ライフサイエンスコーパス: electrodeposition

1 changes induced by surface reactions (e.g., electrodeposition).

2 It also affects the results expected from electrodeposition.

3 ized on Ti foil for PEC converter by in situ electrodeposition.

4 arget electrode is achieved here by cathodic electrodeposition.

5 and used to control dendritic growth during electrodeposition.

6 E was modified by gold nanoparticles (AuNPs) electrodeposition.

7 k enzyme layer (CS-GA-GOx) was fabricated by electrodeposition.

8 gel chemistry, chemical bath deposition, and electrodeposition.

9 de patterns using a one-step template-guided electrodeposition.

10 hickness of an incipient nanowire during its electrodeposition.

11 subsequent comparator-terminated directional electrodeposition.

12 d growth of nanoscale copper clusters during electrodeposition.

13 own on the three low-index planes of gold by electrodeposition.

14 the polymeric materials did not give rise to electrodeposition.

15 alt/nickel binary oxides were synthesised by electrodeposition.

16 d to HER, while the rest contributes to zinc electrodeposition.

17 cobalt and nickel during potential-dependent electrodeposition.

18 the dendritic growth of metals such as Li in electrodeposition.

19 underpins our poor understanding of Li metal electrodeposition.

20 PG) was loaded on electrode surface by pulse electrodeposition.

21 tosuccinate complex, which enable uniform Au electrodeposition.

22 in turn grow along the Cu(2+) gradient upon electrodeposition.

23 acturing process for Si solar cells based on electrodeposition.

24 can be controlled by the parameters of metal electrodeposition.

25 ion barrier for sodium ions, enabling stable electrodeposition.

26 lity during recharge drives rough, dendritic electrodeposition.

27 y-COOH/MNPs, using a chronoamperometric (CA) electrodeposition.

28 harge density versus Deltaf plots for the Ag electrodeposition.

29 strated using direct visualization of sodium electrodeposition.

30 n of imprint lithography, self-assembly, and electrodeposition.

31 reasing R; the latter is adjusted through Pt electrodeposition.

32 atings enable remarkably compact and uniform electrodeposition.

33 the transducer after hydrogel removal and re-electrodeposition.

34 gasoline/diesel, metal processing, and metal electrodeposition.

35 thermal oxidation, electropolymerization and electrodeposition.

36 sorbs at the electrode surface to enhance Mg electrodeposition.

37 [1 1 0] Bi2Te3 films were obtained by pulsed electrodeposition.

38 chiral surfaces can also be produced through electrodeposition, a relatively simple solution-based pr

39 BiVO(4) films were prepared by a simple electrodeposition and annealing procedure and studied as

40 level of construction, particularly for Ptyr electrodeposition and antibody concentration, to optimiz

41 d n-Si/Au nanoparticle Schottky junctions by electrodeposition and characterized them using scanning

42 However, inhomogeneous electrodeposition and contact loss often hinder the appl

43 n situ, real-time, and quantitative study of electrodeposition and electrodissolution.

44 -sections are fabricated by a combination of electrodeposition and glancing-angle deposition (GLAD).

45 ties at the metal anode produce uneven metal electrodeposition and poor anode reversibility, which, a

46 tely determine the faradaic efficiency of Zn electrodeposition and provides a powerful tool for evalu

47 he same compositions prepared by widely used electrodeposition and sputtering methods.

48 adapts to morphological perturbations during electrodeposition and stripping but also modulates the l

49 chloride complex (MACC) which shows high Mg electrodeposition and stripping efficiencies and relativ

50 ransparent electrode (ITO-OTE) accompany the electrodeposition and stripping of lead and mercury on t

51 The electrodeposition and subsequent stripping of lead and c

52 1 to 20 micrometers thick were fabricated by electrodeposition and suitable annealing.

53 Cu electrodeposition and the electrocatalysis of hydrogenat

54 ccepted to explain the early stages of metal electrodeposition and thin-film growth on low-energy sub

55 onto a screen-printed electrode by one-step electrodeposition and used to conjugate the HA ovalbumin

56 be ideal as the electrode material for both electrodeposition and XRF due to its wide solvent window

57 pproach combining electrochemical bottom-up (electrodeposition) and top-down (anodization) processes.

58 antum dots were found to catalyze the silver electrodeposition, and on the other hand, a strong adsor

59 m, followed by room environment nozzle-based electrodeposition, and subsequent etching of the blanket

60 fabricated in anodic alumina membranes using electrodeposition, and this technique is applicable to a

61 le and efficient hydrogen evolution-assisted electrodeposition approach.

62 and provide a promising outlook of selective electrodeposition as an efficient separation approach fo

63 Upd is electrodeposition at a potential prior to that needed to

64 ricated by combining self-assembly and metal electrodeposition at microgap electrodes (E1 and E2).

65 n the GC by a potentiostatic pulse method of electrodeposition at optimized -0.75 V for 1000 s.

66 d explaining electrodepostion mechanisms and electrodeposition-based synthesis strategies used for th

67 in side reactions, dendrite growth, and poor electrodeposition behavior, which prevent its practical

68 ty and low migration barrier, promote planar electrodeposition behavior.

69 Directional electrodeposition between the Au thin-film electrodes, a

70 talline electrolyte modifies the kinetics of electrodeposition by introducing additional overpotentia

71 pect to Mg deposition; however, efficient Mg electrodeposition can be achieved following an electroly

72 re generally, these results demonstrate that electrodeposition can provide a straightforward means of

73 from three perspectives: solution chemistry, electrodeposition chemistry, and film storage chemistry.

74 tal understanding of the in-flask chemistry, electrodeposition chemistry, and storage chemistry limit

75 Adjusting the electrodeposition conditions allowed for tuning of the s

76 Tuning the electrodeposition conditions can allow synthesis of unli

77 By use of moderate electrodeposition conditions such as 50 muM silver, -0.1

78 NPs was initially studied by controlling the electrodeposition conditions.

79 ilm thickness and doping type by varying the electrodeposition conditions.

80 Direct visualization of sodium electrodeposition confirms large improvements in stabili

81 Shock electrodeposition could be exploited to enhance the cycl

82 may be applied to investigate phenomena like electrodeposition, dendrite growth in batteries, and mem

83 ubstantial improvement over BMPyrTFSI for Mg electrodeposition/dissolution.

84 The demand for mining metals via electrodeposition drives the need for high-performance e

85 The electrodeposition duration determines the width of the n

86 ial processes at a Li metal anode, including electrodeposition during battery recharge.

87 mulations incorporating the basic physics of electrodeposition during the early stages of growth.

88 approaches (layer-by-layer (LbL) or one-step electrodeposition (EcD)), layers composition and structu

89 of these two OER pathways with that of MnOx electrodeposition elucidates the self-healing characteri

90 resent a fundamental challenge for selective electrodeposition, especially for critical elements such

91 The polymeric materials undergo electrodeposition following the two-electron reduction o

92 ys of mesoscopic palladium wires prepared by electrodeposition form the basis for hydrogen sensors an

93 (25-microm diameter) were prepared either by electrodeposition from a mercuric ion solution or by sim

94 e growth of dendritic copper structures upon electrodeposition from a negative electrode at the sub-m

95 A water oxidation catalyst generated via electrodeposition from aqueous solutions containing phos

96 for an oxygen evolving catalyst prepared by electrodeposition from Co(2+) solutions in weakly basic

97 ee anodes for oxygen production, and silicon electrodeposition from gaseous precursors.

98 ater oxidation catalysts (Co-Pi) prepared by electrodeposition from phosphate electrolyte and Co(NO(3

99 ave been prepared using a one-step templated electrodeposition from solutions containing different co

100 ts the ultrasmall quartz tip but also starts electrodeposition from the tip orifice.

101 Amongst the possible fabrication techniques, electrodeposition has attracted attention due to its sim

102 he metastable phase through room-temperature electrodeposition in aqueous solution without requiring

103 ME-NEEs are shown to be unique platforms for electrodeposition in forming nanoparticle electrodes (UM

104 shown that surface conduction can stabilize electrodeposition in random, charged porous media at hig

105 NMR (TD-NMR) spectrometer to monitor copper electrodeposition in situ is presented.

106 and quantify ammonia synthesis using lithium electrodeposition in tetrahydrofuran(13).

107 form, and the wires prepared in a particular electrodeposition (in batches of 10(5) to 10(7)) were na

108 Because the rate of the electrodeposition increases with the surface density of

109 properties, and ability to promote stable Li electrodeposition investigated.

110 The alginate electrodeposition involves the controlled Ca(2+) release

111 A long-held view is that unstable electrodeposition is a consequence of inherent character

112 ned by the dimension of the Bi catalyst, the electrodeposition is a reliable method to synthesize nan

113 Electrodeposition is an important approach that can prod

114 y of the Pt substrates prior to and after Ag electrodeposition is examined using atomic force microsc

115 Electrodeposition is found to be dominated by a 2D nucle

116 ire bonding process referred to as gas-phase electrodeposition is reported to form nanobridge-based i

117 During electrodeposition it is possible to vary both the deposi

118 the substrate through one-step template-free electrodeposition, leading to an intimate contact betwee

119 d Pt were synthesized on Au nanoparticles by electrodeposition, leading to controllable size and opti

120 hing of the extended gate electrode prior to electrodeposition, leading to dEGFETs that exhibit a med

121 ocess of lithographically patterned nanowire electrodeposition (LPNE) and then characterized with sca

122 Lithographically patterned nanowire electrodeposition (LPNE) combines attributes of photolit

123 sing the lithographically patterned nanowire electrodeposition (LPNE) method, and (3) electrical dete

124 ocess of lithographically patterned nanowire electrodeposition (LPNE), and then "inked" with biotinyl

125 FA using lithographically patterned nanowire electrodeposition (LPNE).

126 ocess of lithographically patterned nanowire electrodeposition (LPNE).

127 However, a fundamental understanding of the electrodeposition mechanism has been limited by its comp

128 id-to-solid electroreduction and dissolution-electrodeposition mechanisms can easily lead to the form

129 hin films were growth by a dynamic oxidation electrodeposition method (AEIROF).

130 least for platinum, to the constant-current electrodeposition method commonly utilized to prepare SE

131 We developed an electrodeposition method that exploits the thermodynamic

132 nts, suitable modifications were made to the electrodeposition method to prepare films whose architec

133 We introduce a simple and inexpensive electrodeposition method to produce an efficient n-Si/Si

134 Pt-Au nanowire array has been prepared by an electrodeposition method within anodic aluminum oxide (A

135 h gradient composition are fabricated by the electrodeposition method.

136 ous or nonaqueous conditions using versatile electrodeposition methods.

137 ed low throughput limitation of conventional electrodeposition methods.

138 Li electrode architectures for regulating Li electrodeposition morphology and crystallinity.

139 an be applicable to other phenomena, such as electrodeposition, nucleation, and membrane deformation.

140 erage 7 nm in diameter) were produced during electrodeposition, occupying only ~2.4% of the total vol

141 Electrodeposition of a catalytically competent species i

142 ed with antibodies specific for IL-6 through electrodeposition of a diazonium linking group and N'-et

143 rolytic decomposition of butane, followed by electrodeposition of a thin layer of hydrous iridium oxi

144 We report that a 15 s electrodeposition of amorphous TiO2 (a-TiO2) on W:BiVO4/

145 Electrodeposition of an amorphous cobalt catalyst layer

146 phonate, and borate electrolytes effects the electrodeposition of an amorphous highly active water ox

147 We describe a method for the electrodeposition of an isolated single Pt atom or small

148 ming the poly(APPIBr)/AuNRs/GCE interface by electrodeposition of APPIBr, anti-SCCA immobilization, a

149 ith NP diameters ranging from 8 to 250 nm by electrodeposition of Au from HAuCl(4) in H(2)SO(4) at po

150 has been modified in 3 subsequent steps: i) electrodeposition of Au-multiwalled carbon nanotubes (MW

151 Electrodeposition of bismuth and indium improved Zn(2+)

152 Steady-state electrodeposition of Co-OEC exhibits a Tafel slope appro

153 and Sb(3+) can be used as precursors for the electrodeposition of CO2 reduction cathode materials fro

154 sitionally similar to that obtained from the electrodeposition of cobalt oxide materials from phospha

155 ty toward hydrogen evolution results from an electrodeposition of cobalt-containing nanoparticles on

156 th metal, which acts as an electrode for the electrodeposition of conductive polymers, transforming t

157 face or a metal surface attack, for example, electrodeposition of conductors (metals) and non conduct

158 We describe the direct single potential electrodeposition of crystalline Cu2Sb, a promising anod

159 latform array was achieved by potentiostatic electrodeposition of Cu from an acidic copper solution i

160 Electrodeposition of Cu2Sb directly onto conducting subs

161 lic catalytic microrotors were fabricated by electrodeposition of cylindrical Au-Ru rods in the pores

162 and electrochemical characterization of the electrodeposition of different metals, we provide a comp

163 We report the electrodeposition of electrocatalytic clusters of platin

164 The controlled electrodeposition of functional polydopamine (PDA) thin

165 Direct electrodeposition of Ge from an aqueous solution is self

166 The direct electrodeposition of glucose oxidase (EC 1.1.3.4) on a p

167 bilization of glucose oxidase (GOx) and (ii) electrodeposition of gold dendrite-like nanostructures (

168 d to create a recessed nanopore, followed by electrodeposition of gold into the nanopore using either

169 onstruction of the aptasensor began with the electrodeposition of gold nanoparticles (AuNPs) onto a g

170 opyltriethoxysilane (APTES), and followed by electrodeposition of gold nanoparticles (GNPs).

171 erm stability of the sensors was achieved by electrodeposition of gold on the silver electrodes.

172 Electrodeposition of gold was performed to fill the rece

173 Here we demonstrate the successful electrodeposition of high-quality Si films from a CaCl2

174 Electrodeposition of high-surface-area platinum/iridium

175 The gel probe, which is fabricated by electrodeposition of hydrogel on a microdisk electrode,

176 Electrodeposition of lithium (Li) metal is critical for

177 hemical isotopic effect is observed upon the electrodeposition of lithium from solutions of propylene

178 We report on electrodeposition of lithium in simple liquid electrolyt

179 Dendrite-free electrodeposition of lithium metal is necessary for the

180 h high anchoring strengths can ensure smooth electrodeposition of lithium metal, thus paving the way

181 lectrolyte modulus is unnecessary for stable electrodeposition of lithium.

182 The electrodeposition of low surface area lithium is critica

183 ry (CV) at a gold substrate reveals that the electrodeposition of magnetite requires the preceding ad

184 lance (EQCN), we report a method for probing electrodeposition of metal oxide materials from molecula

185 ferent rates, as evidenced by studies on the electrodeposition of metallic silver, at potentials far

186 rochemical criteria for reversible epitaxial electrodeposition of metals are defined and their effect

187 ethodology is explored through the selective electrodeposition of Molybdenum (di)oxide (MoO(2)).

188 hese defects define nucleation sites for the electrodeposition of mushroom shaped platinum nanopartic

189 sted to resist fouling, both dip-coating and electrodeposition of Nafion are associated with substant

190 route to form anti-fouling steel surfaces by electrodeposition of nanoporous tungsten oxide (TO) film

191 Brush electrodeposition of Ni/PTFE composite coatings was expl

192 hape produced by the DNA template, while the electrodeposition of NiONPs on the bare GCE surface led

193 afion-MWCNTs/SPE) were prepared using pulsed electrodeposition of NiONPs on the MWCNTs/SPE surface.

194 thodology can also be applied to monitor the electrodeposition of other paramagnetic ions, such as Ni

195 n of microfabrication procedures followed by electrodeposition of palladium.

196 Electrodeposition of Pb and Bi results in the incipient

197 Devices fabricated by the electrodeposition of Pd directly across a 5 microm gap i

198 e water/1,2-dichloroethane interface and (2) electrodeposition of Pd nanoparticles at the water/1,2-d

199 The moderate thickness resulting from 25 s electrodeposition of PEDOT/GO produces the optimal elect

200 Electrodeposition of poly(3,4-ethylene dioxythiophene) (

201 Pulsed electrodeposition of polyaniline (PANI) allows the fabri

202 e on commercial polyimide films, followed by electrodeposition of pseudocapacitive materials on the i

203 reduced to 24 nm and 18 nm during subsequent electrodeposition of Pt and CuO.

204 As an illustrative example, we explore the electrodeposition of Pt at carbon-coated transmission el

205 voltammetric experiments, were fabricated by electrodeposition of Pt black inside an etched nanocavit

206 ed as a nanoscale molecular template for the electrodeposition of Pt-black, an amorphously nanopatter

207 followed by solvent evaporation and further electrodeposition of RuNPs (50 ppm RuCl(2) for 15 s at -

208 Electrodeposition of Si films from a Si-containing elect

209 In this work, selective electrodeposition of silver on quantum dots is described

210 ght allows in situ dynamic monitoring of the electrodeposition of single cobalt nanoparticles down to

211 ing with high spatial resolution and for the electrodeposition of single metal nanoparticles (e.g., P

212 crometer to nanometer gap experiments and in electrodeposition of single metal nanoparticles for elec

213 n-film catalyst was prepared by simultaneous electrodeposition of Sn(0) and SnO(x) on a Ti electrode.

214 glassy carbon electrode was modified with an electrodeposition of stearic acid/nanosilver composite a

215 d mesoporous platinum films, produced by the electrodeposition of the metal, in the simultaneous pres

216 ymer-bound osmium-complex: Cross-linking and electrodeposition of the redox polymer result when inner

217 alline homojunctions (NHJs) with single step electrodeposition of two copper-indium-selenide (CISe) c

218 For instance, during the electrodeposition of zinc on a copper substrate at a cur

219 The method is illustrated by cathodic electrodeposition of Zn(4)O(BDC)(3) (MOF-5; BDC = 1,4-be

220 grows specifically on the electrode surface, electrodeposition offers great promise as a readily scal

221 ds: Large roughness features were created by electrodeposition on copper meshes; Small roughness feat

222 gh a unique protocol, incorporating confined electrodeposition on lithographically patterned nanoelec

223 PDA micropatterns are then fabricated by electrodeposition on micrometer length scale gold electr

224 Here, we calibrate the system using Ag electrodeposition on Pt electrodes of gradually increasi

225 lfonate (PEDOT/PSS) which was synthesized by electrodeposition on the glassy carbon electrodes.

226 s performed in order to ensure Ppy-COOH/MNPs electrodeposition on the microelectrode surfaces.

227 lymerization on one set of electrodes and Pd electrodeposition on the other set behaved as "hydrogen

228 diimide crosslinker EDC followed by chitosan electrodeposition on the surface of carbon fiber microel

229 The kinetics of Li2 S electrodeposition onto carbon in lithium-sulfur batterie

230 Electrodeposition or electrochemical synthesis is an ide

231 of carbon fibers and subsequent coating with electrodeposition paint and a silicone elastomer.

232 ental scanning electron miscroscopy, and the electrodeposition pattern of lead and mercury was found

233 ing electron microscopy, and the microscopic electrodeposition patterns were found to influence the o

234 ical and chemical processes including pulsed electrodeposition (PED), plastic deformation, recrystall

235 For electrodepositions performed either at room temperature

236 nzymes were entrapped in Os-complex modified electrodeposition polymers (Os-EDPs) with specifically a

237 ormed on the glassy carbon electrode (GC) at electrodeposition potential of -0.75 V, as observed from

238 the electrode interrogate the time-dependent electrodeposition process by virtue of the XRF signals,

239 A self-terminating rapid electrodeposition process for controlled growth of plati

240 In this paper, we developed a facile electrodeposition process for creating a redox-active cr

241 A new electrodeposition process has been proven feasible with

242 directly from silicon dioxide via a one-step electrodeposition process in molten salt for possible ph

243 ng superhydrophobic coatings, using one-step electrodeposition process of nanosilica hybrid film and

244 The electrodeposition process was followed by the electroche

245 The electrodeposition process was further applied for the el

246 lk-distortion and anchoring strengths on the electrodeposition process.

247 cates/silicon oxide precursors by a two-step electrodeposition process.

248 itic deposits is a critical problem in metal electrodeposition processes and could occur in next-gene

249 Mg electrodeposition processes in two specific PEGylated-IL

250 ormity of coatings deposited in many general electrodeposition processes.

251 llinity, composition, and orientation of the electrodeposition products were characterized by using s

252 pared in large scale using a simple template electrodeposition protocol and offer considerable promis

253 We report an electrodeposition protocol for preparing isolated cobalt

254 were created using a kinetically controlled electrodeposition protocol on activated indium-tin oxide

255 er films using a unique pulse-potential step electrodeposition protocol, providing for nearly close-p

256 water solubility, and, for example, net gold electrodeposition rates are up to 22% larger at fouled t

257 nd perpendicular orientations showed similar electrodeposition rates, which is explained by the cyclo

258 electrochemical/chemical (EC) nature of the electrodeposition reaction is exploited to deposit the s

259 e reaction rate in comparison to the ex situ electrodeposition reaction was observed.

260 n this report, the effect of B on the copper electrodeposition reaction, measured by a low-field (0.2

261 monitor the Cu(2+) concentration during the electrodeposition reaction.

262 iation in the Cu(2+) concentration during an electrodeposition reaction.

263 ncover the critical parameters governing the electrodeposition stability of the metallic Zn electrode

264 ate onto the electrode surface during a 30 s electrodeposition step at -0.4 V vs Ag/AgCl from 0.1 M L

265 We describe here an electrodeposition strategy for preparing highly disperse

266 we report a oxygenates directionally induced electrodeposition strategy to construct high-entropy mat

267 CN solutions, providing a general and facile electrodeposition strategy, which streamlines catalyst s

268 Moreover, the underlying mechanism during electrodeposition/stripping is revealed using ab initio

269 rance, ion redistribution, electrocatalysts, electrodeposition substrates and so on.

270 in films has been carried out using cathodic electrodeposition technique at different cathodic potent

271 An electrodeposition technique is described that produces a

272 e RP microelectrodes, we used a sol-gel film electrodeposition technique to create ATP and hypoxanthi

273 polypyrrole (rGO@PPy) electrode via one-step electrodeposition technique.

274 sing an inexpensive binary-template-assisted electrodeposition technique.

275 s were fabricated using photolithography and electrodeposition techniques, and the faces of the plate

276 tant film was strongly dependent on both the electrodeposition temperature and dissolved concentratio

277 l, concentration of dissolved As(2)O(3), and electrodeposition temperature on the quality of the resu

278 For anodic electrodeposition, thin films can be formed using suppor

279 For cathodic electrodeposition, thin films can be formed using suppor

280 this paper we describe the use of templated electrodeposition through colloidal templates to produce

281 oscopy studies showed the great influence of electrodeposition time on surface coating, and high-reso

282 anic structures by templating strategies and electrodeposition to create materials relevant to energy

283 d conduction paths through the insulator and electrodeposition to form metal catalyst islands.

284 We used electrodeposition to further shrink the pores to effecti

285 We exploited electrodeposition to precisely immobilize carbon nanotub

286 Rough electrodeposition, uncontrolled parasitic side-reactions

287 on paste electrode (GNPs /MWCPE) by one-step electrodeposition under controlled potential, the whole

288 The antifouling surface was fabricated via electrodeposition using an equivalent mixture of 4-amino

289 Reversible Mg electrodeposition was achieved with high Coulombic effic

290 Pd electrodeposition was carried out under conditions favor

291 Electrodeposition was first employed for the direct immo

292 monitored continuously, and the directional electrodeposition was terminated when a current near tha

293 ors involved in achieving fine control of Li electrodeposition, we believe that achievement of the re

294 Through direct current electrodeposition, we fabricated vertical arrays of nano

295 Physical vapor deposition (PVD) and electrodeposition were used for thin film deposition.

296 anowires were grown using cyclic voltammetry electrodeposition, which proved to be a fast and environ

297 printed carbon electrode (SPCE), followed by electrodeposition with gold nanoparticles (AuNPs) and, f

298 relating the electrical charge dosage during electrodeposition with spectroscopic ellipsometry measur

299 ds the simplicity and control of traditional electrodeposition with the material quality of melt grow

300 ized rapidly and inexpensively by the direct electrodeposition within the conical pores of a polycarb