ライフサイエンスコーパス: graphene oxide

1 imprinted acrylamide functionalized reduced graphene oxide.

2 ristine graphene, graphene oxide and reduced graphene oxide.

3 he chemical and electrochemical reduction of graphene oxide.

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

5 t, structural nanocomposites reinforced with graphene oxide.

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

7 mperature-induced pseudocapacitive effect of graphene oxide and a thermogalvanic effect of Fe(2+)/Fe(

8 t and sensitive electrochemical sensor using graphene oxide and beta-cyclodextrin functionalized mult

9 ode system combines the high surface area of graphene oxide and carbon nanotubes, and the superior ho

10 o generate a distance among graphene dot and graphene oxide and fluorescence is ON.

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

12 a new fluorescence immunosensor with use of graphene oxide and graphene quantum dot for detection Ca

13 from an oil-in-water emulsion stabilized by graphene oxide and including a silicate precursor to gro

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

15 carbon nanotubes during the self-assembly of graphene oxide and M13, and a similar porous macro-struc

16 r can be attached to the surface of a hemin, graphene oxide and multi-walled carbon nanotubes glassy

17 o do this, a ternary nanocomposite of hemin, graphene oxide and multi-walled carbon nanotubes was use

18 can be successfully incorporated into hemin, graphene oxide and multi-walled carbon nanotubes.

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

20 a nanocomposite based on the functionalised graphene oxide and poly(carbonate-urea)urethane with the

21 mensional self-assembled heterostructures of graphene oxide and polyamine macromolecules, forming a n

22 ing on non-radiative energy transfer between graphene oxide and quantum dots for determination of E.

23 Graphene-based materials particularly graphene oxide and reduced graphene oxide are widely uti

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

25 s have been presented, as pristine graphene, graphene oxide and reduced graphene oxide.

26 tion of hydrogel prevents the aggregation of graphene oxide and significantly promotes their excellen

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

28 technologies such as those based on reduced graphene oxide, and surpass the temperature stability li

29 ional macrostructures (3DMs) of graphene and graphene oxide are being developed for fast and efficien

30 ials particularly graphene oxide and reduced graphene oxide are widely utilized in various applicatio

31 printed polymer (MIP) and gold nanoparticles/graphene oxide (Au/GO).

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 iosensors were developed by using commercial graphene oxide-based screen-printed electrodes and varyi

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

36 A novel One MoNomer dual imprinted graphene oxide/carbon black composite polymer was develo

37 Acryloylated-graphene oxide/carbon black was synthesized for the firs

38 immobilizing Hb on electrochemically reduced graphene oxide-chitosan (ERGO-CS/Hb/FTO) based biocompat

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

40 LOD values measured on graphene oxide coated side by LDI-MS were found to be 0.

41 This technology is based on graphene oxide-coated microplates (GOMs) and photolumine

42 udy demonstrates the development of flexible graphene oxide coatings (GOCs) by the screen-printed tec

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

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

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

46 Cu-MOF-graphene oxide (Cu-MOF-GO) nanocomposite was prepared an

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

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

49 h in situ binding of glycine on the magnetic graphene oxide, electrostatically.

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

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

52 c method, slightly electrochemically reduced graphene oxide (ERGO) presents an anion preference for c

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

54 The current response was mediated by graphene oxide-ferrocene nanofilm with redox-activity co

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

56 smart actuator with precise patterning on a graphene oxide film by hydrogel microstamping.

57 resistance-a mechanical barrier effect-while graphene oxide films absorb the water and convert to mec

58 fied with Au nanoparticles decorated reduced graphene oxide flakes, exhibits a LOD of 0.088 mg L(-1).

59 In contrast to commonly used graphene oxide flakes, pristine graphene flakes possess

60 demonstrate the clear potential of magnetic graphene oxide for magnetic resonance imaging (MRI) appl

61 mposite consisting of poly 3-aminophenol and graphene oxide for solid-phase microextraction of triazo

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

63 le layered acrylamide functionalised reduced graphene oxide-fullerene composite and double layered ac

64 generating acrylamide functionalised reduced graphene oxide-fullerene layer-by-layer assembled dual i

65 low-cost and simplicity for production, ii) graphene oxide functionalised surface to reduces the bio

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

67 particles- poly (4-aminothiophenol)/ reduced graphene oxide/glassy carbon electrode (AuNPs-PAT/rGO/ G

68 The effects of graphene oxide (GO) addition in the PVC gel were also in

69 Herein, we report a hydroxyl-rich graphene oxide (GO) aerogel that can preserve the enzyma

70 ion of screen-printed carbon electrodes with graphene oxide (GO) and an additional layer of cellulose

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

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

73 Recent research has revealed the use of graphene oxide (GO) and its derivatives as a potential b

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

75 ce studies on the MPO-catalyzed oxidation of graphene oxide (GO) and surfactant-coated pristine (6,5)

76 Composites of graphene oxide (GO) and tea waste (TW) exhibited a promi

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

78 Studies unraveling the interactions between graphene oxide (GO) and the biological milieu, including

79 photoluminescence quenching capabilities of graphene oxide (GO) and the versatile format offered by

80 RET) between quantum dot (QD) as a donor and graphene oxide (GO) as an acceptor.

81 Recent studies have demonstrated that graphene oxide (GO) based polymer beads cannot only adso

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

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

84 near-field electrostatic printing (NFEP) and graphene oxide (GO) coating.

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

86 7,7,8,8-tetracyanoquinodimethane (TCNQ) and graphene oxide (GO) for low-potential amperometric detec

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

88 polar resistive switching characteristics in graphene oxide (GO) have been extensively studied in rec

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

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

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

92 Graphene oxide (GO) is an antimicrobial agent with tunab

93 In this study, graphene oxide (GO) is conjugated with ZOL, and the nano

94 ce (SPR) sensor utilizing silver (Ag) and Ag-graphene oxide (GO) is designed and developed for the de

95 charge storage and membrane applications of graphene oxide (GO) materials are dictated by its intrin

96 A polyethersulfone (PES)-supported graphene oxide (GO) membrane has been developed by a sim

97 Graphene oxide (GO) membranes continue to attract intens

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

99 chemically engineered Au-nano-Dendroids, and graphene oxide (GO) nanocomposite.

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

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

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

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

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

105 mainly based on graphene derivatives such as graphene oxide (GO) or reduced graphene oxide (rGO), whi

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

107 Controlling the structure of graphene and graphene oxide (GO) phases is vitally important for any

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

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

110 lfide (SnS) and titanium dioxide (TiO(2)) on graphene oxide (GO) sheets (SnS/TiO(2)@GO ternary compos

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

112 Gold nanoparticles (AuNPs) and graphene oxide (GO) sheets are representative zero- and

113 Graphene oxide (GO) sheets have been used as a model sys

114 Graphene oxide (GO) sheets have been used to construct v

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

116 When mixing graphene oxide (GO) slurry with metal foam and drying in

117 ers were synthesized and blended with a PVDF/graphene oxide (GO) solution, then, electrospun and coat

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

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

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

121 buzov reaction, we are able to functionalize graphene oxide (GO) to produce phosphate graphenes (PGs)

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

123 ion of human serum albumin (HSA) proteins on graphene oxide (GO) was investigated through batch adsor

124 Graphene oxide (GO) was used as a platform for screening

125 is activated upon coating a layer of coupled graphene oxide (GO) with sensitive chemical compounds al

126 The direct treatment of graphene oxide (GO) with the commercially available Lawe

127 posite form of iron oxide nanoparticles (IO)-graphene oxide (GO) with tunable core magnetism and magn

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

129 ipyridine complex (Ru(II)) on the surface of graphene oxide (GO), enabling a dual-functional immunopr

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

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

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

133 Graphene oxide (GO), the most common derivative of graph

134 t properties of both disordered proteins and graphene oxide (GO), we report a disordered protein-GO c

135 Graphene oxide (GO)-based composite materials have becom

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

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

138 reproducible hybrid SERS substrate based on graphene oxide (GO)-supported l-cysteine-functionalized

139 -based metal-organic frameworks (Fe-MOF) and graphene oxide (GO).

140 g hydrothermal technique and integrated with graphene oxide (GO).

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

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

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

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

145 lution-processed 2D-molybdenum disulfide and graphene-oxide (GO) that can be deposited on to stainles

146 alent linking of the two platforms involving graphene oxide-gold nanoparticles (GO-AuNPs) functionali

147 Graphene oxides (GOs) are popular catalyst supports for

148 m, large-area, layered graphene composite of graphene oxide/graphene (GO/G) for the detection of circ

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

150 NM) frameworks, especially those comprising graphene oxide, have received extensive research interes

151 Pyrocatechol violet impregnated magnetic graphene oxide hybrid material (PV-MGO) was prepared as

152 e freestanding transition-metal carbides and graphene oxide hybrid membranes as high-performance PRO

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

154 The strategy involves graphene-oxide/I(2)-catalyzed nitrene insertion using Ph

155 By using graphene oxide in immunosensor fabrication procedure, an

156 r was coated with a nanometric thin layer of graphene oxide in order to provide functional groups for

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

158 in-situ polymerization of 3-aminophenol and graphene oxide in weak alkaline media.

159 A water-based graphene oxide ink was first formulated and single-drop

160 The optical response of a graphene oxide integrated silicon micro-ring resonator (

161 Graphene oxide, integrated with the filamentous bacterio

162 dependent capillary condensation within the graphene oxide interlayers, which, when combined with hi

163 through constructing a heterostructure with graphene oxide, ion selectivity of the BP membrane incre

164 osed technology is highly transformative, as graphene oxide is able to quench different fluorophores,

165 carbon-based nanofillers such as graphene or graphene oxide is expected to yield low-density nanocomp

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

167 cells, distance between of graphene dot and graphene oxide is very low and graphene quantum dot fluo

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

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

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

171 otropic LCs (DNA LCs, nanocellulose LCs, and graphene oxide LCs) is showcased.

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

173 The biostrip consists of mesoporous-chitosan-graphene oxide (m-Chit-GO) composite-based sensing elect

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

175 gamma-Mg(BH(4) )(2) nanocrystals and reduced graphene oxide (MBHg) is described.

176 Layered graphene oxide membranes (GOM) with densely packed sub-n

177 Graphene oxide membranes show exceptional molecular perm

178 exhibit better chlorine resistance than pure graphene oxide membranes.

179 In this study, we report engineered magnetic graphene oxide (MGO) in the nanocomposite form of iron o

180 an inkjet-printed electrochemically reduced graphene oxide microelectrode for HT-2 mycotoxin immunoe

181 The printed graphene oxide microelectrodes were electrochemically re

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

183 Reduced graphene oxide modified by pulsed laser ablation causes

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

185 erials, carbon based nano-modifiers (reduced graphene oxide, multi-walled carbon nanotubes, ordered m

186 Three-dimensional reduced graphene oxide-multiwall carbon nanotubes (3DrGO-MWCNTs)

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

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

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

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

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

192 UC1 based on metal-organic framework-reduced graphene oxide nanocomposite (Cu-MOF-RGO).

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

194 For this reason, a chitosan-graphene oxide nanocomposite film was prepared and imple

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

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

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

198 The results show that graphene or graphene oxide nanosheet films in the dry state are high

199 Then HRP@PGH NPs and graphene oxide nanosheets (GO NSs) were simultaneously e

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

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

202 ultrathin two-dimensional materials such as graphene oxide nanosheets and further assembled into a m

203 D enzyme-polymer nanoparticles (NPs) with 2D graphene oxide nanosheets as conductive supports and nan

204 -aluminum layered double hydroxide coated on graphene oxide nanosheets was synthesized.

205 port a hierarchically nanostructured reduced graphene oxide nanosheets-polypyrrole (rGO@PPy) electrod

206 In this study, we synthesized nano-graphene oxide (NGO) nanoparticles with GRPR-specific pe

207 tionalized micromotors (anti-CRP-rGO(reduced graphene oxide)/Ni/PtNPs (platinum nanoparticles))-based

208 A doubly porous microcomposite polyaniline/graphene oxide/octadecyl-bonded silica magnetite (PANI/G

209 ensitivity of BP-TFG is 100-fold higher than graphene oxide or AuNPs based biosensors.

210 ble extracellular electron acceptors such as graphene oxide or electrodes in microbial electrolysis c

211 le layered acrylamide functionalised reduced graphene oxide or fullerene molecules, which yielded ver

212 le layered acrylamide functionalised reduced graphene oxide or fullerene, single layered acrylamide f

213 On another layer, graphene oxide paper was applied as an LDI-MS substrate

214 e specific cases of molybdenum disulfide and graphene oxide particles, dispersed in a nematic liquid

215 Hg, Co, Ni ions using pectin coated magnetic graphene oxide (pectin/Fe(3)O(4)/GO) is presented.

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

217 ions: a colloidal nematic phase comprised of graphene oxide platelets and a nematic phase formed by a

218 we use MXene (M) nanosheets to functionalize graphene oxide platelets through Ti-O-C covalent bonding

219 rging cell, using asymmetric electrodes of a graphene oxide/platinum nanoparticles cathode and a poly

220 ble Prussian blue (PB)-incorporated magnetic graphene oxide (PMGO) as a peroxidase-mimicking nanozyme

221 roxidase-mimicking, PB-incorporated magnetic graphene oxide (PMGO).

222 ficient for immobilization of carrageenan on graphene oxide/poly(ethylenimine) support (denoted as GO

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

224 Although chemical oxidation of graphite to graphene oxide promotes exfoliation, it requires harsh o

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

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

227 the presence of ascorbic acid via an in situ graphene oxide reduction and beta-CD functionalization p

228 posed by biopolymers and activated carbon or graphene oxide removed up to 70% of mycotoxins (adsorpti

229 ti-walled carbon nanotubes (MWCNTs), reduced graphene oxide (RGO) and fullerene (C(60)), and show sim

230 reen printed electrode modified with reduced graphene oxide (rGO) and gold nano-urchins (AuNUs).

231 uter layer (using carbon black (CB), reduced graphene oxide (rGO) and multi-walled carbon nanotubes (

232 lactone (PCL) and various amounts of reduced graphene oxide (rGO) at 0.5, 1, and 3 wt.%.

233 e have designed here a fully printed Reduced Graphene Oxide (rGO) based impedimetric sensor for one s

234 Herein, we present that the reduced graphene oxide (rGO) doped with nanometer-sized ferrocen

235 Aggregation of reduced graphene oxide (RGO) due to pai-pai stacking is a recurr

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

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

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

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

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

241 for water treatment; in particular, reduced graphene oxide (rGO) membranes with high stability in aq

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

243 ction using Au-nanorattles (AuNRTs)- reduced graphene oxide (rGO) nanocomposite coated on to the gold

244 (3,4-ethylenedioxythiophene) (PEDOT)-reduced graphene oxide (rGO) nanocomposite modified fluorine dop

245 The reduced graphene oxide (rGO) nanosheet is used as the channel ma

246 ose like La(3+)@ ZrO(2) supported on reduced graphene oxide (RGO) nanosheets.

247 ion of bioelectrodes made from laser-reduced graphene oxide (rGO) on flexible polyethylene terephthal

248 Flexible reduced graphene oxide (rGO) sheets are being considered for app

249 drying strategy for the synthesis of reduced graphene oxide (rGO) supported Pt(3) M (M=Mn, Cr, Fe, Co

250 Reduced graphene oxide (rGO) thin films can be exploited as high

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

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

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

254 ntial chemical treatment to generate reduced graphene oxide (rGO) within 3D-printed polylactic acid (

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

256 mposed of polymers and particulates, reduced graphene oxide (rGO), and metal-organic frameworks.

257 ical metal-oxide cathodes (Co(3)O(4)@reduced graphene oxide (rGO), Fe(2)O(3)@rGO, and CoFe(2)O(4)@rGO

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

259 tives such as graphene oxide (GO) or reduced graphene oxide (rGO), which suffers from poor electrical

260 rites, is achieved on self-assembled reduced graphene oxide (rGO).

261 drogel, silver nanowires (AgNW), and reduced graphene oxide (rGO).

262 n-line, impedimetric aptasensor with reduced graphene-oxide (rGO) thin films as transducers to detect

263 ting the electrodes by nanoflakes of reduced-graphene-oxide (rGO), and immobilizing specific viral an

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

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

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

267 FIA) with amperometric detection and reduced graphene oxide sensor for ascorbic acid determination in

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

269 manufactured from individual two-dimensional graphene oxide sheets by a fluidics-enabled assembling p

270 the enhanced shear thinning degree of large graphene oxide sheets in solution.

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

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

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

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

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

276 sor for potassium metabisulphite (KMS) using graphene oxide stabilized gold nanoparticles (GO-AuNPs)

277 d pressure, the [Formula: see text] bonds of graphene oxide stiffen very little with increasing press

278 nsmitted to the [Formula: see text] bonds of graphene oxide straightforwardly as in graphite.

279 ay from both the air-water interface and the graphene oxide surface, protecting them from potential d

280 n electrode (GC) was modified with thiolated graphene oxide (T-GO) to elevate the active surface area

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

282 Reduced graphene oxide/tin dioxide (RGO/SnO(2)) binary nanocompo

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

284 tor is functionalized with partially reduced graphene oxide to create a potassiophilic surface, the e

285 rids coated with mostly one or two layers of graphene oxide to facilitate affinity capture.

286 Simultaneous electroreduction of graphene oxide to RGO and covalent attachment of 4-ABA a

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

288 t a tyrosinase-conjugated zinc oxide-reduced graphene oxide (Tyr/ZnO-rGO) nanocomposite system as a b

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

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

291 Herein, graphene oxide was used for creating disordered macro an

292 two Raman bands of molybdenum disulfide and graphene oxide, we demonstrate that an accurate position

293 ectrospun polyurethane nanofibers doped with graphene oxide were collected on a thin metal net sheet

294 sed electrodes, we covalently functionalized graphene oxide with a redox active thiourea-formaldehyde

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

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

297 lectrochemical and viscoelastic responses of graphene oxides with various degree of electrochemical r

298 duction of soluble fumarate and heterogenous graphene oxide, with electrons from an external power so

299 ZIF-8-graphene oxide (ZIF-8-GO) is first synthesized via a sim

300 Here, we report ZIF-8-reduced graphene oxide (ZIF-8-rGO)-supported bimetallic AuPt nan