ライフサイエンスコーパス: nanocomposite

1 which is higher than most metals and polymer nanocomposite.

2 the all-scale hierarchical structures of the nanocomposite.

3 molybdenum disulfide/chitosan (Au@MoS(2)/Ch) nanocomposite.

4 man analysis to confirm the formation of the nanocomposite.

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

6 O bimetallic nanoparticle and graphene oxide nanocomposite.

7 characterize the synthesized NiFe(2)O(4)-rGO nanocomposite.

8 zed on Carbon quantum dots/octahedral Cu(2)O nanocomposite.

9 modified with N-CQD@Co(3)O(4)/MWCNTs hybrid nanocomposite.

10 d Au-nano-Dendroids, and graphene oxide (GO) nanocomposite.

11 es were applied for characterization of MPSP-nanocomposite.

12 oxide NPs and the catalytic behavior of the nanocomposites.

13 tion of iron carbide nanoparticles and their nanocomposites.

14 FE-CFE) to make relaxor-relaxor-type polymer nanocomposites.

15 preparing and forming cellulose nanomaterial nanocomposites.

16 the door to a novel class of single crystal nanocomposites.

17 y for controllable synthesis of metal-carbon nanocomposites.

18 htforward route for the preparation of novel nanocomposites.

19 applications ranging from functional inks to nanocomposites.

20 for the production of a wide range of novel nanocomposites.

21 ividual BaTiO3 NCs as well as BaTiO3/polymer nanocomposites.

22 e breakdown strength of the P(VDF-HFP)-based nanocomposites.

23 heir acidic counterparts in the synthesis of nanocomposites.

24 the reducing agent to fabricate Au-NP@Zn-MOF nanocomposites.

25 aimed at fabricating halide perovskite-based nanocomposites.

26 ic liquid (IBABr) to prepare IBABr-Au@Zn-MOF nanocomposites.

27 versatile and multifunctional peptide-metal nanocomposites.

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

29 alent metal NPs followed by oxides and other nanocomposites.

30 y analogous electrostatically functionalised nanocomposites.

31 ocaloric properties of ferroelectric polymer nanocomposites.

32 e so-called interfacial effect in dielectric nanocomposites.

33 rifluoroethylene-chlorofluoroethylene)-based nanocomposites.

34 in this way, govern catalytic properties of nanocomposites.

35 ng any polymers and NPs which form catalytic nanocomposites.

36 s to much enhanced breakdown strength of the nanocomposites.

37 ization to the rational design of functional nanocomposites.

38 n increase in the surface area of kaolin/ZnO nanocomposites (31.8 m(2)/g) when compared to kaolin (17

39 particles-poly(amidoamine) (PAMAM) dendrimer nanocomposite (3D-Au-PAMAM) covalently immobilized onto

40 , the smaller particles impart the resulting nanocomposite a higher tensile strength, and elastic and

41 etween the structure and behavior of the MOP nanocomposites, a MOP-composited thermoplastic elastomer

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

43 In polyaniline chitosan silver nanocomposite adsorbed beta-galactosidase, a multi-fold

44 e characterized a customized magnetic silver nanocomposite (Ag-MNP) and evaluated its effects on bact

45 reparation, stability and simplicity of this nanocomposite allow the generation of electrochemical bi

46 FT-IR confirmed the formation of the Fc-GO nanocomposite and PEI deposition on the electrode surfac

47 the surface of MOF effectively stabilize the nanocomposite and serve as radiosensitizers, whereas the

48 nique view of the field of catalytic polymer nanocomposites and allows understanding of where the fie

49 ies for the heterogeneity of polymers in the nanocomposites and the confinement effect the MOPs impos

50 ynthetic strategies for novel BaTiO3/polymer nanocomposites and their structure-composition-performan

51 regarding pros and cons of graphene related nanocomposites and to find ways in order to improve the

52 ese fields, facilitate the design of ordered nanocomposites, and offer clear pathways to device integ

53 The ECEs of the nanocomposites are directly measured and these relaxor n

54 al oxide nanoparticles, and various types of nanocomposites are examples of smart nanomaterials that

55 The desalination performances of our polymer nanocomposites are harnessed here in this work to produc

56 ward integrated wearables, nanomaterials and nanocomposites are in the spotlight of the search for no

57 The resultant nanocomposites are luminescent and exhibit a bright, sub

58 Nanozymes with metallic nanocomposites are promising catalysts for biosensing ap

59 in the biomedical applications of PANI-based nanocomposites are reviewed to provide a background for

60 n, a series of Li(2) S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduc

61 Herein, the novel application of FeS(2)/C nanocomposite as a highly active, stable, and recyclable

62 by far the highest value achieved in polymer nanocomposites at a moderate electric field.

63 pendent electrical conduction of the polymer nanocomposites at elevated temperatures is investigated.

64 es conducted on definitive nanomaterials and nanocomposites at multiple dimension with distinctive ph

65 n, and high performance of the TBPCExBox*PSS nanocomposites augur well for the future development of

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

67 tudy reports a comprehensive assessment of a nanocomposite based on the functionalised graphene oxide

68 rical conductivity of nanomaterials, polymer nanocomposite based strain sensors are successfully deve

69 challenges are discussed for future polymer nanocomposite based wearable strain sensor and their pot

70 review focuses on recent advances in polymer nanocomposite based wearable strain sensors.

71 E-DNA) sensor based on polypyrrole/Fe(3)O(4) nanocomposite bearing redox naphthoquinone tag on PAMAM

72 ary structure of polyaniline chitosan silver nanocomposite bound beta-galactosidase on addition of me

73 activity of native and polyaniline chitosan nanocomposites bound Aspergillus oryzae beta-galactosida

74 he unusual experimental results for BLFO-KBr nanocomposites, but only those among them, which are hig

75 the polymer matrix in ferroelectric polymer nanocomposites by combining atomic force microscopy-infr

76 s, it is demonstrated that the peptide-AuNPs nanocomposite can act as a reusable catalytic coating or

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

78 Thiol-lignocellulose sodium bentonite (TLSB) nanocomposites can effectively remove heavy metals from

79 The nanocomposites characterized by X-ray diffraction (XRD),

80 ttles (AuNRTs)- reduced graphene oxide (rGO) nanocomposite coated on to the gold nanoparticles (AuNPs

81 es have led to the design of iron oxide core nanocomposites, coated with elemental silver to allow th

82 ly(3,4-ethylenedioxythiophene) (PEDOT)-based nanocomposite coating that exhibits excellent DA sensing

83 The synergistic effect of the nanocomposite components was studied by diffuse reflecta

84 Due to the synergic effect of the nanocomposite components, an outstanding photocurrent re

85 ties that impacts the characteristics of the nanocomposites composed thereof is largely unknown.

86 Herein, a multifunctional bio-nanocomposite comprised largely of egg-derived polymers

87 ion on glassy carbon electrode modified by a nanocomposite consisting of gold nanoparticles (AuNP) sy

88 Nanocomposites consisting of a polymer matrix and metall

89 Here, the solution-processable polymer nanocomposites consisting of readily prepared Al(2) O(3)

90 Furthermore, gel nanocomposites containing platelets showed an enhanced r

91 Also, graphene-based nanocomposites could amplify the signal generated by pla

92 tal-organic framework-reduced graphene oxide nanocomposite (Cu-MOF-RGO).

93 sence of MUC1, the peak current of Cu in the nanocomposite decreased, which could be explained based

94 The laser printed nanocomposite delivers a yield strength of up to 1000 MP

95 This crystal-glass high-entropy nanocomposite design concept provides a new approach to

96 s commonly known as "the valley of death" in nanocomposite design.

97 Complex multiphase nanocomposite designs present enormous opportunities for

98 Nanocomposites (diameters lower to 15 mum) composed of m

99 ights to the breakdown mechanisms of polymer nanocomposite dielectrics and establishes a powerful the

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

101 under extreme heat stress, and control over nanocomposite dimensions is maintained on solid substrat

102 parameters were determined based on the TLSB nanocomposite dosage, concentration of zinc subgroup ion

103 In this work, we have developed an MWCNT-rGO nanocomposite electrode for the sensitive detection of A

104 The resulting P3MT/HACNT nanocomposite electrodes exhibit high areal capacitance

105 ricated by immobilizing glutamate oxidase on nanocomposite electrodes made of platinum nanoparticles,

106 used for a range of applications, including nanocomposites, electronic devices, and all-liquid micro

107 tocatalytic activity of Nd(0.3)Sr(0.7)MnO(3) nanocomposite emerges from large surface area, structura

108 gineering and applications of graphene-based nanocomposites enhanced sensors for detecting minute and

109 the structural characteristics of RGO/SnO(2) nanocomposite enhances the sensing property.

110 ites are directly measured and these relaxor nanocomposites exhibit, so far, the highest EC temperatu

111 The kaolin/ZnO nanocomposites exhibited better adsorption performance t

112 The ZnO/clay nanocomposites exhibited excellent recyclable and re-use

113 The optimized ZnPc/BVNS nanocomposite exhibits a ca. 16-fold enhancement in the

114 of applications, including advanced polymer nanocomposite fabrication, drug delivery, imaging, and l

115 he successful production of endless hematite nanocomposite fibers which highlights this technology's

116 A commercially available, 3D printer nanocomposite filament of carbon nanotubes (CNTs) and ac

117 tions are performed for the P(VDF-HFP)-based nanocomposites filled with nanoparticles of different pr

118 an ultralow electric field of 75 MV m(-1) in nanocomposites filled with the orthotropic composite nan

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

120 exible and completely water insoluble pectin nanocomposite film in comparison to the other polymers c

121 For this reason, a chitosan-graphene oxide nanocomposite film was prepared and implemented as the e

122 To achieve a low methoxy-pectin nanocomposite film with maximum resistance to water and

123 that MNAs are easily made from solvent-cast nanocomposite films by micromolding.

124 er-based process to obtain highly reinforced nanocomposite films by simple mixing of two liquid cryst

125 Here, using 3D straining in nanocomposite films of (SmMnO(3))(0.5)((Bi,Sm)(2)O(3))(0

126 ecular weight polyethylene (UHMWPE)/graphene nanocomposite films with a high thermal conductivity are

127 These polymers produce nanocomposite films with excellent NP dispersion, optica

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

129 of single-crystal block copolymer-preceramic nanocomposite films, the structures are converted into m

130 -dimensional lithium metal/lithium tin alloy nanocomposite foil realized by a simple calendering and

131 aphene oxide/tin dioxide (RGO/SnO(2)) binary nanocomposite for acetone sensing performance was succes

132 abrication of highly conductive Au@MoS(2)/Ch nanocomposite for sensitive electrochemical detection of

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

134 tive bone, compromising application of these nanocomposites for in situ bone regeneration.

135 alytic performance of the Nd(1-x)Sr(x)MnO(3) nanocomposites for photodegradation of Acridine orange d

136 fabrication of robust multifunctional MXene nanocomposites for printed and lightweight structural de

137 comparative studies of kaolin and kaolin/ZnO nanocomposites for the adsorption of Cr(VI), Fe(III), CO

138 properties and practicality of LM-elastomer nanocomposites for use in soft machines and electronics

139 ineered magnetic graphene oxide (MGO) in the nanocomposite form of iron oxide nanoparticles (IO)-grap

140 simultaneously, generating necklace-like bio-nanocomposites (GOx@PAVE-CNTs) with GOx-loading polymeri

141 a facile solvothermal procedure, a CdS/WO(x) nanocomposite has been synthesised which exhibits photoc

142 c organic frameworks (BMOF)s based on carbon nanocomposites have been designed with a compositionally

143 hollow microsphere (PNHM)/Fe(3)O(4) magnetic nanocomposites have been synthesized by a novel strategy

144 examples of the MPNPs incorporated polymeric nanocomposites have been unstudied from this perspective

145 Nanocomposites have been utilized in many applications i

146 However, such nanocomposites have remained elusive because of incompat

147 The anion-insertion anode is a nanocomposite having ferrocene encapsulated inside a mic

148 zed cardiac extracellular matrix (ECM)-based nanocomposite hydrogel is developed to provide superior

149 itical consideration in the determination of nanocomposite hydrogel properties.

150 Polyzwitterion-clay nanocomposite hydrogels as a soft, stretchable, and tran

151 Plasmonic nanocomposite hydrogels containing gold nanoparticles an

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

153 as an ionic liquid (IL) and NiFe(2)O(4)-rGO nanocomposite (IL/NiFe2O4/rGO/CPE), a sensitive and effe

154 The as-synthesized MWCNT-Inulin-TiO(2) bio-nanocomposite immobilized with glucose oxidase (GOx) was

155 ed growth, a highly ordered Au-BaTiO(3) -ZnO nanocomposite in a unique "nanoman"-like form, i.e., sel

156 uctivity of stable Ag-decorated 2-D graphene nanocomposite in ethylene glycol based nanofluid by lase

157 ncreased risk associated with the use of CNT nanocomposites in 3D printing.

158 es and applications of conductive PANI-based nanocomposites in the biomedical fields, such as antimic

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

160 ocus in on the industrial applications of GR nanocomposite, including super capacitors, biosensors, s

161 anoparticles (PdNPs), and Polyaniline (PANI) nanocomposite-interface was fabricated on the screen-pri

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

163 uch a self-assembled and ordered three-phase nanocomposite is obtained through a combination of vapor

164 The outstanding performance of this organic nanocomposite is the result of favorable percolation net

165 hydroxides (LDHs) for preparation of porous nanocomposites is a favorable strategy to design potenti

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

167 The multiscale character of nanocomposites is crucial: nanocrystals (5-50 nm) offer

168 Here, a class of liquid metal (LM)-elastomer nanocomposites is presented with elastic and dielectric

169 n profit scalable production of this kind of nanocomposite materials for different applications in a

170 nanoparticles provide an attractive class of nanocomposite materials.

171 aightforward and efficient route to make new nanocomposite materials.

172 nting lies the promise of revolutionary new "nanocomposite" materials.

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

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

175 The resulting nanocomposite membranes prepared via solvent transfer-in

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

177 lemental powders has led to the formation of nanocomposite microstructures composed of a nickel-rich

178 ient electrochemical biosensors based on CNT nanocomposite MNAs.

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

180 e PNPs induce dispersed or weakly aggregated nanocomposite morphologies, depending on the extent of z

181 ic phosphonated-functionalized sporopollenin nanocomposite (MPSP-nanocomposite) was synthetized and u

182 posed by the two ferroics, and heterogeneous nanocomposite multiferroics demand ingredients' structur

183 led carbon nanotubes molybdenum disulfide 3D nanocomposite (MWCNT-MoS(2) NC) was successfully synthes

184 mensional nanostructures in its discrete and nanocomposites nanotopography on sensing lung cancer bio

185 n conducted using the (ZnO NRs)(1-x)(CNs)(x) nanocomposites (NCs) having appropriate structural and e

186 applications, and recent developments about nanocomposites obtained from biorenewable sources.

187 report the thermoelectric properties of SnTe nanocomposites obtained from the consolidation of surfac

188 Especially, nanocomposites (obtained by using biorenewable sources)

189 To do this, a ternary nanocomposite of hemin, graphene oxide and multi-walled

190 posed; it is based on the formulation of the nanocomposite of multiwalled carbon nanotubes (MWCNTs) a

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

192 The utilization of AuNP/GO nanocomposite offers large surface area, exceptional aff

193 collected and mixed with GO to form AuNP/GO nanocomposite on an electrode for the following electroc

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

195 rode (SPCE) was modified by phosphorene-gold nanocomposite onto which an aptamer specific to OA was i

196 Nd(1-x)Sr(x)MnO(3) nanocomposites perovskites were synthesized using sol ge

197 sulted in the discovery of a novel epitaxial nanocomposite phase-change memory material.

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

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

200 ion and demonstrate their incorporation into nanocomposite polymer films that can be used as active c

201 Metal-carbon nanocomposites possess attractive physical-chemical prop

202 r-free individual BaTiO3 NCs, BaTiO3/polymer nanocomposites possess several advantages.

203 These SnTe-CdSe nanocomposites possess thermoelectric figures of merit o

204 d to date, nanomaterials and multifunctional nanocomposites possessing certain structural and physico

205 eposited layer-by-layer via laser melting of nanocomposite powders, which enhance the laser absorptio

206 t here a robust, versatile polymeric-protein nanocomposite (PPNC) platform capable of efficient (>=90

207 inase enzyme on spin-coated films of ZnO-rGO nanocomposite prepared via self-assembly approach.

208 These nanocomposites prevent non-specific interactions while e

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

210 Our bio-inspired nanocomposites provide a general framework for the devel

211 Nanoparticle (NP)/polymer nanocomposites received considerable attention because o

212 nematic phase, we obtain robust, structural nanocomposites reinforced with graphene oxide.

213 e electrode surface with an MWCNT-rGO hybrid nanocomposite resulted in a 10-fold increase in current

214 cterization of the thus-formed peptide-AuNPs nanocomposite reveals enhanced thermal stability, electr

215 The nanocomposite/sensor probe was characterized using UV-Vi

216 l and structural analysis of the synthesized nanocomposites show their core-shell nature with average

217 Besides, the nanocomposite showed good applicability for analysis of

218 n, phosphorus can be recovered from the iron nanocomposite sorbent.

219 These nanocomposite sorbents exhibit rapid sorption with satur

220 4.4 mg As(III) g(-1) for the iron and copper nanocomposite sorbents respectively, which is up to four

221 Among graphene materials, graphene-based nanocomposites stands out owing to its significant prope

222 date, both biomolecule-clay and polymer-clay nanocomposite strategies have utilised the negatively ch

223 Here we present a novel nanocomposite synthesis method based on the direct growt

224 The nanocomposite synthesized with desolvation method was st

225 c oxide-reduced graphene oxide (Tyr/ZnO-rGO) nanocomposite system as a biosensing test-bed for rapid

226 Experiments on the Al+CuO nanocomposite system reveal a reaction front thickness o

227 approach to engineer the ordering of complex nanocomposite systems with unprecedented control over el

228 Nanocomposite tectons (NCTs) are a recently developed bu

229 Thin-film nanocomposite (TFN) membranes have been widely studied o

230 ysis of MUV-3 results in a N-doped graphitic nanocomposite that exhibits extraordinary performance fo

231 ing it possible to design magnetic/plasmonic nanocomposites that allow the dynamic tuning of the plas

232 alent attachment of the hybrid POM forms new nanocomposites that are stable at temperatures and pH va

233 the state-of-the-art dielectric polymers and nanocomposites that are typically prepared via tedious,

234 This coating by growth process produces nanocomposites that do not emit particles and has the ca

235 able progress achieved in vertically aligned nanocomposite thin films from a perspective of tuning fu

236 Vertically aligned nanocomposite thin films with ordered two phases, grown

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

238 zinc oxide-poly(dimethylsiloxane) (ZnO-PDMS) nanocomposite to detect the local release of VSCs is rep

239 ed with graphene/titanium dioxide (G/TiO(2)) nanocomposite to improve the electrode in terms electroc

240 r-matrix interfaces of electroactive polymer nanocomposites to boost their collective properties.

241 harnessed by liquid crystal elastomer (LCE) nanocomposites to drive actuation.

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

243 s into the contribution of nanomaterials and nanocomposites to wearable technology with a focus on we

244 However, synthesis of these nanocomposites typically employs toxic solvents and haza

245 Inorganic-organic nanocomposites, typically as an inorganic core with surf

246 Growth of epitaxial nanocomposites using lattice-mismatched constituents als

247 ging nano-objects in complex systems such as nanocomposites using time-of-flight secondary ion mass s

248 catalytic efficiency of Nd(0.3)Sr(0.7)MnO(3) nanocomposite was 95% of the initial AO dye concentratio

249 Nanocomposite was activated using glutaraldehyde chemist

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

251 The nanocomposite was applied for stir bar sorptive extracti

252 rostructural characterization of synthesized nanocomposite was carried out using different spectrosco

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

254 The nanocomposite was characterized by various tools and sig

255 Attachment of Lsbgal onto nanocomposite was confirmed by AFM, FE-SEM, FTIR, and CL

256 printed SPR nanosensor based on Ag@AuNPs-HBN nanocomposite was developed in the presence of poly(2-hy

257 Cr(VI) removal performance by the nanocomposite was evaluated for two realistic drinking w

258 atalytic performance of the resulting PDA-Pt nanocomposite was evaluated using an electrochemical wor

259 Cu-MOF-graphene oxide (Cu-MOF-GO) nanocomposite was prepared and cast on the electrode sur

260 trong interaction between tyrosinase and the nanocomposite was revealed by the high value of the Mich

261 The results showed that band gap of TC-GQD nanocomposite was shifted to visible lights relative to

262 The TLSB nanocomposite was subsequently investigated to validate

263 A hydrophilic nanocomposite was synthesized by an easy route to improv

264 titania-ceria-graphene quantum dot (TC-GQD) nanocomposite was synthesized by hydrothermal method for

265 The g-C(3)N(4)/GNF nanocomposite was synthesized by the hydrothermal treatm

266 The MIP/Au/GO nanocomposite was synthesized through non-covalent impri

267 A carbon black/Prussian blue nanocomposite was used as a bulk-modifier of the conduct

268 tionalized sporopollenin nanocomposite (MPSP-nanocomposite) was synthetized and used for stir bar sor

269 Characterizations of the nanocomposite were performed by various techniques, incl

270 The prepared nanocomposites were characterized, and their electrochem

271 Then the GOx@PAVE-CNTs bio-nanocomposites were electro-deposited onto electrode sur

272 The Energy gap of the Nd(1-x)Sr(x)MnO(3) nanocomposites were estimated for all concentrations to

273 and (photo) electrochemical responses of the nanocomposites were investigated and tested for the degr

274 ZnO nanoparticles and kaolin/ZnO nanocomposites were prepared by sol-gel followed by wet-

275 BP-Au nanocomposites were synthesized by an in-situ, one-step

276 (3,4- ethylenedioxythiophene) (PEDOT)- AuNPs nanocomposites were synthesized respectively.

277 Herein, Cu/C, Ni/C and Co/C nanocomposites were synthesized using a two-step method

278 and physical characterization, prepared new nanocomposites were used to design a new electrochemical

279 ssue, by definition, is an organic-inorganic nanocomposite, where metabolically active cells are embe

280 to a change in direction in the field of gel nanocomposites, where nanoparticle shape plays an import

281 s may impart catalytic properties to polymer nanocomposites, while polymers with a different structur

282 rohibited solvent exchange properties of the nanocomposites, whilst those polymer chain states are tu

283 The nanocomposite with a mass ratio of (1:10) shows the high

284 e material are controlled, realizing a novel nanocomposite with near theoretical yield strength (G/24

285 ons for the NCDs detection based on graphene nanocomposite with other 2D nanomaterials are outlined.

286 Nanocomposites with different ratios of titanium dioxide

287 y be added into glasses and ceramics to form nanocomposites with enhanced properties, it is extremely

288 loped based on facile one-step assembled bio-nanocomposites with enzymes-loaded polymeric nanoparticl

289 phene oxide is expected to yield low-density nanocomposites with exceptional mechanical properties.

290 their special interactions with MXene enable nanocomposites with high mechanical strength without sac

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

292 In the second part, nanocomposites with many graphene, inorganic and polymer

293 ways in order to improve the performance of nanocomposites with new designs.

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

295 mechanically robust MXene (Ti(3) C(2) T(x) ) nanocomposites with one-dimensional (1D) cellulose nanof

296 ocrystals, which are first self-assembled in nanocomposites with programmable microscopic shapes.

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

298 Monodispersed hairy nanocomposites with typical 2 nm (isophthalic acid)(24)

299 vercome by the preparation of its blends and nanocomposites with various (bio)polymers and nanomateri

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