ライフサイエンスコーパス: graphene oxide

1 he chemical and electrochemical reduction of graphene oxide.

2 y been documented in two-dimensional reduced graphene oxide.

3 tubes, boron nitride nanotubes, graphene and graphene oxide.

4 structures with carbon nanotubes and reduced graphene oxides.

5 an aflatoxin B1 (AFB1) level using a reduced graphene oxide aerogel labeled with a single strand DNA

6 ed, silver nanoparticle-decorated carboxylic graphene oxide (Ag@fGO-T3) as a carrier and anti-T3 anti

7 materials fundamentally differ from 2D flat graphene oxide analogues in that they are highly aggrega

8 xed solution containing a precursor salt and graphene oxide and a subsequent heat treatment.

9 ctivation of a mixture of polyaniline-coated graphene oxide and ammonium hexafluorophosphate (AHF).

10 y imaging method to detect carbon nanotubes, graphene oxide and carbon nanodots in mice.

11 en developed using nanomaterials; Exfoliated Graphene Oxide and Gold Nano-Urchins for modification of

12 as synthesized by a single-step reduction of graphene oxide and HAuCl4 solution.

13 biosensor based on electrochemically reduced graphene oxide and iridium oxide nanoparticles for the d

14 pling reagents, in electrochemically reduced graphene oxide and iridium oxide nanoparticles matrix.

15 V) were employed to characterize synthesized graphene oxide and modified electrode surfaces.

16 ructures such as carbon nanotubes, graphene, graphene oxide and nanodiamonds.

17 ed on chemically derived graphene, including graphene oxide and reduced graphene oxide, properly func

18 erature, are separated by defects in reduced graphene oxide and self-assemble into nanoparticles on c

19 In this study, nanocomposite of graphene oxide and silane modified magnetic nanoparticle

20 f graphite, the electrochemical reduction of graphene oxide and the electrochemical delamination of C

21 rge number of electroactive sites in reduced graphene oxide and the high conductivity nature of graph

22 itic materials, such as graphene and reduced graphene oxide, and a reliable analyte recognition.

23 materials (CNMs) including carbon nanotubes, graphene oxide, and carbon black provide a range of surf

24 Oxide platelets, with analogous structure to Graphene Oxide, and therefore we term them as "White Gra

25 Multigenerational graphene oxide architectures can be programmed by specif

26 Microsized particles in reduced graphene oxide are Joule heated to high temperature ( ap

27 These studies establish graphene oxide as a two-dimensional building block with

28 The electrode surface was fabricated with graphene oxide assimilated with gold nanoparticles decor

29 imension and thickness) nanodimensional gold-graphene oxide (Au@GO) flakes under visible light and th

30 Crumpled 3D graphene oxide based materials fundamentally differ from

31 s is the first demonstration of 3D, crumpled graphene oxide based nanocomposite structures applied sp

32 of polyethylenimine and urease onto reduced-graphene-oxide based field-effect transistors (rGO FETs)

33 We have developed a reduced graphene oxide-based field-effect transistor method for

34 As a proof-of-concept demonstration, reduced graphene oxide-based gas sensors, which were flexible, u

35 ally large-scale applications of the reduced graphene oxide-based nanoparticle-containing composite h

36 New reduced graphene oxide-based silver nanoparticle-containing comp

37 ium-ion batteries are fabricated by printing graphene-oxide-based composite inks and solid-state gel

38 is much more difficult than from graphene or graphene oxides because of the poor dispersibility of h-

39 ion produced high rate of graphite oxide and graphene oxide (BEGO) sheets, CO2, and current at lower

40 e events are fabricated from patterned metal-graphene oxide biopaper.

41 rticle gets sandwiched between two layers of graphene oxide by chemical synthesis route.

42 decorated with nano-Pd, the Pd-coated porous graphene oxide can be used as a bifunctional catalyst fo

43 Porous graphene oxide can be used as a metal-free catalyst in t

44 hat the stimuli-responsive nature of reduced graphene oxide can lead to the formation of crumpled nan

45 (bamyl) from peanut (Arachis hypogaea) onto Graphene oxide-carbon nanotube composite (GO-CNT), Graph

46 functionalized with a water-soluble reduced graphene oxide-carboxymethylcellulose (rGO-CMC) hybrid n

47 s, inexpensive, and environmentally friendly graphene oxide catalytic system for the C-H bond arylati

48 Results show that the reduced graphene oxide-chitosan (rGO-Chit) film as a suitable el

49 modification of glassy carbon electrode with graphene oxide/chitosan film and covalently attached of

50 and energy dispersive spectroscopy show that graphene oxide-coated nanocellulose was partially reduce

51 Such graphene oxide coatings can be deposited by scalable sol

52 report the usage of six luminescent nanodot-graphene oxide complexes as novel fluorescent nanoprobes

53 characterized towards catechol, in terms of graphene oxide concentration, number of cycles to reduce

54 ed amorphous cobalt hydroxide/oxide-modified graphene oxide (CoOxH-GO) possessing peroxidase-like cat

55 pared by one pot synthesis from a mixture of graphene oxide, copper nitrate and uric acid, followed b

56 t strong mechanical stability inherited from graphene oxide, displaying minimal structural changes du

57 ds-DNA/poly(L-cysteine)/Fe3O4 nanoparticles-graphene oxide (ds-DNA/p(L-Cys)/Fe3O4 NPs-GO/CPE) for se

58 ia the formation of Li2O2, we used a reduced graphene oxide electrode, the additive LiI, and the solv

59 h that of a bare printed graphene or reduced graphene oxide electrode.

60 ensors coated with electrochemically reduced graphene oxide (ERGO) and a second set of antibodies sel

61 IL) immobilized on electrochemically reduced graphene oxide (ERGO) for the detection of glucose via a

62 was immobilized on electrochemically reduced graphene oxide (ERGO) through the pi-pi stacking of hydr

63 od by spray coating an aqueous dispersion of graphene oxide/few-layered graphene/deoxycholate.

64 Using a graphene oxide film means the fiducial markers are not i

65 and the current response was monitored using graphene oxide film modified electrode as transducer.

66 Reduced graphene oxide film with adsorbed phenothiazone was used

67 zation of aluminium nanoparticles in reduced graphene oxide film, which we demonstrate to have excell

68 ne films are facilely fabricated by reducing graphene oxide films on recyclable Cu foils in H2-contai

69 5)) in diameter were deposited onto separate graphene oxide films overlaying holes on amorphous carbo

70 nd that the perpendicular Young's modulus of graphene oxide films reaches a maximum when one complete

71 The use of size-selected clusters on a graphene oxide films represents a significant technical

72 r elasticity of few-layer-thick graphene and graphene oxide films.

73 The porous networks made of large reduced graphene oxide flakes (>20 mum) are superelastic and exh

74 tent is prepared by annealing a freeze-dried graphene oxide foam in ammonia.

75 avidin modified-gold nanoparticles/thiolated graphene oxide, followed by its conjugation with the Ru-

76 The gallery spaces in multilayer graphene oxide, for example, can intercalate hydrated me

77 of highly conductive, well-dispersed reduced graphene oxide further stabilizes and improves its perfo

78 ctor probe in immunoassay format on graphene-graphene oxide (G-GO) modified screen printed carbon ele

79 Fluorescent quenching graphene oxide (GO) and Cy5-labeled G8 aptamer were used

80 igher labeling efficiency in comparison with graphene oxide (GO) and exhibited excellent radiostabili

81 emoval efficiency of nanohybrids composed of graphene oxide (GO) and Fe3O4 nanoparticles with various

82 In this work, we have synthesized flat graphene oxide (GO) and five physically crumpled GOs (CG

83 ell mass cytometry to dissect the effects of graphene oxide (GO) and GO functionalized with amino gro

84 dized carbon, and its two major derivatives, graphene oxide (GO) and reduced graphene oxide (rGO) hav

85 ed perylenediimide (PDI-HIS), copper ion and graphene oxide (GO) and that could be utilized as a high

86 The aggregation and stability of graphene oxide (GO) and three successively reduced GO (r

87 rapid and facile detection of thrombin using graphene oxide (GO) and thrombin binding aptamer (TBA).

88 dite (FAM-ssDNA), ethidium bromide (EB), and graphene oxide (GO) are employed in the sensing system.

89 the colloidal mixture of waste Si sludge and graphene oxide (GO) at the same time by ultrasonic atomi

90 Graphene Oxide (GO) based low cost flexible electronics

91 Given the fact that graphene oxide (GO) can act as an electron acceptor, we

92 Graphene oxide (GO) can be considered as one of the most

93 monstrate that the discotic nematic phase of graphene oxide (GO) can be shear aligned to form highly

94 FBG) coated with an anti-CRP antibody (aCRP)-graphene oxide (GO) complex.

95 lirubin oxidase (BOD)-based biocathode using graphene oxide (GO) could be prepared in 2 steps.

96 The graphene oxide (GO) doped conducting polymer poly (3,4-e

97 Graphene oxide (GO) flakes of different sizes were prepa

98 In this study, we evaluated the use of graphene oxide (GO) for biofouling mitigation in FO.

99 zymes, was immobilized in its active form on graphene oxide (GO) for enhanced electrochemical respons

100 7,7,8,8-tetracyanoquinodimethane (TCNQ) and graphene oxide (GO) for low-potential amperometric detec

101 Recently, graphene oxide (GO) has been suggested as an adsorbent;

102 Graphene oxide (GO) has great potential for actinide rem

103 Membranes made of stacked layers of graphene oxide (GO) hold the tantalizing promise of revo

104 tion of MOHCs containing nanoMIL-101(Cr) and graphene oxide (GO) in an effort to improve the thermo-p

105 is study is investigating the performance of graphene oxide (GO) in the protective effect of olive oi

106 he aerogel is prepared through incorporating graphene oxide (GO) into alginate (ALG) matrix by using

107 Graphene oxide (GO) is a graphene derivative that emits

108 The structure of graphene oxide (GO) is a matter of discussion.

109 Graphene oxide (GO) is a novel material that has attract

110 Graphene oxide (GO) is an emerging material for energy a

111 Graphene oxide (GO) is hydrophilic and swells significan

112 Graphene oxide (GO) is promising in scalable production

113 In this work, graphene oxide (GO) is reduced by patterned metal interd

114 Graphene oxide (GO) materials have demonstrated consider

115 Graphene oxide (GO) membranes continue to attract intens

116 One emerging example consists of graphene oxide (GO) membranes for separation processes.

117 Graphene oxide (GO) membranes have demonstrated great po

118 quantum dots (Qdots) aptamer functionalized graphene oxide (GO) nano-biosensor for simple, rapid, an

119 composite of Fe3O4 nanoparticles loaded onto graphene oxide (GO) nano-sheets (Fe3O4@GO).

120 ) electrode reinforced by MnO2/CuO loaded on graphene oxide (GO) nanoparticles (PVA/MnO2@GO/CuO).

121 d recombinant human tropoelastin (MeTro) and graphene oxide (GO) nanoparticles are developed.

122 pH, ionic strength (IS), and temperature on graphene oxide (GO) nanoparticles attachment onto quartz

123 We explore graphene oxide (GO) nanosheets functionalized dual-peak

124 tibacterial prickly Zn-CuO nanoparticles and graphene oxide (GO) nanosheets on a Ni porous electrode.

125 Herein, we report a graphene oxide (GO) nanosheets-based fluorometric DNA bi

126 with water molecules, are complemented by 2D graphene oxide (GO) nanosheets.

127 Two-dimensional (2D) graphene and graphene oxide (GO) offer great potential as a new type

128 of poly(3,4-ethylene dioxythiophene) (PEDOT)/graphene oxide (GO) onto the CFE surface is shown to inc

129 with deposition of carbon nanotube (CNT) or graphene oxide (GO) particles on the FN layer.

130 The pH sensor, based on a graphene oxide (GO) sensitive layer, had a sensitivity o

131 alized gold nanorods (GNRs) decorated on the graphene oxide (GO) sheet on the surface of the glassy c

132 interactions was designed based on decorated graphene oxide (GO) sheet with alumina (Al2O3) nanocryst

133 strong electrostatic interaction between the graphene oxide (GO) sheets and the TiO2 NFs, poly(allyla

134 Graphene oxide (GO) sheets are mixed with the aptamer-QD

135 sion electron microscopy (TEM) grids bearing graphene oxide (GO) sheets that have been modified with

136 We combined graphene oxide (GO) sheets with a specific peptide aptam

137 fting 3-mercaptopropyl trimethoxysilane on a graphene oxide (GO) surface.

138 flow system comprised of two functionalized graphene oxide (GO) surfaces that allow the capture of d

139 of a nature-inspired synthetic leaf made of graphene oxide (GO) thin film material, which exhibited

140 for reduction and simultaneous derivation of graphene oxide (GO) to form a biocompatible polymeric ma

141 ) were synthesized by a partial reduction of graphene oxide (GO) using urea [CO(NH2)2].

142 was prepared by electrochemical reduction of graphene oxide (GO) with PDA.

143 s having carbon materials as fillers such as graphene oxide (GO), carbon nanotubes (CNT), carbon blac

144 isotropic orientation of GBNs, most notably graphene oxide (GO), in previous experimental studies ob

145 l-modified electrodes (carbon, graphene (G), graphene oxide (GO), single wall carbon nanotube (SWCNT)

146 effects of the characteristic properties of graphene oxide (GO), such as the high hydrophilicity, ne

147 mical oxidation routes for the production of graphene oxide (GO), such as the Hummers' method, suffer

148 Graphene oxide (GO), the main precursor of graphene-base

149 Graphene oxide (GO), which is an oxidized form of graphe

150 In this study, sub-20-nm thick, layered graphene oxide (GO)-based hollow fiber membranes with gr

151 coccus lysodeikticus whole cells adsorbed on graphene oxide (GO)-coated Surface Plasmon Resonance (SP

152 we report an mRNA delivery system employing graphene oxide (GO)-polyethylenimine (PEI) complexes for

153 nanoscale materials, including graphene and graphene oxide (GO).

154 hylrhodamine-labeled LPS-binding peptides on graphene oxide (GO).

155 tum dots (QDs), carbon nanotubes (CNTs), and graphene oxide (GO).

156 cellent potential of carboxyl-functionalized graphene oxide (GO-COOH) composites to form biocompatibl

157 functionalized silver nanoparticle-decorated graphene oxide (GO-L-AgNPs) participates in pi-pi intera

158 Mercapto-modified graphene oxide (GO-SH) can be applied in quantitative ad

159 unctional groups so that the reduced form of graphene oxide (GO; reduced form: rGO) remains a highly

160 Nitrogen-doped graphene oxides (GO:Nx) were synthesized by a partial re

161 ransverse-magnetic (TM)-polarised light by a graphene-oxide (GO) coated polymer waveguide has been ob

162 nced Raman spectroscopy (SERS) of aggregated graphene oxide/gold nanoparticle hybrids with immunomagn

163 immobilized onto the surface of the reduced graphene oxide-graphene double-layer electrode via pi-pi

164 redox current was observed from the reduced graphene oxide-graphene double-layer electrode, a 42% an

165 ene by polyamidoamine (PAMAM) dendrimers and graphene oxide (GrO).

166 present work, a stimuli encoded zipper-like graphene oxide (GrO)/polymer interface was fabricated wi

167 Electrochemical analysis of graphene oxide has revealed an unexpected inherent redox

168 on solution processed layer by layer polymer/graphene oxide hybrid system has been demonstrated.

169 pproach to assemble copper-nanowires/reduced-graphene-oxide hybrid coatings onto inorganic and organi

170 l reactants (CO2 radical anions, S(2-)-doped graphene oxide in water) caused strong carbon (epsilonC

171 ing due to functionalization on the graphene-graphene oxide interface.

172 The device incorporates graphene oxide into a thermoresponsive polymer film to s

173 New coatings are obtained when graphene oxide is further oxidized at moderate anodic po

174 y the photoluminescence quenching ability of graphene oxide is reported.

175 Besides, graphene oxide is water soluble and thus easy to process

176 ing (d) of approximately 13.5 A, typical for graphene oxide laminates that swell in water.

177 articles as a model system, we implemented a graphene-oxide layer as a substrate to significantly red

178 ctional diamines as cross-linkers to connect graphene oxide layers.

179 developed for the preparation of large sized graphene oxide (LGO) sheets with lateral sizes >10 mum,

180 thesized via a co-precipitation method using graphene oxide/magnetic chitosan nanocomposite as suppor

181 Graphene oxide materials are engineered for robust self-

182 10 nm can be self-assembled within a reduced graphene oxide matrix in 10 ms.

183 The porous reduced graphene oxide matrix serves as an effective electron co

184 es embedded in a chemically-modified reduced graphene oxide matrix.

185 then thawing water trapped in the multilayer graphene oxide membrane leads to the opening up of micro

186 tigate the change in thickness of multilayer graphene oxide membranes due to intercalation of water,

187 In this work, however, we demonstrate that graphene oxide membranes may remove (99)Tc, present in t

188 Graphene oxide membranes show exceptional molecular perm

189 re we report a mechanochemical phenomenon in graphene oxide membranes, covalent epoxide-to-ether func

190 dditional experiments on chemically modified graphene oxide membranes, with ring-opened epoxide group

191 exhibit better chlorine resistance than pure graphene oxide membranes.

192 ose a reusable biosensor based on a magnetic graphene oxide (MGO)-modified Au electrode to detect vas

193 tudy, we report 3D LiMn0.75Fe0.25PO4/reduced graphene oxide microspheres synthesized by one-step salt

194 tify the adsorption of U(VI) to multilayered graphene oxide (MLGO), we tested whether three different

195 Reduced graphene oxide modified by pulsed laser ablation causes

196 In this work, graphene oxide modified electrodes were used as highly e

197 wder based on silver nanoparticles decorated graphene oxide modified glassy carbon electrode (AgNPs@G

198 We report herein the use of cysteamine-graphene oxide modified gold microelectrode arrays in un

199 ronounced plasticity and damage tolerance to graphene oxide monolayers.

200 of self-assembled melamine, phytic acid, and graphene oxide (MPSA/GO).

201 er mesoporous Co3 O4 /nitrogen-doped reduced graphene oxide (N-rGO) nanosheets.

202 of hydrogen peroxide (H2O2) using a reduced graphene oxide-nafion@silver6 (rGO-Nf@Ag6) nanohybrid mo

203 vel and highly sensitive biosensor employing graphene oxide nano-sheets (GO), multiwalled carbon nano

204 ly labeled single stranded probe strands and graphene oxide nanoassemblies have been used to detect m

205 in the same RNA family using two-dimensional graphene oxide nanoassemblies.

206 of this FRET strategy amplified using AuNPs/graphene oxide nanocomposite as quencher.

207 urface of Ag-ZnO bimetallic nanoparticle and graphene oxide nanocomposite.

208 was developed using zeolites nanoflakes and graphene-oxide nanocrystals (Zeo-GO).

209 BNNT bundles to a continuous array of White Graphene Oxide nanoplatelet stacks.

210 ds (AAs) has been developed using disposable graphene oxide nanoribbon (GON) screen printed electrode

211 (FET) biosensor utilizing solution-processed graphene oxide nanoribbon (GONR) for methylene blue (MB)

212 s and an oxygen-functional-group gradient in graphene oxide nanoribbon network assemblies.

213 properties of GNR and their parent products, graphene oxide nanoribbons (GONR).

214 te the microwave-assisted synthesis of short graphene oxide nanoribbons (GONRs) through unzipping cut

215 ased on ruthenium bipyridyl complex-modified graphene oxide nanosheets ([Ru(bpy)3](2+)-GO) is propose

216 ore-shell nanoparticles supported on reduced graphene oxide nanosheets (Ag@Pt-GRs) was synthesized an

217 ne oxide-carbon nanotube composite (GO-CNT), Graphene oxide nanosheets (GO) and Iron oxide nanopartic

218 ng of titanium dioxide nanofibers (TNFs) and graphene oxide nanosheets (GONs) for screen printed carb

219 We find that PEGylated graphene oxide nanosheets (nGO-PEGs) stimulate potent cy

220 depositing 1D cellulose nanocrystals and 2D graphene oxide nanosheets by using a spin assisted layer

221 n threshold are designed by reducing in situ graphene oxide nanosheets with ascorbic acid and suppres

222 e temperature tunable lamellar spaces of the graphene oxide nanosheets, the water permeance of the me

223 er-like morphology was formed on the reduced graphene oxide paper using pulsed sonoelectrodeposition,

224 ed blinking during graphene oxide-to-reduced graphene oxide photoreduction is attributed, in large pa

225 were performed by nanocomposite of magnetic graphene oxide-polyimide, as an efficient solid-phase ex

226 Fiber' concept, in which a partially reduced graphene oxide (prGO) film is deposited on a fiber-optic

227 aphene, including graphene oxide and reduced graphene oxide, properly functionalized for improved per

228 we could selectively produce either GQDs or graphene oxide quantum dots (GOQDs) by simply changing t

229 Covalent bonding of graphene oxide quantum dots (GOQDs) onto amino modified

230 The light emission from reduced graphene oxide quantum dots (rGO-QDs) exhibit a signific

231 have reported the novel synthesis of reduced graphene oxide (r-GO) dendrite kind of nanomaterial.

232 g Li into bendable scaffolds such as reduced graphene oxide (r-GO) films.

233 ide (MoSx) is covalently anchored to reduced graphene oxide (r-GO) via a simple one-pot reaction, the

234 ediators or functionalization of the reduced graphene oxide (rGO) active layer.

235 novel anode was developed by coating reduced graphene oxide (rGO) and manganese oxide (MnO2) composit

236 or for chlorpromazine (CPZ) based on reduced graphene oxide (RGO) and polydopamine (PDA) composite mo

237 d with gold nanoparticles (GNPs) and reduced graphene oxide (rGO) as a sensing nano-hybrid film was d

238 ive random access memory technology, reduced graphene oxide (RGO) can be widely used for non-volatile

239 a co-polymer matrix assembled on the reduced graphene oxide (RGO) electrode surface.

240 Due to abundant pi bonds, reduced graphene oxide (RGO) exhibited significantly higher labe

241 a polypeptide (JR2EC) functionalized reduced graphene oxide (rGO) field effect transistor (FET) is re

242 An olfactory biosensor based on a reduced graphene oxide (rGO) field-effect transistor (FET), func

243 g supercapacitors based on 3D porous reduced graphene oxide (RGO) film exhibit extremely high specifi

244 using electrophoretically deposited reduced graphene oxide (RGO) films for the first time.

245 f redox active and bioengineering of reduced graphene oxide (RGO) for the development of versatile bi

246 Reduced graphene oxide (rGO) has been fabricated into a microele

247 derivatives, graphene oxide (GO) and reduced graphene oxide (rGO) have played an important role in im

248 S nanoparticles anchored onto a MoS2-reduced graphene oxide (rGO) hybrid.

249 he temperature sensor was based on a reduced graphene oxide (rGO) layer that changed its electrical r

250 e electrochemical biosensor based on reduced graphene oxide (rGO) modified disposable pencil graphite

251 (3,4-ethylenedioxythiophene) (PEDOT)-reduced graphene oxide (rGO) nanocomposite modified fluorine dop

252 ers (NFs) are tightly wrapped inside reduced graphene oxide (rGO) nanosheet skeletons, for high-perfo

253 e method to produce conformal coated reduced graphene oxide (rGO) on vertically aligned titanium oxid

254 ent broadband thermal radiation from reduced graphene oxide (RGO) paper mixed with single-walled carb

255 e have fabricated a nanocomposite of reduced graphene oxide (rGO) sheets and chitosan (Cn) polymer ba

256 Fs) through an effective wrapping of reduced graphene oxide (rGO) sheets on electrospun TiO2 NFs.

257 by atomically thin and gas-selective reduced graphene oxide (rGO) sheets.

258 anoparticles (AgNPs) were mixed with reduced graphene oxide (rGO) to modify the surface of screen-pri

259 sis of gold nanoparticles (AuNPs) on reduced graphene oxide (rGO) using an aqueous solution of chitos

260 Reduced graphene oxide (rGO) was thus functionalized by Prussian

261 d on the controllable integration of reduced graphene oxide (rGO), amorphous carbon, and MgO nanocrys

262 k electrode (AuDE) was coated with a reduced graphene oxide (rGO), decorated with plasmonic gold-coat

263 With the help of 2D electroactive reduced graphene oxide (RGO), we successfully inhibited the Brow

264 rial nanocellulose (BNC) layer and a reduced graphene oxide (RGO)-filled BNC layer is introduced for

265 ized polypyrrole (PPy) film with the reduced graphene oxide (rGO).

266 stretching method, a highly elastic reduced graphene oxide (rGO)/polyacrylic ester hierarchically wr

267 ed on gold nanoparticles anchored on reduced graphene oxide (RGO-AuNPs) and l-lactate dehydrogenase (

268 and theoretical characterization for reduced Graphene-Oxide (rGO) based FETs used for biosensing appl

269 nanocomposite material consisting of reduced graphene oxide/Rh nanoparticles was prepared by a one-po

270 Solvated reduced graphene oxide (S-rGO) membranes are stable in organic s

271 es essential experimental aspects of reduced graphene oxide's absorption/emission trajectories, while

272 he underlying photochemistry responsible for graphene oxide's reduction.

273 ther, this array-based luminescent nanoprobe-graphene oxide sensing platform presents a useful cell s

274 tem is based on the utilization of nanoprobe-graphene oxide sensor elements that can be disrupted in

275 xtend aromatic conjugation into the combined graphene oxide sheets and are responsible for the highly

276 The oxygen functional groups in these graphene oxide sheets and the addition of KOtBu are esse

277 buted to the direct electropolymerization of graphene oxide sheets via oxidation of the phenol edge g

278 The effects of utilizing graphene oxide, silica, and gold nanoparticles in cancer

279 To develop the method, a graphene oxide-silica composite reinforced hollow fiber

280 triguing functionalities of wrinkled reduced graphene oxide, single-layer graphene, and few-layer hex

281 This biosensor was constructed by coating graphene oxide/ssDNA (GO-ssDNA) on an Au-electrode for V

282 h ferrocene molecules covalently anchored on graphene oxide, sulfur electrode materials with capacity

283 rd-order nonlinearity about 0.45 cm(2)/GW in graphene oxide thin films at the telecommunication wavel

284 graphene-based film bonded to functionalized graphene oxide through amino-silane molecules.

285 g TiO2 with sulfur and incorporating reduced graphene oxide (TiO2-S/rGO hybrid), with an aim to narro

286 Here we show that unexpected blinking during graphene oxide-to-reduced graphene oxide photoreduction

287 band of TiO2 into the Fermi level of reduced graphene oxide under external electric field.

288 y(N-isopropylacrylamide) covalently bound to graphene oxide via free-radical polymerization.

289 de concentration, number of cycles to reduce graphene oxide, volume of iridium oxide nanoparticles an

290 pi-pi bonds and electrochemical reduction of graphene oxide was achieved by cyclic voltammetry.

291 rode modified with electrochemically reduced graphene oxide was developed for the detection of a spec

292 The graphene oxide was immobilized onto the surface of a gra

293 Oxide, and therefore we term them as "White Graphene Oxide" (WGO).

294 exfoliation of graphite or the reduction of graphene oxide, while graphene films are prepared predom

295 s is fabricated through thermal treatment of graphene oxide with a nitrogen-contained resin.

296 sensor that is achieved by coupling reduced graphene oxide with gamma-cyclodextrin (rGO/gamma-CD).

297 lved the simultaneous reduction of RhCl3 and graphene oxide with NaBH4 and the in situ deposition of

298 osed of 7 wt% 'lithiophilic' layered reduced graphene oxide with nanoscale gaps that can host metalli

299 Reduced graphene oxide-yttria nanocomposite (rGO:Y) is applied a

300 nia (average particle size 13 nm) on reduced graphene oxide (ZrO2-RGO) to avoid coagulation of the zi