ライフサイエンスコーパス: electrochemistry

1 on of biomolecular targets using nano-impact electrochemistry.

2 microspectroscopy combined with protein film electrochemistry.

3 by X-ray analysis, UV/vis spectroscopy, and electrochemistry.

4 be this key solid-liquid interface region of electrochemistry.

5 particle electrodes and their use in bipolar electrochemistry.

6 ls that have been difficult to establish via electrochemistry.

7 d variable-temperature MCD, and protein-film electrochemistry.

8 that are not accessible from single-particle electrochemistry.

9 H3PO4) as an electrolyte for self-organizing electrochemistry.

10 e granting positive exposure to ionic liquid electrochemistry.

11 a novel combination of molecular biology and electrochemistry.

12 tion of hydrogen as recorded by protein film electrochemistry.

13 trically modified with bismuth using bipolar electrochemistry.

14 stry and appreciable voltages for sodium-ion electrochemistry.

15 mental science, heterogeneous catalysis, and electrochemistry.

16 ectrospray ionization mass spectrometry, and electrochemistry.

17 xygen reduction reaction (ORR) using bipolar electrochemistry.

18 terials that are now commonly used in modern electrochemistry.

19 by the solvent in conventional liquid-phase electrochemistry.

20 potential were determined by the interfacial electrochemistry.

21 rocesses, which is the subject of endohedral electrochemistry.

22 ectrospray ionization mass spectrometry, and electrochemistry.

23 fluorescence microscopy in combination with electrochemistry.

24 dohedral metallofullerenes and in endohedral electrochemistry.

25 ne of the major challenges in materials- and electrochemistry.

26 of redox species to the solution via bipolar electrochemistry.

27 N-aromatic phosphoramidates were verified by electrochemistry.

28 on such nanoparticle electrodes via bipolar electrochemistry.

29 owledge of the mechanisms that underlie H2O2 electrochemistry.

30 ding mechanistic evidence of strain-modified electrochemistry.

31 plex Mg(PF6)2(CH3CN)6 and its solution-state electrochemistry.

32 inker structure were further investigated by electrochemistry, absorption measurements, and EFISH exp

33 tionalized surface was characterized by XPS, electrochemistry, AFM, and STM.

34 allowing dynamic insights unobservable using electrochemistry alone.

35 e function of [S3] (-) in materials science, electrochemistry, analytical chemistry and geochemistry

36 elds of synthesis and catalysis, extraction, electrochemistry, analytics, biotechnology, etc.

37 DTBs exhibit reversible cathodic electrochemistry and boron-centered Lewis acidity in add

38 ted modified materials were characterized by electrochemistry and by X-ray photoelectron spectroscopy

39 While both the electrochemistry and defects of this material have been

40 the interfacial tension via a combination of electrochemistry and electrocapillarity.

41 Direct electrochemistry and electrocatalysis of cytochrome c im

42 hesis, computational analysis, photophysics, electrochemistry and electrochemiluminescence (ECL) of a

43 The electrochemistry and electrogenerated chemiluminescence

44 Electrochemistry and fluorescence imaging tools have bee

45 experimental techniques, that is, kinetics, electrochemistry and high resolution mass spectrometry (

46 ular catalyst [Ni(cyclam)](2+) is studied by electrochemistry and infrared spectroelectrochemistry.

47 Based on the combination of electrochemistry and LSPR measurement, the electrochemic

48 hesis, dissolution and extraction processes, electrochemistry and material chemistry.

49 ens new opportunities intersecting fields of electrochemistry and mechanics.

50 cations of chemical C-H oxidation reactions, electrochemistry and microfluidic technologies to drug t

51 the whole field of the intersection between electrochemistry and ordered mesoporous materials.

52 he role of residual lithium carbonate in the electrochemistry and outgassing of lithium transition-me

53 understanding of potassium plating/stripping electrochemistry and paves the way for the development o

54 razide ligand plays an important role in the electrochemistry and photophysics of the complexes.

55 plications, are at the forefront of bridging electrochemistry and polymer (physics), which have also

56 First of all, fundamental electrochemistry and related ionic/electronic conduction

57 ction of O2 to H2O (detected using ring disk electrochemistry and rotating ring disk electrochemistry

58 Electrochemistry and scanning/transmission electron micr

59 We employed infrared spectro-electrochemistry and site-selective isotope editing to m

60 phenomena can be revealed by the synergy of electrochemistry and SM-SERS, which explores in this cas

61 scopic methods (UV-vis-NIR, UPS, pulse EPR), electrochemistry and spectroelectrochemistry, magnetic m

62 tion of the platform allows one to carry out electrochemistry and spectroscopy individually or simult

63 Yet, probing local electrochemistry and surface structure at complex surfac

64 r that this approach bridges the gap between electrochemistry and the traditional tools used in polym

65 ption and circular dichroism spectroscopies, electrochemistry and theoretical calculations are shown

66 A combination of high-pressure electrochemistry and variable-temperature UV-vis spectro

67 to energy research, heterogeneous catalysis, electrochemistry, and atmospheric and environmental scie

68 ious detection modes including colorimetric, electrochemistry, and chemoluminescent regarding the det

69 hydroxylamines were characterized using NMR, electrochemistry, and density functional theory.

70 used together with steady-state absorption, electrochemistry, and DFT calculations, indicates that t

71 In this work, the basic photophysics, electrochemistry, and electrogenerated chemiluminescence

72 crystallographically, and also by NMR, EPR, electrochemistry, and electronic spectra.

73 y ionization mass and UV-vis spectroscopies, electrochemistry, and isothermal titration calorimetry e

74 Additionally, steady-state photolysis, electrochemistry, and laser time-resolved spectroscopic

75 nment, such as temperature, light intensity, electrochemistry, and mechanical force.

76 applications to PCET in solution, proteins, electrochemistry, and photoinduced processes are present

77 Absorption spectra, electrochemistry, and single crystal structures of the t

78 ed by variable-temperature NMR spectroscopy, electrochemistry, and single crystal X-ray diffraction.

79 graphene, and nanotubes) are used widely in electrochemistry, and there is a long-standing view that

80 ctrolytes for superionic Li(+) conduction in electrochemistry applications.

81 on microbeads remotely addressed via bipolar electrochemistry, are implemented as a powerful tool for

82 Electrochemistry as a key technology ensures a safe and

83 led, paving the way for the use of localized electrochemistry as a route to controlled diazonium modi

84 In this review, we present the progress of electrochemistry as a valuable tool in construction of n

85 controllability of boron-doped diamond (BDD) electrochemistry as an easily accessible tool for produc

86 These complexes display unique pH-dependent electrochemistry associated with deprotonation of the ph

87 e report field-effect modulation of solution electrochemistry at 5 nm thick ZnO working electrodes pr

88 Single-particle electrochemistry at a nanoelectrode is explored by dark-

89 Unlike conventional electrochemistry at a single electrode, however, the mas

90 Electrochemistry at individual metal nanoparticles (NPs)

91 During the last decade protein electrochemistry at miniaturized electrodes has become i

92 EI in solid-state redox systems and reactive electrochemistry at precisely defined conditions.

93 phite, but have significant implications for electrochemistry at related carbon materials such as gra

94 rodes exhibit highly spatially heterogeneous electrochemistry at the nanoscale, both within secondary

95 utions is demonstrated with a combination of electrochemistry, atomic force microscopy (AFM), and sur

96 net involved in the function of these direct electrochemistry based enzyme electrodes, their characte

97 Targeted electrochemistry based metabolomic platform (LCECA) was

98 f efficient biosensors following this direct electrochemistry based principle are discussed.

99 We use an electrochemistry-based model (ECBE) here to measure the

100 We applied an electrochemistry-based, targeted metabolomics platform t

101 Electrochemistry, biosensors and microfluidics are popul

102 e the basic concepts and recent histories of electrochemistry, biosensors, and microfluidics, and des

103 If the samples are exposed to air prior to electrochemistry, both ORR and carbon oxidation signals

104 Bipolar electrochemistry (BPE) is nowadays well-known but relati

105 h generally accepted conclusions in platinum electrochemistry but also offer important insights on va

106 ferrocenemethanol, a compound widely used in electrochemistry but scarcely studied by spectroelectroc

107 Here, we demonstrate how bipolar electrochemistry can be exploited to evaluate the effici

108 dation and reduction chemistry, and the role electrochemistry can play as a sustainable method for th

109 or a wide variety of applications, including electrochemistry, catalysis, and as models of biological

110 be widely applicable in fields as diverse as electrochemistry, catalysis, and bioenergetics.

111 dvances of SMSERS and TERS in fields such as electrochemistry, catalysis, and SM electronics, which a

112 in the confines of a thin-layer FTIR spectro-electrochemistry cell provides evidence for a unpreceden

113 cytochrome (MtrF) has been resolved and its electrochemistry characterized.

114 ere also successfully evaluated in a dynamic electrochemistry (chronopotentiometry) sensing mode for

115 described here combines classical aspects of electrochemistry, colloidal science, material science, f

116 gold film electrode under fully operational electrochemistry conditions.

117 X-ray photoelectron spectroscopy and electrochemistry confirm catalyst immobilization.

118 X-ray photoelectron spectroscopy and electrochemistry confirm catalyst immobilization.

119 Rotating disk electrochemistry coupled to resonance Raman spectroscopy

120 current density remains exsisting after 1000 electrochemistry cycles.

121 onance Raman spectroscopy coupled to dynamic electrochemistry data suggests the formation of a bridgi

122 e has been achieved in understanding surface electrochemistry due to the profound knowledge of the na

123 tremendous research interest in the field of electrochemistry due to their intrinsic properties, incl

124 cient supply of substrate as in protein film electrochemistry during spectral acquisition.

125 The role of electrochemistry (EC) in the ionization process was addr

126 solving this critical issue via integrating electrochemistry (EC) online with a top-down MS approach

127 In this study we have applied electrochemistry (EC) to overcome disulfide bridge compl

128 gg white lysozyme, in which one biotinylated electrochemistry (EC)-cleaved peptide was identified aft

129 In online electrochemistry (EC)/LS DESI MS, when 0 V was applied t

130 r of applications (including photocatalysis, electrochemistry, electronics and optoelectronics, among

131 Finally, bipolar electrochemistry enables mobile electrodes, dubbed micro

132 The resulting electrochemistry establishes the basis for a remarkably

133 As a conventional technique, electrochemistry exhibits its unique advantage on machin

134 Protein film electrochemistry experiments on Hyd-3 demonstrate that i

135 By combining electrochemistry experiments with molecular dynamics sim

136 archers working in the photoluminescence and electrochemistry fields who are interested in exploring

137 techniques such as kinetic rotating droplet electrochemistry, fluorescence polarization, isothermal

138 eport demonstrates the successful use of BDD electrochemistry for greater precision in generating a t

139 ectric, semiconductor, molecular orbital and electrochemistry frameworks.

140 The role of pyridinium cations in electrochemistry has been believed known for decades, an

141 less GOx biosensor developed based on direct electrochemistry has exhibited an impressive analytical

142 this work, we explore generation-collection electrochemistry in a rotating droplet hydrodynamic syst

143 is sufficiently stable to exhibit reversible electrochemistry in aqueous solution.

144 ophilic environment, by using solution phase electrochemistry in DMSO solutions of Fe(III)-heme plus

145 rk demonstrates a new capability of studying electrochemistry in microdroplets, which offers an oppor

146 ed on new and more comprehensive work on FeS electrochemistry in model and anoxic Lake Pavin samples,

147 characterized by surface spectroscopies and electrochemistry in organic and aqueous solvents.

148 Fenton reaction, thus widening the scope of electrochemistry in protein and peptide chemistry and an

149 Chemistry in flames: Dynamic electrochemistry in the gas phase is described by consid

150 The ability to perform electrochemistry in the presence of large voltages and e

151 Traditionally, electrochemistry in the presence of significant external

152 arious mechanistic features of the pertinent electrochemistry (including stepwise versus concerted ca

153 ) has attractive properties for conventional electrochemistry, including low background current and s

154 pens up new opportunities in single molecule electrochemistry, including the use of ionic liquids, as

155 This will enable reliable dynamic electrochemistry investigations into redox reactions at

156 e reference electrode material for gas phase electrochemistry investigations.

157 shows that combining fluorescence CLSM with electrochemistry is a powerful tool to study electrochem

158 Flow electrochemistry is an efficient methodology to generate

159 Electrochemistry is an interfacial technique which is do

160 Electrochemistry is another branch of science that can c

161 Direct electrochemistry is potentially very useful for learning

162 Bipolar electrochemistry is receiving growing attention in the l

163 The SAM redox electrochemistry is sensitive to the surfactant aggregat

164 Unmet potential: Electrochemistry is the most simple and basic way of alt

165 Ferricyanide electrochemistry is totally inhibited on graphite electr

166 raise the possibility that MMOSI effects in electrochemistry-largely neglected in the past-may be mo

167 lly low electronic conductivity and unstable electrochemistry lead to poor cycling stability and infe

168 Coupling with electrochemistry, LSPR results indicated good integrity

169 we overview fundamental concepts of Graphene Electrochemistry, making electrochemical characterisatio

170 tively little research has been conducted on electrochemistry mediated by plasmon excitations.

171 le molecule detection, analytical chemistry, electrochemistry, medical diagnostics and bio-sensing.

172 This dynamic electrochemistry methodology gives information on the la

173 impedimetric assays) compared to traditional electrochemistry methods in general hence demonstrating

174 , electrochemical impedance spectroscopy and electrochemistry methods such as cyclic voltammetry (CV)

175 erized by UV-vis absorption spectroscopy and electrochemistry, modeled using density functional theor

176 plications involving assays of fluorescence, electrochemistry, nano-label and nano-constructs are dis

177 n in a wide variety of disciplines including electrochemistry, neurobiology, and behavioral psycholog

178 The electrochemistry of a ferro/ferricyanide probe was used

179 e electron transfer rate associated with the electrochemistry of a redox active film tethered to meta

180 Here, the adsorption and electrochemistry of anthraquinone-2,6-disulfonate (AQDS)

181 First, the macroscopic electrochemistry of AQDS is studied on a range of surfac

182 The electrochemistry of bisphenol A (BPA) was studied by vol

183 ed that has no comparable counterpart in the electrochemistry of bulk gold electrodes.

184 The direct and catalyzed electrochemistry of CO(2) partake in the contemporary at

185 Direct electrochemistry of cytochrome P450 containing systems h

186 affect both the interfacial state of DNA and electrochemistry of DNA-conjugated redox labels and, as

187 We report here the electrochemistry of emulsion droplets by observing singl

188 ng furthermore permits the comparison of the electrochemistry of EndoIII mutants, including a new fam

189 Direct electrochemistry of glucose oxidase (GOD) was achieved w

190 Direct electrochemistry of glucose oxidase (GOx) at an electroc

191 e ERGO-MWCNT hybrid film, as a result direct electrochemistry of GOx has been achieved.

192 The direct electrochemistry of GOx was revealed at the RGO-GOx modi

193 The electrochemistry of graphene and its derivatives has bee

194 We also discuss the electrochemistry of graphene grown by chemical vapour de

195 aluated as a new material for probing direct electrochemistry of hemoglobin (Hb).

196 In this study, the electrochemistry of I(-), I2, and ICl has been investiga

197 Our present work not only enriches the electrochemistry of layered intercalation compounds, but

198 In this work, we investigate the electrochemistry of lithium sulfide films ranging in thi

199 nneling will have a measurable impact on the electrochemistry of M-I-MNP systems.

200 ng, and this binding allows the DNA-mediated electrochemistry of MB intercalated into the duplex and,

201 mposite was prepared and attained the direct electrochemistry of Mb with pair of well-defined redox p

202 ew covers the challenges and advances in the electrochemistry of MCOs and their use in EBFCs with a p

203 s/myoglobin (RGO-MWCNT-Pt/Mb) for the direct electrochemistry of myoglobin and its application toward

204 c activity on the size of the nanoparticles, electrochemistry of nanoparticles, surface restructuring

205 ed platform to perform mediator-free, direct electrochemistry of non-engineered cytochromes P450 unde

206 The electrochemistry of several p-phenylenediamine derivativ

207 The chemistry and electrochemistry of TCNQ (7,7,8,8-tetracyanoquinodimetha

208 The solution electrochemistry of the bimetallic complex shows four st

209 Electrochemistry of the diamine is carried out to explor

210 The direct electrochemistry of the enzymatic electrocatalyst on NiO

211 Inspired by the fundamental electrochemistry of the lithium-ion battery, we envision

212 The electrochemistry of the radical species 2,2-diphenyl-1-p

213 The electrochemistry of these films is markedly different fr

214 n performed to gain further insight into the electrochemistry of Ti(IV)/Ti(III) and Ti(III)/Ti(II) re

215 ered a favorable microenvironment for direct electrochemistry of xanthine oxidase (XOD).

216 The electrochemistry of ZnO:N thin film based electrode is i

217 Electrochemistry offers a convenient alternative for met

218 Electrochemistry offers a simple approach to metal detec

219 wn that the application of a bias voltage in electrochemistry offers an additional parameter to promo

220 iOH implies a different active iodine/oxygen electrochemistry on battery charge.

221 at is specific to Mtb with gold nanoparticle electrochemistry on disposable screen printed carbon ele

222 ped ZnSe) have allowed the influence of trap electrochemistry on nanocrystal photoluminescence to be

223 Using FTIR spectro-electrochemistry on the [FeFe] hydrogenase from Chlamydo

224 oth heterobimetallic structures display rich electrochemistry, only the trinuclear Au-Ni-Au complex f

225 R activity, combining in situ UV-vis spectro-electrochemistry, operando electrochemical mass spectrom

226 of complexity that can be revealed from such electrochemistry/optics coupling.

227 as crystal growth, heterogeneous catalysis, electrochemistry, or biological function.

228 ve been achieved by using transition metals, electrochemistry, or O2 to regenerate the oxidized quino

229 y thought to be limited for room-temperature electrochemistry, our results demonstrate that nanoparti

230 The advantages of electrochemistry over radioactivity and fluorescence mak

231 and UV irradiation, atomic layer deposition, electrochemistry, oxidation, reduction, hydrolysis, the

232 ts electrocatalytic activity in protein film electrochemistry (PFE) experiments, is merely to exhibit

233 Protein film electrochemistry (PFE) has been used to study the assemb

234 bauer spectroscopies as well as protein-film electrochemistry (PFE).

235 The electrochemistry, photoluminescence and electrogenerated

236 Oxygen electrochemistry plays a key role in renewable energy te

237 Ox (pI 4.3) on the anode operating on direct electrochemistry principle.

238 Electrochemistry provides a noninvasive method for probi

239 Electrochemistry provides a powerful tool for the late-s

240 s allowing single mode (electrophysiology or electrochemistry) recording.

241 inting methods along with a review of recent electrochemistry related studies adopting 3D-printing as

242 carbon composite electrodes have substandard electrochemistry relative to metallic and glassy carbon

243 Electrochemistry represents one of the most intimate way

244 quartz-crystal nanobalance has been used in electrochemistry research for over three decades.

245 The development of microbial electrochemistry research toward technological applicati

246 Moreover, protein film electrochemistry reveals that targeted manipulation of t

247 his mechanistic explanation for the observed electrochemistry seems unlikely in light of recent quant

248 Using a closed bipolar electrochemistry setup, all important parameters such as

249 While electrochemistry shows promise, it is limited by its tem

250 DNA-modified electrochemistry shows that the 4Fe-4S cluster of DNA-bo

251 view discusses advances in synthetic organic electrochemistry since 2000.

252 Here, we combine electrochemistry, site-directed mutagenesis, molecular d

253 rrocene units have been investigated through electrochemistry, spectroelectrochemistry, density funct

254 We report here the electrochemistry, spectroscopy, and electrogenerated che

255 The electrochemistry, spectroscopy, and electrogenerated che

256 d pressure-dependent (17)O NMR spectroscopy, electrochemistry, stopped-flow kinetic analyses, and EPR

257 Single-molecule (SM) electrochemistry studied by surface-enhanced Raman scatt

258 is spectroscopy, spectroscopic ellipsometry, electrochemistry, synchrotron X-ray reflectivity, angle-

259 atteries, starting from an overview of their electrochemistry, technical challenges and potential sol

260 Fast-scan cyclic voltammetry (FSCV) is an electrochemistry technique which allows subsecond detect

261 y, energy-dispersive X-ray spectroscopy, and electrochemistry techniques.

262 Here we report protein film electrochemistry that defines the reduction potential of

263 individual parts of the hydrogen and oxygen electrochemistry that govern the efficiency of water-bas

264 a combination of redox titration and protein electrochemistry that in contrast to hitherto characteri

265 imilar to Marcus relaxation processes in wet electrochemistry, the thermal broadening of the Fermi di

266 l applications in Lewis acidic catalysis and electrochemistry through to uses as soft and component m

267 materials can remarkably promote the oxygen electrochemistry, thus boosting the entire clean energy

268 f techniques, including catalysis screening, electrochemistry, time-resolved spectroscopy, and comput

269 sed analytical device (hyPAD), uses faradaic electrochemistry to create an ion depletion zone (IDZ),

270 s in infection screening approaches that use electrochemistry to detect molecular biomarkers for dist

271 re characterized by optical spectroscopy and electrochemistry to gain an understanding of the factors

272 This is the first study to use electrochemistry to generate a nitro reduction metabolit

273 behaviors of the particles were examined in electrochemistry to investigate strain effects arising f

274 Using direct electrochemistry to learn about the mechanism of electro

275 s method couples fluorescence microscopy and electrochemistry to localize and size electro-active def

276 ance (LSPR) sensor was developed by coupling electrochemistry to LSPR spectroscopy measurement on the

277 face property in various fields ranging from electrochemistry to pharmaceuticals.

278 rein demonstrates the potential of utilizing electrochemistry to provide a complementary avenue to ac

279 Clues provided by electrochemistry to understand these enzymes and how the

280 ights into both theoretical and experimental electrochemistry toward a better understanding of a seri

281 a novel cross-linking MS in conjunction with electrochemistry using disulfide-bond-containing dithiob

282 s a means of studying fundamental aspects of electrochemistry using the attoliter oil droplet and off

283 Using these reporters DNA electrochemistry was shown to be both DNA-mediated and i

284 Using DNA electrochemistry, we found that a change in oxidation st

285 raction, molecular dynamics simulations, and electrochemistry, we present evidence for two population

286 Using protein film electrochemistry, we show that formate oxidation by EcFD

287 Using protein film electrochemistry, we show that two [4Fe-4S] clusters adj

288 Fluorescence microscopy and electrochemistry were employed to examine capping agent

289 disk electrochemistry and rotating ring disk electrochemistry), when imidazole is bound to the heme (

290 ceives considerable interest is the field of electrochemistry, where graphene has been reported to be

291 mine antibiotics, is examined through direct electrochemistry, where the potential of both its AdoMet

292 Protein film electrochemistry, which probes the dependence of steady-

293 n diffusion) is a long-standing challenge in electrochemistry with applications in desalination and e

294 bling reversible potassium plating/stripping electrochemistry with high efficiency ( approximately 99

295 This approach, combining dynamic electrochemistry with resonance Raman spectroscopy, may

296 Recent advances in electrochemistry with special references to proteomics a

297 is applied in a wireless mode using bipolar electrochemistry with the actual electrode potentials be

298 In this work, we combined analytical electrochemistry with trace analytics to assess the cata

299 al spectroscopy, NMR and EPR spectroscopies, electrochemistry, X-ray absorption spectroscopy, and qua

300 igated by UV-vis, NMR, and ESR spectroscopy, electrochemistry, X-ray diffraction analysis, and theore