コーパス検索結果 (1語後でソート)
通し番号をクリックするとPubMedの該当ページを表示します
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
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
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
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
66 the rich d electron physics not available to nanocomposites based on sp bonded graphene and carbon na
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.
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.
79 , a multifunctional Fe3O4@SiO2@PEI-Au/Ag@PDA nanocomposite catalyst with highly stabilized reactivity
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
84 a graphenated polypyrrole (G-PPy) conductive nanocomposite confirming the adsorption of avidin on gra
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
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
107 H-MoS2 nanosheets, layer by layer process of nanocomposite fabrication, and strain engineering, we de
109 that the strengthening effect of the TiSiCN nanocomposite film can be attributed to the coherent-int
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
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
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
133 re comparable to those of enamel despite the nanocomposites having a smaller hard-phase content.
136 vances in the fabrication and application of nanocomposite hydrogels in tissue engineering applicatio
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
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.
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
162 blends as potential components in dielectric nanocomposite materials for high energy density capacito
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
172 the formation of stimuli responsive hydrogel nanocomposite membranes, and can be easily modified to i
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
178 O-MWCNT and MWCNT/AuNPs, the rGO-MWCNT/AuNPs nanocomposite modified electrode was the most sensitive
180 ophene) (PEDOT)-reduced graphene oxide (rGO) nanocomposite modified fluorine doped tin oxide (FTO).
183 sonance based salivary cortisol sensor using nanocomposite molecular imprinted layer reported first t
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
193 y mode resonance and molecular imprinting of nanocomposites of zinc oxide (ZnO) and polypyrrole (PPY)
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
201 was significantly enhanced by employing the nanocomposite photocatalyst and using prereduction and s
205 ding challenge to produce bulk polymer-metal nanocomposites (PMNCs) with a uniform dispersion of meta
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
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
217 of model polymer (high-density polyethylene) nanocomposites reinforced by nanocarbon fillers consisti
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
226 carbon electrode modified with the imprinted nanocomposite showed a highly selective and ultrasensiti
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
235 of complex three-dimensional gold-containing nanocomposite structures by simultaneous two-photon poly
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
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
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
250 of a novel bimorphological anisotropic bulk nanocomposite using a multistep deformation approach, wh
252 veloped to produce porous conductive polymer nanocomposites using the conventional solution-casting m
262 Glassy carbon electrode coated with this nanocomposite was employed as nanostructured support for
265 rk, a nanoparticle loaded conductive polymer nanocomposite was obtained by a one-step synthesis appro
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
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
279 nofiber/thermoplastic polyurethane (CNF/TPU) nanocomposites were prepared directly by solution castin
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
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
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
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
WebLSDに未収録の専門用語(用法)は "新規対訳" から投稿できます。