ライフサイエンスコーパス: nanocomposite

1 he surface (i.e., nanoribbon-like P3HT/AuNRs nanocomposites).

2 for the development of graphene-gold (G-Au) nanocomposite.

3 ficantly depend on the microstructure of the nanocomposite.

4 O bimetallic nanoparticle and graphene oxide nanocomposite.

5 on and subsequent mechanical response of the nanocomposite.

6 fabrication of the sensor from prepared MIP nanocomposite.

7 bserved to form the Fe3O4@SiO2@PEI-Au/Ag@PDA nanocomposite.

8 SA was used to stabilize OPH activity in the nanocomposite.

9 dant polyvinyl alcohol (PVA-AWP)/Fe-Ni alloy nanocomposite.

10 s to assess the drug mobility within the bio-nanocomposite.

11 effects of the individual components in the nanocomposite.

12 de occurs to produce highly crystalline G-Au nanocomposite.

13 presence of positive charge on the prepared nanocomposite.

14 also leads to improved mechanics of gels and nanocomposites.

15 evices, supercapacitors, and flame retardant nanocomposites.

16 for Pb-doped Bi0.7 Sb1.3 Te3 thermoelectric nanocomposites.

17 ustry also is expected to be a major user of nanocomposites.

18 nical actuation properties of the exfoliated nanocomposites.

19 ment of the mechanical properties of polymer nanocomposites.

20 electric properties as compared to two-phase nanocomposites.

21 hat the spin Seebeck effect persists in bulk nanocomposites.

22 alent metal NPs followed by oxides and other nanocomposites.

23 ght parts from new easy-to-process polymeric nanocomposites.

24 o the dielectric properties of the resulting nanocomposites.

25 biosensors with nanotubes, nanoparticles and nanocomposites.

26 on of space vehicles to self-healing ceramic nanocomposites.

27 gh surface area, especially the carbon based nanocomposites.

28 anges underpin the macroscopic stiffening of nanocomposites.

29 d) can achieve great material homogeneity in nanocomposites.

30 properties of high energy density capacitor nanocomposites.

31 thermoelectric performance of the resulting nanocomposites.

32 fire retardants, and nano-fillers in polymer nanocomposites.

33 ed structure that comprises an IR-responsive nanocomposite actuator layer and a mechanochromic elasto

34 hly oriented semicrystalline polymer fibers; nanocomposite actuators; twisted nanofiber yarns; therma

35 thermal diffusivity (alpha) of the graphene nanocomposite and relates alpha to a dispersion index.

36 ial-over 4.5 times greater than the uncoated nanocomposite and superior to those reported for similar

37 emarkably improving mechanical properties of nanocomposites and optimizing controlled drug release, r

38 ex matrix to form an active printable hybrid nanocomposite, and used as a uniform coating on top of p

39 nterface is used to construct MoS2 /graphene nanocomposites, and various asymmetrically dual-decorate

40 exceptional mechanical properties of polymer nanocomposites are achieved through intimate mixing of t

41 ionally designed sandwich-structured polymer nanocomposites are capable of integrating the complement

42 ous structure and thermal stability of these nanocomposites are characterized by N2 adsorption-desorp

43 ults demonstrate that the flow properties of nanocomposites are complex and can be tuned via changes

44 t the electrical transport behaviours of the nanocomposites are controlled by the magnetic transition

45 cence-quenching properties of graphene-based nanocomposites are exploited in various detection scheme

46 Dielectric polymer nanocomposites are rapidly emerging as novel materials f

47 Gel-nanocomposites are rapidly emerging functional advanced

48 These nanocomposites are sensitive electromechanical sensors w

49 Highly bendable n-type thermoelectric nanocomposites are successfully developed by embedding m

50 Flexible polymer nanocomposites are the best candidates for application i

51 improved using a carbon black/Prussian Blue nanocomposite as a working electrode modifier.

52 tosan-graphene quantum dots (Fe3O4@Chi-GQDs) nanocomposite as an adsorbent for the preconcentration o

53 made to conjugate DNA probe to Fe3O4/TMC/Au nanocomposite as electrochemical label for strip-based g

54 trategy amplified using AuNPs/graphene oxide nanocomposite as quencher.

55 ethod using graphene oxide/magnetic chitosan nanocomposite as supporting material.

56 3O4/N-trimethyl chitosan/gold (Fe3O4/TMC/Au) nanocomposite as tracing tag to label DNA probe and poly

57 of nAg particles by crumpled GO-TiO2 (GOTI) nanocomposites as an approach to (re)generate, and thus

58 using well-established bifunctional Au-Fe3O4 nanocomposites as the separation nanoprobes to efficient

59 La0.7 Sr0.3 MnO3 :CeO2 (LSMO):CeO2 nanocomposites, as a prototype, are demonstrated to form

60 properties, and applications of various gel-nanocomposites assembled from different metal-based nano

61 en we immobilized anti-2,4-D antibody onto a nanocomposite AuNPs-PANABA-MWCNTs employing the carboxyl

62 nced electrochemical performance of ZrO2-RGO nanocomposite based biosensor.

63 the first liquid phase exfoliated WS2-Nafion nanocomposite based electro-mechanical actuators.

64 ed graphene and carbon nanotubes, as well as nanocomposite based on metallic nanoparticles.

65 Gel-nanocomposites based on CNTs and graphenes and their fun

66 the rich d electron physics not available to nanocomposites based on sp bonded graphene and carbon na

67 The existing polymer nanocomposite-based dielectrics with a limited energy de

68 describe the development of a novel graphite nanocomposite-based electrochemical sensor for the multi

69 We demonstrate that when introduced into a nanocomposite bcc Mg is far more ductile, 50% stronger,

70 le and chromatic mechanical response in MoS2-nanocomposites between 405 nm to 808 nm with large stres

71 ilizers) when comparing as-produced and aged nanocomposites, but no significant increase of releases.

72 ate for the synthesis of graphene/zinc oxide nanocomposite by solvothermal growth.

73 nded onto the surface of graphene/zinc oxide nanocomposite by the bio-linker 1-pyrenebutyric acid N-h

74 released materials from coatings and polymer nanocomposites by producing what is called "fragmented p

75 vivo replication of enamel-inspired columnar nanocomposites by sequential growth of zinc oxide nanowi

76 tensile-strained Ge/In0.52Al0.48As (InAlAs) nanocomposites by using spontaneous phase separation.

77 The high performance of rGO@MgO/C nanocomposite can be ascribed to the hierarchical archit

78 The as-prepared bifunctional nanocomposites can be used to simultaneously purify targ

79 , a multifunctional Fe3O4@SiO2@PEI-Au/Ag@PDA nanocomposite catalyst with highly stabilized reactivity

80 The color of the AuNPs-rGO nanocomposite changes from wine red to purple with the a

81 based on 3sigma) of the proposed online HPLC/nanocomposite-coated microfluidic-based PCARD/ICPMS syst

82 s species, As(III) and As(V), we developed a nanocomposite-coated microfluidic-based photocatalyst-as

83 Nanoribbon-shaped nanocomposites composed of conjugated polymer poly(3-hex

84 a graphenated polypyrrole (G-PPy) conductive nanocomposite confirming the adsorption of avidin on gra

85 The nanocomposites consist of randomly-oriented diamond and

86 We applied an enzyme based nanocomposite consisting of polymethylene green as elect

87 bes the development and utilization of a new nanocomposite consisting of titanium dioxide nanofibers

88 tube sponge shape memory polymer (CNTS/SMPs) nanocomposite could be triggered within ~10 seconds by t

89 Gelatin-graphene conductive biopolymer nanocomposites (CPCs) with ultralow percolation threshol

90 films and other high-temperature polymer and nanocomposite dielectrics.

91 The resulting nanocomposites display unusual electromechanical behavio

92 Thus, gel-nanocomposites doped with preformed/in situ synthesized

93 These multimodal nanocomposite drug carriers should be ideal for selectiv

94 that, silver was grown on the surface of the nanocomposite due to the reduction of the dopamine in th

95 hange of a high-specific-capacity nickel-tin nanocomposite during operation as a Li-ion battery anode

96 ronics are presented by exploiting networked nanocomposite elastomers where high quality metal nanowi

97 rsor concentration, which in turn affect the nanocomposites electrical conductivity and their catalyt

98 In this study, we describe a graphite-based nanocomposite electrode (Au-rGO/MWCNT/graphite) that use

99 h-density active Li domains, the as-obtained nanocomposite electrode exhibits low polarization, stabl

100 most recent advances in the area of Ge-based nanocomposite electrode materials and electrolytes for s

101 capacitance and the cyclic stability of the nanocomposite electrode over that of the pure carbonized

102 These nanocomposites exhibit an abnormal decoupling of the ele

103 The as-prepared nanocomposites exhibit high peroxidase-like activity for

104 Synthesized nanocomposites exhibited significant potential for the s

105 The nanocomposite exhibits a record-high energy product (28

106 The optimized rGO@MgO/C nanocomposite exhibits remarkable CO2 capture capacity (

107 H-MoS2 nanosheets, layer by layer process of nanocomposite fabrication, and strain engineering, we de

108 widely recognised as a challenge in polymer nanocomposites fabrication.

109 that the strengthening effect of the TiSiCN nanocomposite film can be attributed to the coherent-int

110 In this work, a novel nanocomposite film consisting of the Au nanoparticles/gr

111 g mechanism and microstructural model of the nanocomposite film due to lack of the convincible experi

112 FTIR) demonstrated that BSA entrapped in the nanocomposite film have been changed in its secondary st

113 en the C/Si content ratio is 2:2, the TiSiCN nanocomposite film is remarkably strengthened with the m

114 ed feature of the interfaces when the TiSiCN nanocomposite film is strengthened, suggesting that the

115 The morphology of the nanocomposite film was characterized by scanning electro

116 ',2''-terthiophene-3' (p-benzoic acid) (TBA) nanocomposite film.

117 The produced nanocomposite films are flexible, mechanically robust an

118 e observed between the control and bioactive nanocomposite films as revealed by SEM and AFM images.

119 of this work was to develop active bio-based nanocomposite films from fish gelatin (FG) and chitosan

120 blue-chitosan-gold nanoparticle (PB-CS-AuNP) nanocomposite films with excellent biocompatibility were

121 n this investigation, the quarternary TiSiCN nanocomposite films with the different C and Si contents

122 ssy carbon electrode (GCE) modified with the nanocomposite for the formation of a sensing layer and i

123 lized graphene quantum dot (AgNPs/thiol-GQD) nanocomposite for the measurement of 2,4,6-Trinitrotolue

124 w pathway for the synthesis of carbon-sulfur nanocomposites for energy storage technologies.

125 l, illustrating the versatility of epitaxial nanocomposites for strain engineering.

126 itu synthesis of metal oxide-polyelectrolyte nanocomposites formed via impregnation of hydrated polye

127 in food contact and secondary leaching from nanocomposite fragments with an increased surface into e

128 es a large degree of long-range ordering for nanocomposite growth that could lead to unique functiona

129 on the structural evolution of the resulting nanocomposites has been investigated in detail.

130 Self-assembled nanocomposites have been extensively investigated due to

131 ergy density, and flexibility of the polymer nanocomposites have been thoroughly investigated.

132 Nanocomposite having 20% of ZnO in PPY is found to give

133 re comparable to those of enamel despite the nanocomposites having a smaller hard-phase content.

134 We have developed a novel moldable nanocomposite hydrogel by combining dopamine-modified po

135 recently investigated for the fabrication of nanocomposite hydrogels for tissue engineering.

136 vances in the fabrication and application of nanocomposite hydrogels in tissue engineering applicatio

137 ytocompatible, and encapsulated cells in the nanocomposite hydrogels show high viability.

138 form mechanically resilient and elastomeric nanocomposite hydrogels.

139 A biocompatible nanocomposite including bovine serum albumin (BSA) templ

140 show that the mechanical properties of these nanocomposites, including hardness, are comparable to th

141 nspired polymer coating onto the Mn-graphene nanocomposite increased ORR performance significantly, w

142 ity and maximum electric displacement of the nanocomposites increased, while the breakdown strength d

143 This G-Au nanocomposite introduces a new electrode material in the

144 In-vitro assays indicate that this bio-nanocomposite is able to interact and cause morphologica

145 n, a sandwich microstructure for PVDF-BaTiO3 nanocomposite is designed, where the upper and lower lay

146 orated multi-walled carbon nanotube (MWCNTs) nanocomposite is fabricated via a two-step process.

147 A self-assembled nanocomposite is prepared from an aqueous mixture of apt

148 The TiO2-G nanocomposite is therefore an effective electrode materi

149 ue photomechanical response in 2H-MoS2 based nanocomposites is a result of the rich d electron physic

150 The catalytic activity of Apt-Au NPs/BiOCl nanocomposites is at least 90-fold higher than that of A

151 The distribution of Au25 (SG)18 in the two nanocomposites is confirmed by electron microscopy, and

152 the dielectric breakdown behavior of polymer nanocomposites is crucial to the design of high-energy-d

153 wed by its conjugation with the Ru-silica@Au nanocomposite labeled secondary antibody to form a sandw

154 or probe fabrication includes dip coating of nanocomposite layer of zinc oxide and molybdenum sulphid

155 he localized current pathways in the organic nanocomposite layers for each IRS.

156 The use of Ru-Si@Au nanocomposites led to a remarkable increase in the ECL i

157 Here, we describe nanocomposites, made by conformally coating twisted elas

158 d intrinsic coercivity (H ci) of a hard/soft nanocomposite magnet using the mass fraction.

159 A novel nanocomposite material consisting of reduced graphene ox

160 otential for realizing devices based on this nanocomposite material.

161 t stiffness and toughness rarely achieved in nanocomposite materials are presented.

162 blends as potential components in dielectric nanocomposite materials for high energy density capacito

163 and organization of nanoparticles in polymer nanocomposite materials.

164 Polymer nanocomposites-materials in which a polymer matrix is bl

165 mply immobilized onto the TiO2-MWCNT/CHIT-SB nanocomposite matrix through simple pi - pi stacking and

166 Such conjugated polymer/plasmonic nanorod nanocomposites may find applications in fields, such as

167 ric and capacitive properties of the polymer nanocomposites may pave a way for widespread application

168 Here we report the fabrication of Cx-BN nanocomposites, measuring up to 10 mm in longest dimensi

169 esis of nAg particles at the surface of GOTI nanocomposite membrane assemblies, allowing for simultan

170 s a foundation for the formation of advanced nanocomposite membranes comprising diverse building bloc

171 The resulting nanocomposite membranes prepared via solvent transfer-in

172 the formation of stimuli responsive hydrogel nanocomposite membranes, and can be easily modified to i

173 ent and tuning of multi-bit storable organic nanocomposite memory device systems.

174 estigate the current fluctuations of organic nanocomposite memory devices with NDR and the IRSs under

175 o be extended to the synthesis of N-OMP/SiO2 nanocomposites, mesoporous SiO2 , crystalline mesoporous

176 For this purpose, a nanocomposite microsphere platform was developed for sel

177 The ssDNA-nanocomposite modified electrode was characterized by cy

178 O-MWCNT and MWCNT/AuNPs, the rGO-MWCNT/AuNPs nanocomposite modified electrode was the most sensitive

179 Thus, using the GO-Al2O3 nanocomposite modified electrode, the cell viability was

180 ophene) (PEDOT)-reduced graphene oxide (rGO) nanocomposite modified fluorine doped tin oxide (FTO).

181 was immobilized on the surface of ZnO/Pt-Pd nanocomposites modified FTO electrode.

182 leic acid density on the graphene/zinc oxide nanocomposite-modified sensing platform.

183 sonance based salivary cortisol sensor using nanocomposite molecular imprinted layer reported first t

184 Nanocomposite molecular material based on cobalt phthalo

185 nanocomposites, nanoflowers, nanotubes and nanofibers we

186 BHCNTs can, therefore, be used to make nanocomposites, nanopaper sheets, and bundles that are s

187 Two nanocomposites (NCs) containing SiO2 nanoparticles (NPs)

188 This paper reports a typical synthesis of a nanocomposite of functionalized graphene quantum dots an

189 m mollusk and fish samples were performed by nanocomposite of magnetic graphene oxide-polyimide, as a

190 Components of polymer preparation and the nanocomposite of polymer with ZnO are optimized for real

191 A series of nanocomposites of cobalt embedded in N-doped nanoporous

192 Then, nanocomposites of conductive fillers such as carbon nano

193 y mode resonance and molecular imprinting of nanocomposites of zinc oxide (ZnO) and polypyrrole (PPY)

194 The TiO2/G nanocomposite offered a favorable microenvironment for d

195 However, the resulting hard/soft nanocomposites often exhibit random crystallographic ori

196 nge ordering through selective nucleation of nanocomposites on termination patterned substrates.

197 lead to unique functionalities and takes the nanocomposites one step closer toward future nanoscale d

198 ld nanoparticles (GNPs) in polypyrrole (PPy) nanocomposite onto the screen printed carbon electrode (

199 olve this issue have mainly focused on using nanocomposites or hybrids by integrating nanosized metal

200 They are sintered into porous, bulk nanocomposites (phi 10 mmxh 10 mm) with low kappa (0.48

201 was significantly enhanced by employing the nanocomposite photocatalyst and using prereduction and s

202 strengthen the conversion efficiency of the nanocomposite photocatalytic reduction.

203 A narrowband red-light nanocomposite photodetector with gain is presented based

204 The nanocomposite played a dual role in this work, as a plat

205 ding challenge to produce bulk polymer-metal nanocomposites (PMNCs) with a uniform dispersion of meta

206 A stretchable porous nanocomposite (PNC) is reported based on a hybrid of a m

207 plexes and clusters, fullerenes, dendrimeric nanocomposites, polymeric materials (organic and/or inor

208 electrode toward paraoxon indicated that the nanocomposite possesses a promising potential to fabrica

209 Herein, graphene quantum dots in nanocomposite practically induced the electrocatalytic a

210 The self-assembled nanocomposite probe comprised of amino acid (histidine)

211 tegy to develop water soluble, biocompatible nanocomposite probe for the detection of pyrophosphate (

212 een constructed based on graphene/zinc oxide nanocomposite produced via a facile and green approach.

213 qualitative and quantitative measurements of nanocomposites properties were accomplished by scanning

214 Using the proposed nanocomposite provides a specific platform with increase

215 Using the proposed nanocomposite provides a specific platform with increase

216 These hybrid nanocomposites, quite superior than their rival material

217 of model polymer (high-density polyethylene) nanocomposites reinforced by nanocarbon fillers consisti

218 Tungsten carbide cobalt (WC-Co) matrix nanocomposites reinforced with varying amounts of ND (2

219 nanofibers (CNF)), denoted as PG-C and CNF-C nanocomposites, respectively, were synthesized using sol

220 distribution of the carbon nanotubes in the nanocomposite results in high electrical conductivity, a

221 The nanocomposites retain the 3D hierarchical porous network

222 The as-prepared nanocomposites retain the high porosity and thermal stab

223 The 3D CNTs-AMB1 nanocomposite scaffold is further demonstrated as a pote

224 The PDI-HIS-Cu-GO (PCG) nanocomposite sensor provides a unique platform for the

225 SiO2@Au nanocomposites served as nanocarriers for co-immobilizat

226 carbon electrode modified with the imprinted nanocomposite showed a highly selective and ultrasensiti

227 MOHC/GO nanocomposites showed enhanced surface area, porosity, a

228 The Fe3O4@SiO2@PEI-Au/Ag@PDA nanocomposite shows a high saturation magnetization (Ms)

229 The as-prepared AuNPs-rGO nanocomposite shows appropriate selectivity towards NO2(

230 synthesis of monodisperse silicon and carbon nanocomposite spheres (MSNSs) is achieved via a simple a

231 concept of the use of monodisperse Si and C nanocomposite spheres toward practical lithium-ion batte

232 al features on the molecular scale, reveal a nanocomposite structure hierarchically assembled to form

233 The TiSiCN film is characterized as the nanocomposite structure with the TiN nanocrystallites su

234 e, as this would allow complete control over nanocomposite structure-property relationships.

235 of complex three-dimensional gold-containing nanocomposite structures by simultaneous two-photon poly

236 Furthermore, conductive nanocomposite structures that immobilize proteins can sy

237 a pure permanent-magnet system to a stronger nanocomposite system at lower costs.

238 A 2D multifunctional nanocomposite system of gold nanorods (AuNRs) was develo

239 The creation of nanocomposite systems based on one-dimensional nanofiber

240 resent a new class of building blocks called nanocomposite tectons (NCTs), which consist of inorganic

241 route to high-temperature dielectric polymer nanocomposites that simultaneously possess high dielectr

242 In the prepared nanocomposite, the CuNCs@BSA found to play as a conducti

243 Despite its widespread use in nanocomposites, the effect of embedding graphene in high

244 Here, we have designed and prepared magnetic nanocomposite thermoelectric materials consisting of BaF

245 e fabrication of a graphene/titanium dioxide nanocomposite (TiO2-G) and its use as an effective elect

246 allowing linear and nonlinear elasticity of nanocomposites to be tuned independently.

247 rials to illustrate the possibility of using nanocomposites to control surface wave propagation throu

248 ion studies were conducted with the prepared nanocomposites to examine their maximum adsorption poten

249 nvestigate the breakdown behavior of polymer nanocomposites under electrostatic stimuli.

250 of a novel bimorphological anisotropic bulk nanocomposite using a multistep deformation approach, wh

251 Growth of epitaxial nanocomposites using lattice-mismatched constituents als

252 veloped to produce porous conductive polymer nanocomposites using the conventional solution-casting m

253 Vertically aligned nanocomposites (VAN) thin films present as an intriguing

254 The AuNPs-rGO nanocomposite was applicable to the sensitive and select

255 The synthesized nanocomposite was applied in preconcentration of Pb(2+)

256 The Fe3O4@SiO2@PEI-Au/Ag@PDA nanocomposite was carefully characterized by the SEM, TE

257 The G-Au nanocomposite was characterised by UV-vis, XRD, FTIR, TE

258 The as-synthesised graphene/zinc oxide nanocomposite was characterised with scanning electron m

259 The nanocomposite was characterized by field emission scanni

260 The nanocomposite was characterized by TEM, XRD, FTIR, XPS,

261 The AuNPs-rGO nanocomposite was confirmed by different physicochemical

262 Glassy carbon electrode coated with this nanocomposite was employed as nanostructured support for

263 The nanocomposite was modified in the presence of glucose an

264 Uniform deposition of the nanocomposite was observed by scanning electron microsco

265 rk, a nanoparticle loaded conductive polymer nanocomposite was obtained by a one-step synthesis appro

266 The nanocomposite was synthesized by electrochemical polymer

267 GO-Al2O3 nanocomposite was synthesized using self-assembly of GO

268 The Fe3O4@SiO2@PEI-Au/Ag@PDA nanocomposite was used to catalyze the reduction of p-ni

269 This G-Au nanocomposite was used to modify glassy carbon electrode

270 uctural and chemical analysis of synthesized nanocomposites was conducted using different characteriz

271 lementary aptamer (AuNPs-S2), the ECL of QDs nanocomposites was efficiently quenched (switch "off" st

272 (bpy)3(2+)doped silica doped AuNPs (Ru-Si@Au nanocomposite) was developed for detection of p53 protei

273 ELP-OPH/BSA/TiO2NFs/c-MWCNTs nanocomposite were systematically characterized using fi

274 The prepared nanocomposites were characterized, and their electrochem

275 silica-nanoparticle-doped liquid-crystalline nanocomposites were found to be able to dynamically self

276 so, the morphology and structure of prepared nanocomposites were investigated by transmission electro

277 ttivity and energy storage of the P(VDF-HFP) nanocomposites were investigated.

278 ns) effecting the adsorption capacity of the nanocomposites were optimized.

279 nofiber/thermoplastic polyurethane (CNF/TPU) nanocomposites were prepared directly by solution castin

280 The prepared nanocomposites were studied as magnetic adsorbents for t

281 The resulting AuNPs/PEDOT:PSS nanocomposites were subsequently characterized under a p

282 dye using solar irradiation, CeO2 doped TiO2 nanocomposites were synthesized hydrothermally at 700 de

283 eous system was developed using a functional nanocomposite which consists of elastin-like-polypeptide

284 by using chiral selective conductive polymer nanocomposite which mimics antibodies and enzymes.

285 heses of next generation multifunctional gel-nanocomposites, which could be achieved by increasing th

286 nosized building blocks" can 1) generate new nanocomposites with antibiofilm properties or 2) be used

287 ree-dimensional carbon/metal oxide (3DC/MOx) nanocomposites with both the composition and structure h

288 present neutron scattering investigations on nanocomposites with dynamically asymmetric interphases f

289 Nowadays, three-phase nanocomposites with either combination of fillers or pol

290 n metals (Ti, V, Cr, Zr, Nb and W) and their nanocomposites with emphasis on basic principles and lit

291 urface area is functionalized to form stable nanocomposites with gold nanoparticles (AuNPs) and elect

292 nique is presented to produce self-assembled nanocomposites with long-range ordering through selectiv

293 experimental efforts on synthesizing polymer nanocomposites with novel microstructures to achieve hig

294 engineer advanced graphene-based functional nanocomposites with rationally designed compositions and

295 he predicted breakdown strengths for polymer nanocomposites with specific microstructures agree with

296 The nanocomposites with the highest aspect ratio BaTiO3 NFs

297 However, the nanocomposites with the lowest aspect ratio BaTiO3 NFs a

298 A particularly suitable approach to produce nanocomposites with unique level of control over their s

299 ame polymer and nanoparticles in the form of nanocomposites with varying surface texture and self-cle

300 when engineering a complex type of material, nanocomposites, with exquisite control over structural a

301 A new nanocomposite (ZnO/Cysteic acid) was deposited on glassy