ライフサイエンスコーパス: electrochemistry

1 droplets, laminar flows in microfluidics or electrochemistry.

2 ient integration of the insulating MOFs into electrochemistry.

3 e.g., atmospheric chemistry, biophysics, and electrochemistry.

4 stretchable electronics, photoacoustics, and electrochemistry.

5 anometers, have been developed for nanoscale electrochemistry.

6 r the first time their quantitative scope in electrochemistry.

7 electrocatalytic properties are analyzed by electrochemistry.

8 ch yields direct spatial information on Li-S electrochemistry.

9 devoted to reuse and recycle in the field of electrochemistry.

10 on of biomolecular targets using nano-impact electrochemistry.

11 particle electrodes and their use in bipolar electrochemistry.

12 that are not accessible from single-particle electrochemistry.

13 terials that are now commonly used in modern electrochemistry.

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

15 of redox species to the solution via bipolar electrochemistry.

16 N-aromatic phosphoramidates were verified by electrochemistry.

17 on such nanoparticle electrodes via bipolar electrochemistry.

18 te-free Li deposition and reversible cathode electrochemistry.

19 owledge of the mechanisms that underlie H2O2 electrochemistry.

20 ding mechanistic evidence of strain-modified electrochemistry.

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

22 bundance, low cost, nontoxicity, and diverse electrochemistry.

23 microspectroscopy combined with protein film electrochemistry.

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

25 f hypervalent iodine mediators for synthetic electrochemistry.

26 yields and selectivity in synthetic organic electrochemistry.

27 s with their structural versatility and rich electrochemistry.

28 ighly valuable applications of single-entity electrochemistry.

29 tackle the challenging problem of interface electrochemistry.

30 years of engagement in the field of organic electrochemistry.

31 d as electrode materials for anion insertion electrochemistry.

32 polypeptides, and more generally on organic electrochemistry.

33 his new notion may be important for alkaline electrochemistry.

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

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

36 allowing dynamic insights unobservable using electrochemistry alone.

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

38 ction, investigated both using heterogeneous electrochemistry and by trapping intermediates in organi

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

40 ifferent properties, such as color emission, electrochemistry and chirality.

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

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

43 Direct electrochemistry and electrocatalysis of cytochrome c im

44 des a roadmap for next-generation studies in electrochemistry and electrocatalysis, advocating that c

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

46 robial electrochemistry merges microbiology, electrochemistry and electronics to provide a set of tec

47 Electrochemistry and exploiting electrochemical fingerpr

48 hat way, we propose a new approach involving electrochemistry and fluorescence techniques.

49 We discover, using a combination of electrochemistry and in situ probes of UV-vis absorption

50 The combination of electrochemistry and in situ spectroelectrochemistry tog

51 odes are systematically varied, we elucidate electrochemistry and mechanics of contactless actuation.

52 ens new opportunities intersecting fields of electrochemistry and mechanics.

53 n various carbon materials by direct protein electrochemistry and mediated one with redox mediators e

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

55 al discussion regarding the potassium-sulfur electrochemistry and on how it differs from the much bet

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

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

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

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

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

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

62 ficance in terms of both the fundamentals of electrochemistry and the rational design of catalysts fo

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

64 Supported by in situ Raman spectro-electrochemistry and theoretical modeling as well as con

65 The observed electrochemistry and UV-visible transitions are in good

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

67 ing electrode at its half-height for in situ electrochemistry, and a top open surface to inject solut

68 science combined with computational design, electrochemistry, and battery engineering, all to propel

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

70 We use a combination of spectroscopy, electrochemistry, and density functional theory (DFT) to

71 perties are studied by optical spectroscopy, electrochemistry, and density functional theory calculat

72 de a theoretical background of semiconductor electrochemistry, and describe the use of localised visi

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

74 Using native mass spectrometry, protein film electrochemistry, and electron paramagnetic resonance sp

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

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

77 paramagnetic resonance spectroscopy, protein electrochemistry, and mass spectrometry.

78 rest in material science, surface chemistry, electrochemistry, and other fields.

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

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

81 ects, with the support of mass spectrometry, electrochemistry, and single-crystal X-ray crystallograp

82 pheric and environmental chemistry, biology, electrochemistry, and solar energy conversion.

83 ic force microscopy (mC-AFM), spin-dependent electrochemistry, and spin Hall devices that measure the

84 TATBPs was studied by optical spectroscopy, electrochemistry, and X-ray diffraction.

85 We report an integrated electrochemistry approach to nanoparticle synthetic desi

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

87 Electrochemistry as a key technology ensures a safe and

88 Herein, we use nano impact electrochemistry as an additive-free method to overcome

89 lular and extracellular information in vivo, electrochemistry assessments, and optogenetic perturbati

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

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

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

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

94 energy storage devices, is the complexity of electrochemistry at the electrode-electrolyte interfaces

95 .g., intercalation of Li(+) in batteries and electrochemistry at the three-phase boundary in fuel cel

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

97 Comparing with classic DNA electrochemistry based mutation detection strategy, CRIS

98 (SGECM) is a novel technique measuring local electrochemistry based on a gel probe.

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

100 While electrochemistry-based DNA sensors reduce instrumental c

101 ed to enable researchers in areas related to electrochemistry, biochemistry or microfluidics to asses

102 Bipolar electrochemistry (BPE) is a powerful method based on the

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

104 , enhancing the sensitivity of droplet-based electrochemistry by 5 orders of magnitude.

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

106 d provide a framework for thinking about how electrochemistry can be uniquely applied to solving prob

107 ntal platform is introduced that builds upon electrochemistry capable of generating reactive intermed

108 Electrochemistry-capillary electrophoresis-mass spectrom

109 ues by changing the separation conditions in electrochemistry-capillary electrophoresis-ultraviolet-v

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

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

112 gold film electrode under fully operational electrochemistry conditions.

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

114 results provide insights into stress-lithium electrochemistry coupling at the nanoscale and suggest p

115 current density remains exsisting after 1000 electrochemistry cycles.

116 ing is a recurrent problem in graphene-based electrochemistry, decreasing the effective working area

117 allography, electron paramagnetic resonance, electrochemistry) demonstrates that the semiquinonate is

118 Electrochemistry, DFT calculations, and the study of a m

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

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

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

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

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

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

125 platforms sensing strategies (fluorescence, electrochemistry, electrochemiluminescence, and colorime

126 including a unique application of EC-ESI/MS (Electrochemistry/ElectroSpray Ionization Mass Spectromet

127 he most exciting interdisciplinary fields of electrochemistry, energy storage, materials chemistry, a

128 Reaction kinetics, thermodynamics, electrochemistry, EPR spectroscopy, and DFT calculations

129 nanoscale by exploiting their unique surface electrochemistry establishes an innovative analytical me

130 oundational understanding of anion insertion electrochemistry establishes LHs as a materials platform

131 The resulting electrochemistry establishes the basis for a remarkably

132 By combining electrochemistry experiments with molecular dynamics sim

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

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

135 ity between aqueous environments and quinone electrochemistry for carbon capture, eliminating the saf

136 strengths of intracellular biochemistry with electrochemistry for energy conversion and chemical synt

137 plant patients, was directly quantified with electrochemistry for the first time, with the assay rang

138 At highly biased potentials, electrochemistry grants access to silyl radicals through

139 Electrochemistry grants direct access to reactive interm

140 Here, we introduce new electrochemistry hardware that considerably suppresses n

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

142 Silicon electrochemistry has the potential to advance sustainabl

143 on methods based on photoredox catalysis and electrochemistry have joined approaches which utilize th

144 nanopipets (CNPs) for studying permselective electrochemistry in a conductive nanopore.

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

146 This work demonstrates the power of electrochemistry in accessing new chemical space and pro

147 ME), one can study single-particle collision electrochemistry in acid concentrations as high as 3 M o

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

149 ns exploit the exquisite control afforded by electrochemistry in contrast with classical approaches o

150 ssion and other interfering mechanisms using electrochemistry in general not only in the drug detecti

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

152 In contrast to the rapid growth of synthetic electrochemistry in recent years, enantioselective catal

153 We report the application of electrochemistry in the analysis of carotenoids.

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

155 Traditionally, electrochemistry in the presence of significant external

156 t the nature and reactivity of Pd/Au surface electrochemistry including the adsorbed/absorbed hydroge

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

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

159 uch layered oxide can be further improved by electrochemistry-induced activation.

160 ost are further revisited by elaborating the electrochemistry, intercalant effect, and intercalation

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

162 Flow electrochemistry is an efficient methodology to generate

163 Electrochemistry is another branch of science that can c

164 (dry) battery based on reversible superoxide electrochemistry is presented.

165 Bipolar electrochemistry is receiving growing attention in the l

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

167 Ferricyanide electrochemistry is totally inhibited on graphite electr

168 ntiometric sensor (LAPS) and light-activated electrochemistry (LAE) for addressable photoelectrochemi

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

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

171 Coupling with electrochemistry, LSPR results indicated good integrity

172 of physical phenomena, including catalysis, electrochemistry, lubrication, and crystal growth.

173 Electrochemistry makes it possible to avoid using O(2) a

174 y mass spectrometric data can be obtained by electrochemistry-mass spectrometry but also further char

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

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

177 Microbial electrochemistry merges microbiology, electrochemistry a

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

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

180 exemplary system, the presented correlative electrochemistry-microscopy approach is generally applic

181 Modulated light-activated electrochemistry (MLAE) at semiconductor/liquid interfac

182 n, we introduce a microfluidic redox-neutral electrochemistry (muRN-eChem) platform that has broad ap

183 Many applications in modern electrochemistry, notably electrosynthesis and energy st

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

185 This sheds new light on electrochemistry of alpha-amino acids, on occurrence of

186 Electrochemistry of carotenoids has attracted a lot of i

187 tion technique for explosives, the (spectro-)electrochemistry of compounds from two major nonaromatic

188 Direct electrochemistry of cytochrome P450 containing systems h

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

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

191 The electrochemistry of flavone (1) has been carefully inves

192 The electrochemistry of graphene and its derivatives has bee

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

194 unity stoichiometries as can be found in the electrochemistry of halides, hydrogen, and metal complex

195 This experiment allows one to observe the electrochemistry of hundreds to thousands of molecules t

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

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

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

202 here are fundamental questions regarding the electrochemistry of S-based cathode and of K metal anode

203 rizes recent achievements in the molten salt electrochemistry of silicon, highlighting subjects of te

204 Expansion of PSDs would alter electrochemistry of synapses, thereby contributing to a

205 The solution electrochemistry of the bimetallic complex shows four st

206 all voltage measurements, and spin-dependent electrochemistry of the decaheme cytochromes MtrF and Om

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

208 ns at the electrode surface during the redox electrochemistry of the quinone.

209 The electrochemistry of these films is markedly different fr

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

211 Electrochemistry offers a convenient alternative for met

212 Electrochemistry offers opportunities to promote single-

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

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

215 ysis of field-effect-controlled outer-sphere electrochemistry on ultrathin back-gated ZnO working ele

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

217 nspirational insights on nanocavity-enhanced electrochemistry, opening new routes for biochemical det

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

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

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

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

222 e spectroscopy (EIS) is a versatile tool for electrochemistry, particularly when applied locally to r

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

224 netic CD (MCD) spectroscopy and protein film electrochemistry (PFE) in a study to resolve heme ligati

225 -state solution kinetic assays, protein film electrochemistry (PFE), and pre-steady-state stopped-flo

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

227 ions is expected to fundamentally affect the electrochemistry, phase behavior and morphology of elect

228 Oxygen electrochemistry plays a key role in renewable energy te

229 Classical electrochemistry problem of polarization of an electrode

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

231 n a manner that spans nanoscale electronics, electrochemistry, redox switching, and derived nanoscale

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

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

234 (XEC) of alkyl and aryl halides promoted by electrochemistry represents an attractive alternative to

235 Electrochemistry represents one of the most intimate way

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

237 c circuitry is often overlooked by microbial electrochemistry researchers.

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

239 We also harness electrochemistry's unique feature of precise potential c

240 Herein, we apply the single-entity electrochemistry (SEE) to directly and quantitatively me

241 eport a new application of the single-entity electrochemistry (SEE) to in situ measure a partition co

242 nt electrochemical activity by single-entity electrochemistry (SEE).

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

244 ns using cyclic voltammetry and hydrodynamic electrochemistry show that the presence of a cationic an

245 view discusses advances in synthetic organic electrochemistry since 2000.

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

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

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

249 Catalysts for aprotic electrochemistry such as lithium-sulfur (Li-S) batteries

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

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

252 concept of asymmetrical alternating current electrochemistry that achieves high degrees of contamina

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

254 on of carbon black particles based on impact electrochemistry that was capable of selective detection

255 By means of spin-dependent electrochemistry, the CISS effect is demonstrated by cyc

256 the current renaissance of synthetic organic electrochemistry, the heterogeneous and space-dependent

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

258 ll-encompassing mechanism, including surface electrochemistry, their solution and interfacial phases,

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

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

261 hat we report here demonstrates the power of electrochemistry to access highly reactive intermediates

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

263 oscience, there is growing interest in using electrochemistry to create nanostructured materials and

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

265 d site-directed mutagenesis and protein film electrochemistry to determine how efficient catalysis de

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

267 ed monolayer on a gold surface and then used electrochemistry to monitor its guanidine denaturation a

268 We report the use of electrochemistry to perform a direct oxidative dearomati

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

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

271 Using this strategy, we leverage electrochemistry to seamlessly combine two canonical rad

272 this report, we further expand the scope of electrochemistry to the reductive functionalization of a

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

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

275 een put into understanding its formation and electrochemistry under realistic battery conditions, but

276 y a variety of analytical methods, including electrochemistry, UV-vis absorption and resonance Raman

277 ace was examined at the nanoscale by quantum electrochemistry via the effective screening medium meth

278 Electrochemistry was combined with SERS for dual-modalit

279 In tandem with the biological assays, electrochemistry was employed to determine the real-time

280 Also, electrochemistry was involved in an innovative way to in

281 Using DNA electrochemistry, we find that binding of the DNA polyan

282 Moreover, using DNA electrochemistry, we find that the cluster coordinated b

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

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

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

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

287 Fluorescence microscopy and electrochemistry were employed to examine capping agent

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

289 give rise to highly robust and reproducible electrochemistry, whereas volatile (low boiling point) s

290 ates in-depth mechanistic insights employing electrochemistry, which suggests a stepwise one proton t

291 on concentration have a dominant role on the electrochemistry, while mechanics is mainly affected by

292 roelectrodes (UMEs) were characterized using electrochemistry with correlated microscopy.

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

294 rol of the composition of beta-Fe(1+x) Se by electrochemistry with simultaneous tracking of the assoc

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

296 as a materials platform for anion insertion electrochemistry with the potential for future applicati

297 work we show that merging the sensitivity of electrochemistry with the user-friendliness of an optica

298 Prospectively, employing MOFs in electrochemistry would notably broaden the scope of elec

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

300 The layers were fully characterized using electrochemistry, XPS, and AFM, and switching between op