (Pd) nanopa

283 We report the colloidal synthesis of a series of surfactant-stabilized

284 We report the colloidal synthesis of an ~3 tungsten-oxygen (W-O) layer

285 Motivated by this, the first success in colloidal synthesis of AuCu/CsPbCl(3) core/shell PNCs an

286 report on strong chiral amplification in the colloidal synthesis of intrinsically chiral lanthanide p

287 In recent years, the colloidal synthesis of intrinsically chiral nanocrystals

288 lical structures at the sub-100 nm scale via colloidal synthesis remains underexplored.

289 Here, we use colloidal synthesis to make ~140 nm length and ~15 nm wa

290 ectrode surface-in close analogy to standard colloidal synthesis-with electrochemical measurements of

291 Here, we describe a nematic colloidal system consisting of mesostructures of gold ca

292 synthetic methods provide a well-controlled colloidal system consisting of nanocrystals with differe

293 A colloidal system for visible-light photo-H(2) generation

294 he MSD, we find that upon densification, our colloidal system moves through several states of matter.

295 Here, however, we demonstrate demixing in a colloidal system of polydisperse, rod-like clay particle

296 al unexpected many-body interactions in this colloidal system, ranging from de-mixing of elastic mono

297 Multi-colloidal systems exhibit a variety of structural and fu

298 st characterized by particle aggregation and colloidal theory for future synthetic strategies.

299 collected from fully-grown pigs for studying colloidal transport of sub-micron sized particles in muc

300 Herein we show that self-assembly of colloidal zeolite LTA superball (ZAS) by tilted-angle se