ライフサイエンスコーパス: nanocluster

1 ize regime (1-3 nm in diameter, often called nanoclusters).

2 surface modifications to this very prominent nanocluster.

3 e drug pamidronate to a NIR fluorescent gold nanocluster.

4 of a platinum atom into a molecule-like gold nanocluster.

5 bling the number of neurexin-1 molecules per nanocluster.

6 ivo oncogenic Ras exists in isoform-distinct nanoclusters.

7 ic state in the size evolution of bimetallic nanoclusters.

8 detecting a variety of thiolate-capped gold nanoclusters.

9 insights into the Au-Ag bonds in bimetallic nanoclusters.

10 assemblies inside cells and are organized in nanoclusters.

11 stable, atomically precise, colloidal metal nanoclusters.

12 ctrical conductivity of the entrapped copper nanoclusters.

13 for the synthesis of high-nuclearity copper nanoclusters.

14 ise to growth of monodisperse, size-tailored nanoclusters.

15 electronic and optical properties of the 58e nanoclusters.

16 imaging revealed that FLS2 and BRI1 form PM nanoclusters.

17 s up to 3 nm, the size regime referred to as nanoclusters.

18 structural polymorphism in these archetypal nanoclusters.

19 easons of the dimensional transition in gold nanoclusters.

20 ated by varying cation substitution to these nanoclusters.

21 ls of the frontier orbitals of Au25(SR)18(-) nanoclusters.

22 m earth-abundant phosphorescent metal halide nanoclusters.

23 in situ monitoring of the formation of gold nanoclusters.

24 by the decreased fluorescence of both metal nanoclusters.

25 ureus with and without labeling by gold (Au) nanoclusters.

26 densities of endogenous antigen-loaded CD1d nanoclusters.

27 rface of the target cell and internalized as nanoclusters.

28 sis was employed to characterize the surface nanoclusters.

29 e, the nanowires collapse into ordered UO(2) nanoclusters.

30 R (Nb80) is highly immobile and organized in nanoclusters.

31 d-shaped Co(12)Se(16)(PEt(3))(10) and C(140) nanoclusters.

32 cles, thereby favoring the dispersion of the nanoclusters.

33 electron redistribution in a series of gold nanoclusters.

34 ion ligand engineering on atomically precise nanoclusters.

35 g the bi-tetrahedral core structures of gold nanoclusters.

36 affecting its motion state distribution and nanoclustering.

37 ters open up an avenue to employ ultra-small nanoclusters (1 nm) for the design of thermal sensors an

38 he design and synthesis of ultrasmall nickel nanoclusters (~1.5 nm) deposited on defect-rich boron ni

39 We report that the giant 246-gold-atom nanocluster (2.2 nm in gold core diameter) protected by

40 After the FUS treatment, radiolabeled gold nanoclusters, (64)Cu-AuNCs, were intravenously injected

41 that oxidative etching of [Au(25)SR(18)](-) nanoclusters adds an excess thiolate ligand and generate

42 cular dynamics study of a test system-a gold nanocluster adsorbed on free-standing graphene clamped b

43 tmospheric aerosol characterization to cover nanocluster aerosol (NCA) particles and show that a majo

44 However, nanocluster aerosol (NCA) particles, that is particles i

45 allows site-selective attachment of a silver nanocluster (AgNC), the reduced or photoexcited state of

46 d across all sub-regions, PSD95 packing into nanoclusters also varied between sub-regions determined

47 ions of the well-known chiral Au(38)(SR)(24) nanocluster and its Pd- and Ag-doped derivatives, we pro

48 ited-state physical chemistry of luminescent nanoclusters and a general strategy for the rational des

49 opy (STM) studies for supported 2D epitaxial nanoclusters and developments in modeling for 3D NCs mot

50 achieved by chemical coupling of active CoO nanoclusters and high-index facet Mn3 O4 nano-octahedron

51 ng chemistry for tailoring the structures of nanoclusters and is expected to open new avenues for des

52 is induced between vesicles containing RhoB nanoclusters and plasma membrane protrusions.

53 ed of strongly coupled Ni-deficient Li(x)NiO nanoclusters and polycrystalline Ni nanocrystals and its

54 rials, nanoscale photonic devices, plasmonic nanoclusters and surface-enhanced Raman scattering (SERS

55 one of them is embedded with label-free gold nanoclusters and the other one with gold nanoparticles c

56 o the concept of conformational isomerism in nanoclusters, and demonstrates the utility of high press

57 th of the catalytically active ultrasmall Ni nanoclusters, and further in stabilizing these nanoscale

58 The development of atomically precise nanoclusters (APNCs) protected by organometallic ligands

59 somatic Nav1.6 channels localized to stable nanoclusters approximately 230 nm in diameter.

60 The aptamer-conjugated silver nanoclusters (Apt@AgNCs) were synthesized and immobilize

61 Copper nanoclusters are a new class of nanomaterials that can p

62 rticle tracking revealed that diffusing CD1d nanoclusters are actively arrested by the actin cytoskel

63 ly precise monolayer-protected gold thiolate nanoclusters are an intensely researched nanomaterial fr

64 s absorption and PLE spectra of the reported nanoclusters are consistent with previously established

65 More than 20,000 Au12, Au13, and Au14 nanoclusters are evaluated.

66 al methods of obtaining chiroptically active nanoclusters are introduced, such as enantioseparation b

67 m, indicating that the means by which Nav1.6 nanoclusters are maintained in the soma is biologically

68 Au nanoclusters are of technological relevance for catalysi

69 hosphorescent emitters based on metal-halide nanoclusters are reported.

70 These data identify PSD95 nanoclusters as a basic structural unit, or building blo

71 ddress stability of thiolate-protected metal nanoclusters as a function of the number of metal core a

72 stability of these 'magic-number' colloidal nanoclusters as a function of their atomic-level structu

73 Forster resonance energy transfer using gold nanoclusters as a signal reporter and gold nanoparticles

74 e results demonstrate the potential of metal nanoclusters as a solution-processed material for semico

75 using geometrically anisotropic superatomic nanoclusters as building blocks.

76 te membrane-bound RAS dimers, oligomers, and nanoclusters as landing pads for effector proteins that

77 e and energetically low structures of BenH2n nanoclusters as predicted using density functional theor

78 for selective self-assembly of molecules or nanoclusters, as well as for the functionalization of th

79 oxylate-ligated indium phosphide magic-sized nanocluster at 0.83 A resolution.

80 e demonstrate that neurexin-1 forms discrete nanoclusters at excitatory synapses, revealing a novel o

81 microscopy, we show that CD1d molecules form nanoclusters at the cell surface of APCs, and their size

82 and Rab37 vesicles and the formation of LAT nanoclusters at the immunological synapse.

83 er stabilize TMK1- and flotillin1-containing nanoclusters at the PM.

84 mic seed (Fe), from a pre-existing amorphous nanocluster (Au) or by coalescence of two separate amorp

85 ining crystal violet (CV) and thiolated gold nanocluster ([Au(25)(Cys)(18)]) activated at a low flux

86 e-sensitive incorporation of a gold-thiolate nanocluster, Au133(SR)52, selectively in the bMOF-102/10

87 atomic site and, accordingly, a new bimetal nanocluster, [Au19Cd2(SR)16](-), is produced.

88 steine to conjugate monolayer protected gold nanoclusters (AuNC).

89 noglobulin E (IgE) in human serum using gold nanoclusters (AuNCs) as fluorescent label was developed.

90 The excellent fluorescence property of Au nanoclusters (AuNCs) has received great attention for va

91 Ultrasmall gold nanoclusters (AuNCs) have emerged as agile probes for in

92 escence (ECL) is detected from dithiolate Au nanoclusters (AuNCs) in aqueous solution under ambient c

93 -shifting of the fluorescence emission of Au nanoclusters (AuNCs) into NIR-II region with improved qu

94 uminescent near-infrared (NIR)-emitting gold nanoclusters (AuNCs) using bovine serum albumin (BSA) as

95 y slow down renal clearance of few-atom gold nanoclusters (AuNCs) with the same surface ligands but d

96 tudy, we generated protein encapsulated gold nanoclusters (AuNCs@ew) with bright photoluminescence by

97 or (LFPB) based on gold-viral biomineralized nanoclusters (AuVCs) as nanozymes that enables the detec

98 ine-linked nanocluster nodes (referred to as nanocluster-based frameworks, NCFs).

99 dynamics, which are critical for developing nanocluster-based photonic devices.

100 Overall, this study proposes a NGO nanoclusters-based nanoprobe for GRPR targeted near-infr

101 gly, we show that the ligand shell of Au(25) nanoclusters becomes more fragile and rigid after ligand

102 +) [dppe = 1,2-bis(diphenylphosphino)ethane] nanoclusters both possess a 13-atom icosahedral core wit

103 to tailor the number of metal atoms in metal nanoclusters, but control of surface ligand number at a

104 single surface thiolate ligand (-SR) on gold nanoclusters can be realized, opening the door to precis

105 In addition, these chiral gold nanoclusters can downregulate TET1 and TET2 mRNA express

106 l, we observed that the effective density of nanoclusters can exceed NPs' primary (bulk) density depe

107 nd that the saturated polymeric forms of the nanoclusters cannot retain molecular hydrogen, in contra

108 paramagnetic iron oxide nanoparticle (SPION) nanoclusters (Ce6-SCs) were prepared via an oil-in-water

109 hedral [Au(13)Ag(12)(PPh(3))(10)Cl(8)]SbF(6) nanoclusters composed of two icosahedral Au(7)Ag(6) unit

110 SCD maps can spatially "paint" the delivered nanocluster concentration, a technique that we named as

111 ing the copy number of proteins within these nanoclusters constitutes a major challenge because of un

112 uction is feasible without detectable silver nanocluster contaminants.

113 We demonstrated that IV injected nanoclusters could be deposited into target brain region

114 tomically precise assembly and size control, nanoclusters could be widely adopted as building blocks

115 dope single atoms of Ag or Cu into hollow Au nanoclusters, creating precise alloy nanoparticles atom-

116 ch was developed for the synthesis of copper nanoclusters (Cu NCs) and used as a fluorescent probe fo

117 uding bovine serum albumin (BSA) template Cu nanoclusters (CuNCs@BSA) and single-walled carbon nanotu

118 predicting the location and concentration of nanoclusters delivered by FUS-BBBD.

119 Additionally, following confirmation of nanocluster delivery, release of the nanocluster payload

120 Cu-modified CeO(2)-supported Pt sub-nanoclusters demonstrate a remarkable performance with a

121 oll-like receptor 7/8 agonist R848 increases nanocluster density and iNKT cell activation.

122 ers (Hb/AuNCs) and aptamer-stabilized silver nanoclusters (DNA/AgNCs) for analysis of Cyt c are prese

123 ably image the changes in endogenous protein nanoclustering dynamics associated with specific conform

124 ed higher mobility with surprisingly similar nanoclustering dynamics to that of Nb80.

125 Quantum-confined Au nanoclusters exhibit molecule-like properties, including

126 This nanocluster exhibits a threefold rotationally symmetrica

127 Specifically, the Au246 nanocluster exhibits multiple excitonic peaks in transie

128 cluster size and organic ligands, stable Au nanocluster films can electronically couple and become s

129 The electrical conductivity of Au nanocluster films can vary by several orders of magnitud

130 ucting transport has not been reported in Au nanocluster films.

131 o varied between sub-regions determined from nanocluster fluorescence intensity.

132 ize to the plasma membrane and be arrayed in nanoclusters for biological activity.

133 igated the use of MRI-visible, albumin-based nanoclusters for noninvasive, localized and temporally s

134 sful application of an aptamer bioconjugated nanoclusters for the detection of apoptosis based on rel

135 carbon nanotube-gold nanoparticle (CNT-AuNP) nanoclusters, for signal amplification.

136 sis reveals that the thiolate ligands on the nanocluster form local tetramers by intracluster interac

137 noclusters through immobilization during the nanocluster formation and also during the active catalyt

138 bout the evolutionary paths of molecular and nanocluster formation and its relation to laser plume hy

139 dynamic development leading to molecular and nanocluster formation remain one of the most important t

140 +) excitatory synapses containing neurexin-1 nanoclusters from 40-50% to ~80%, and doubling the numbe

141 e red emitting glutathione stabilized copper nanoclusters (GSH-CuNCs).

142 The non-metallicity of the Au(130-x) Ag(x) nanocluster has set up a benchmark to study the transiti

143 While the ability to crystallize metal nanoclusters has revealed their geometric structure, the

144 Magic-sized nanoclusters have been implicated as mechanistically rel

145 e assays based on hemoglobin-stabilized gold nanoclusters (Hb/AuNCs) and aptamer-stabilized silver na

146 between two thiolate-protected 28-gold-atom nanoclusters, i.e. Au28(S-c-C6H11)20 (where -c-C6H11 = c

147 naptic dysfunction by promoting aberrant Fyn nanoclustering in spines.

148 h implications for the symmetry of rafts and nanoclusters in cell membranes, which have similar repor

149 fied the copy number of dynein motors within nanoclusters in the cytosol and along the microtubules.

150 e electronic coupling between the individual nanoclusters in the film.

151 s show that the (100) surface breaks up into nanoclusters in the presence of CO2 at 20 Torr and above

152 Release of glutamate from nanoclusters in vivo caused enhanced c-Fos expression, i

153 ng into the [Au23(SR)16](-) (R = cyclohexyl) nanocluster, in which two neighboring surface Au atomic

154 d that antioxidant (glutathione) chiral gold nanoclusters induce a decrease of 5-hydroxymethylcytosin

155 orrelation with nanocluster size and support-nanocluster interactions.

156 The kernel of the nanocluster is a Marks decahedron of Au79, which is the

157 ferent doping modes when the [Au23(SR)16](-) nanocluster is doped with different metals (Cu, Ag), inc

158 eric transformation in an atomically precise nanocluster is reported.

159 As nanoclustering is essential for efficient signaling, we

160 The molecule-like nature of the Au nanoclusters is evidenced by a hopping transport mechani

161 nd surface bonding-induced chirality for the nanoclusters is proposed.

162 containing bacteria, the florescence of gold nanoclusters is recovered.

163 a single crystal containing uranyl peroxide nanoclusters is reported for pyrophosphate-functionalize

164 indicating that the loading capacity of the nanoclusters is sufficient to induce neuronal activation

165 es and properties of atomically precise gold nanoclusters is the object of active research worldwide.

166 For many applications of well-defined gold nanoclusters, it is desirable to understand their struct

167 ated lattice oxygen anchors deposited Pt sub-nanoclusters, leading to a moderate CO adsorption streng

168 The Co metal and oxides remain as nanoclusters (less than 5 nm) thus active in subsequent

169 iposomes (LipoTherm) were prepared with gold nanoclusters (LipoTherm-AuNC) to increase the stability

170 We showed that nanocluster location could be confirmed in vivo with MRI

171 etal-localized HOMO-LUMO transition of these nanoclusters lowers in energy linearly with increasing e

172 ique and diverse features of uranyl peroxide nanoclusters may contribute to the enhanced mobility of

173 d-pulsed laser irradiation and magnetic gold nanoclusters (MGNCs) as the etching agents is described.

174 and suggests that ion channel topography and nanoclustering might be under the control of second mess

175 ver, the observation that TCRs assemble into nanoclusters might allow for homotropic allostery, in wh

176 Multimetallic nanoclusters (MMNCs) offer unique and tailorable surface

177 ive 11-mercaptoundecanoic acid-modified gold nanoclusters (MUA-Au NCs) for tumor-targeted drug delive

178 sis and structure of a giant 102-silver-atom nanocluster (NC) 1 is presented.

179 Herein, we report a 78-nuclei silver nanocluster (NC) [Ag(78) ((i) PrPhS)(30) (dppm)(10) Cl(1

180 -shaped, charge-neutral, diplatinum-doped Ag nanocluster (NC) of [Pt2Ag23Cl7(PPh3)10].

181 ure determination of a large box-shaped Ag67 nanocluster (NC) protected by a mixed shell of thiolate

182 face-mediated interconnection (SMI) of metal nanoclusters (NCs) and nanoparticles (NPs) in fibrous ma

183 tures of ligand-protected Au and other metal nanoclusters (NCs) are successfully obtained, and the or

184 Atom-by-atom manipulation on metal nanoclusters (NCs) has long been desired, as the resulti

185 thetic chemistry of atomically precise metal nanoclusters (NCs) have significantly broadened the acce

186 fetimes in exotic crystalline phases of gold nanoclusters (NCs) in addition to the well-known face-ce

187 stabilization of ligand-free, small platinum nanoclusters (NCs) Pt(12+/-x) is presented.

188 evolution of the optical properties of gold nanoclusters (NCs) versus size is of great importance be

189 Metal nanoclusters (NCs), typically consisting of a few to ten

190 ties derived from the integrated Au25 (SG)18 nanoclusters (NCs).

191 c ligands to attain atomically precise metal nanoclusters (NCs).

192 Such atomically precise NPs (or nanoclusters, NCs) bridge up with conventional NPs by pr

193 ral frameworks composed of bipyridine-linked nanocluster nodes (referred to as nanocluster-based fram

194 Monodisperse ceria nanoclusters now permit investigation of their propertie

195 This study is the first report for Cu nanocluster nucleation on ploy thymine tails of ssDNA wh

196 ture of ultra-stable Au144(SR)60 magic-sized nanoclusters obtained from atomic pair distribution func

197 Formation of larger nanoclusters occurs in the absence of interactions betwe

198 phytohormone auxin-induced, sterol-dependent nanoclustering of cell surface transmembrane receptor ki

199 table under reductive potentials prevent the nanoclustering of nanoparticles.

200 dered nanodomains, which in turn promote the nanoclustering of ROP6 GTPase that acts downstream of TM

201 by promoting cell surface receptor-mediated nanoclustering of signaling components and cytoskeleton-

202 via a processing route that creates distinct nanoclusters of atoms that pin grain boundaries within t

203 of osteopontin is their ability to sequester nanoclusters of calcium phosphate to form a core-shell s

204 Nanoclusters of FcgammaRI, but not FcgammaRII, are const

205 Nanoclusters of Ir were electrochemically deposited on c

206 gammaRII, are constitutively associated with nanoclusters of SIRPalpha, within 62 +/- 5 nm, mediated

207 one as a new tool for customized creation of nanoclusters of zinc peroxide.

208 III-nitride nanowires decorated with Ru sub-nanoclusters offer controlled surface charge properties

209 ydrophobic lignin, and equivalent water-rich nanoclusters on polar cellulose surfaces.

210 ing nanoconjugates showed slight increase in nanoclusters on the cell surface with time.

211 ycling, ruthenium segregates out as metallic nanoclusters on the reconstructed surface.

212 -driven, mutually convertible isomers of the nanoclusters open up an avenue to employ ultra-small nan

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

214 atomically precise, thiolate-protected metal nanoclusters, our understanding of the driving forces fo

215 tion of nanocluster delivery, release of the nanocluster payload into brain tissue can be triggered b

216 The structurally precise Cu-rich hydride nanoclusters [PdCu(14) H(2) (dtc/dtp)(6) (C=CPh)(6) ] (d

217 wed diversity characterised by the number of nanoclusters per synapse.

218 sorption of the well-defined Au(25) (SG)(18) nanocluster, photoacoustic (PA) imaging was used to visu

219 [Au(25)(SCH(2)CH(2)-p-C(6)H(4)-N(3))(18)](-) nanocluster platform with azide moieties appended onto e

220 m the previously reported Au30 S(S-(t) Bu)18 nanocluster protected by 18 tert-butylthiolate ligands a

221 precise Au(130-x) Ag(x) (average x=98) alloy nanoclusters protected by 55 ligands of 4-tert-butylbenz

222 Ag binary architecture in such a large alloy nanocluster provides atomic-level insights into the Au-A

223 re spatially organised into single and multi-nanocluster PSDs.

224 Three bimetallic platinum/silver nanoclusters, PtAg(20)(dtp)(12) (1), Pt(2)Ag(33)(dtp)(17

225 talytic activity of the resulting bimetallic nanocluster, PtAu24(SC6H13)18, for the hydrogen producti

226 Herein, we report ultrasmall platinum nanoclusters (PtNCs) encapsulated in amine-functionalize

227 irect evidence for the formation of THF-rich nanoclusters (R(g) ~ 0.5 nm) on the nonpolar cellulose s

228 Creating structures with superatomic nanoclusters rather than atoms offers the possibility of

229 The presence of Rap1 within the nanoclusters reduces the number of the clustered oncogen

230 Although the structure of individual nanoclusters remained relatively conserved across all su

231 ance of signals favors activation, FcgammaRI nanoclusters reorganize into periodically spaced concent

232 Ultra-small, magic-sized metal nanoclusters represent an important new class of materia

233 The molecule-like bimetallic nanocluster represents a class of catalysts that bridge

234 The H-bonding networks within the nanoclusters resemble the resonance structures of polycy

235 chloride (Cl(-)) template in controlling the nanocluster's nuclearity with atomic precision and the e

236 effect of a single Ag atom difference in the nanocluster's size in controlling the NCF dimensionality

237 Co-ligation of SIRPalpha with CD47 abrogates nanocluster segregation.

238 ber of metal core atoms and thiolates on the nanocluster shell.

239 ations from Au103 and Au102 include (i) both nanoclusters show similar HOMO-LUMO gap energy (i.e., Eg

240 reaction of a single surface ligand on gold nanoclusters shows potential to precisely control the nu

241 ocatalyst and elucidate its correlation with nanocluster size and support-nanocluster interactions.

242 The Ag(90) nanocluster solves the apparent incompatibility with the

243 to-core binding energy that appears to drive nanocluster stabilization.

244 Auxin-induced TMK1 nanoclustering stabilizes flotillin1-associated ordered

245 ates a ligand-based strategy for controlling nanocluster structure and also provides a method for the

246 face motif is observed for the first time in nanocluster structures.

247 ers, particularly 17, were used to stabilize nanoclusters such as Pd/Au for the catalytic asymmetric

248 Nanoclustering suggests that Rap1 suppression is Ras iso

249 on both 3' and 5' ends as a template for Cu-nanocluster supraparticle formation.

250 Multi-nanocluster synapses were frequently found in the CA3 an

251 Synapses generally contain a single nanocluster that comprises more than four neurexin-1 mol

252 xin-1 is assembled into discrete presynaptic nanoclusters that are dynamically regulated via ectodoma

253 ss this need, we have developed iron sulfide nanoclusters that catalyse nitric oxide generation from

254 ise disordered systems composed of plasmonic nanoclusters that either operate as a broadband absorber

255 osphorylated K-Ras reorganizes into distinct nanoclusters that retune the signal output.

256 gions revealed they comprised discrete PSD95 nanoclusters that were spatially organised into single a

257 In these hybrid nanoclusters, the relative stoichiometry, size, shape, a

258 of monodisperse [Cd54Se32(SePh)48(dmf)4](4-) nanoclusters; the second is a unique porous CdSe crystal

259 can have both regarding the size control of nanoclusters through immobilization during the nanoclust

260 as been also focusing on the doping of metal nanoclusters through introduction of noble metals, such

261 HC injecting electron density into the metal nanocluster thus lowering the barrier for bromobenzene a

262 ds to segregation of FcgammaRI and SIRPalpha nanoclusters to be 197 +/- 3 nm apart.

263 t potential of using anisotropic superatomic nanoclusters to create solid-state materials and provide

264 , Ca(2+) membrane territories, and signaling nanoclusters to modulate T cell signaling and function.

265 re of the phenomenon ensures eruption of the nanoclusters towards a much colder region, giving rise t

266 This indicates the sensitivity of the nanocluster transformation pathway to the cluster surfac

267 ally precise anion-templated silver thiolate nanoclusters, two of which form one- and two-dimensional

268 s) represent an important group of metal-oxo nanoclusters, typically comprised of early transition me

269 ransformation products of the Au(22)(SG)(18) nanocluster under representative working conditions and

270 Here, we synthesize a nested Ag(90) nanocluster under solvothermal condition.

271 examines the sorption of the uranyl peroxide nanocluster [UO(2)(O(2))(OH)](60)(60-) (U(60)) to Na-mon

272 u25(SR)18(-) (R = H, CH3, CH2CH3, CH2CH2CH3) nanoclusters upon photoexcitation are discussed using ti

273 tability and decomposition pathways of LiBH4 nanoclusters using grand-canonical free-energy minimizat

274 track the seeded growth of atom-precise gold nanoclusters using mass spectrometry, revealing that the

275 n nanobiosensor based on bivalent aptamer-Cu nanocluster was designed and optimized for specific and

276 ining conformational isomer crystals of gold nanoclusters, we investigate crystallization-induced pho

277 Nanoclusters were crystallized as cubic crystals (</=0.5

278 eveal a host of new structures for water-ice nanoclusters when adsorbed on an atomically flat Cu surf

279 ons in the number/size of emissive graphenic nanoclusters wherein multiscale modelling captures essen

280 nker-DNA hybridization that formed 3D radial nanoclusters, which generated a remarkable electrochemic

281 and) lead to different surface structures on nanoclusters, which in turn give rise to various charact

282 y the treatment with glutathione chiral gold nanoclusters, which may inhibit the activity of TET prot

283 ution, Ca(2+) ions induce the aggregation of nanoclusters, which precipitate on the surface of SWy-2.

284 The generated nanoclusters, which were mainly composed of chicken oval

285 The product of reaction of this nanocluster with 1 equiv of water has also been structur

286 nd crystal structure determination of a gold nanocluster with 103 gold atoms protected by 2 sulfidos

287 We report the X-ray structure of a gold nanocluster with 30 gold atoms protected by 18 1-adamant

288 Herein, a high-nuclearity copper nanocluster with 81 copper atoms, formulated as [Cu(81)(

289 mainly through the side entry.Doping a metal nanocluster with heteroatoms dramatically changes its pr

290 egated to sort subsets of phospholipids into nanoclusters with defined lipid compositions that determ

291 nanoparticles, both plasmonic ones and small nanoclusters with molecule-like properties.

292 Integrating these electrocatalytic nanoclusters with multimaterial fibres allows nitric oxi

293 s expected to open new avenues for designing nanoclusters with novel surface structures using differe

294 solved electronic absorption spectra of gold nanoclusters with precisely mass-selected chemical compo

295 and differences in the emission of these two nanoclusters with similar cores.

296 Atomically precise metal nanoclusters with tailored surface structures are import

297 report a family of atomically precise ceria nanoclusters with ultra-small dimensions up to 1.6 nm (

298 phage surfaces but are organized in discrete nanoclusters, with a mean radius of 71 +/- 11 nm, 60 +/-

299 -poor liquid phases, nucleation of amorphous nanoclusters within the metal-rich liquid phase, followe

300 hydrophobic SPION into stable, water-soluble nanoclusters without the use of any additional amphiphil