ライフサイエンスコーパス: redox reaction

1 amine layers were confirmed by the increased redox reaction.

2 eaction or a cumulative cationic and anionic redox reaction.

3 ion of quasicrystals under shock without any redox reaction.

4 taining EC product was found to catalyze the redox reaction.

5 the alkynoate partner undergoes an internal redox reaction.

6 Fe(3+) cations are reconstructed without any redox reaction.

7 of the EDL that abruptly changes due to the redox reaction.

8 e are required to maximize the yield of this redox reaction.

9 a cheap alternative for this intramolecular redox reaction.

10 ies of the compounds on each half of the LDH redox reaction.

11 europium metal, and a melt of imidazole in a redox reaction.

12 ayered-to-spinel phase transition and oxygen redox reaction.

13 cal capacity, high working voltage, and fast redox reaction.

14 t the holding potential and the irreversible redox reaction.

15 evelopment of materials based on the anionic redox reaction.

16 nd environmental applications exploiting the redox reactions.

17 ly relevant processes that typically involve redox reactions.

18 d acid production from respiration and other redox reactions.

19 ations at Cu2O/Cu interfaces as they undergo redox reactions.

20 intercalation process, inspired by Li2 MnO3 redox reactions.

21 lectronic transition via fast and reversible redox reactions.

22 les, and offer rich active sites for surface redox reactions.

23 allic domains to accept charges and catalyze redox reactions.

24 ore charge in excess of the transition metal redox reactions.

25 e exposed to the electrolyte and involved in redox reactions.

26 insoluble lithium sulfides through multistep redox reactions.

27 an generate reaction equivalents for driving redox reactions.

28 acilitate lithium ion storage via reversible redox reactions.

29 istic manner, thereby lowering the energy of redox reactions.

30 ecially with regard to biologically mediated redox reactions.

31 promising as improved catalysts for various redox reactions.

32 ial energy production, glycolysis, and other redox reactions.

33 dical (Y(*)) that is vital to many catalytic redox reactions.

34 ater interface (MWI), including sorption and redox reactions.

35 activities for outer-sphere and inner-sphere redox reactions.

36 undamental for environmental geochemistry of redox reactions.

37 l metabolite participating in core metabolic redox reactions.

38 n also act in concert to mediate a series of redox reactions.

39 transport and electronic conduction for fast redox reactions.

40 catalyse a number of important multielectron redox reactions.

41 ionship between crystallographic defects and redox reactions.

42 exes represent critical intermediates of the redox reactions.

43 mational changes to facilitate multielectron redox reactions.

44 ite of the enzyme, includes the pH-dependent redox reactions, accounts for the effect of the proton-m

45 oreductases mediate electron transfer (i.e., redox) reactions across the tree of life and ultimately

46 m the lower diffusion process of ions during redox reaction after prion interaction due to bulk effec

47 Moreover, we show that controlled redox reactions allow for interconversion of these DNA-e

48 o redox-MHD, density gradients caused by the redox reactions also play important roles.

49 tal data for both a simple fast one electron redox reaction and an electron transfer with a following

50 l stability, electronic conduction, vanadium redox reaction and lithium-ion diffusion supported by va

51 es an effective platform for elucidating the redox reaction and oxygen diffusion within transition me

52 , because it alters the driving force of the redox reaction and thus electron transfer kinetics, sign

53 through particle bombardment and interfacial redox reaction and vacancy annihilation through oxidatio

54 ed organic matter (DOM) affects mercury (Hg) redox reactions and anaerobic microbial methylation in t

55 proteins catalyse a diversity of fundamental redox reactions and are one of the most studied enzyme f

56 erials, in contrast, operate by fast surface redox reactions and are shown to enhance energy storage

57 Coenzymes of cellular redox reactions and cellular energy mediate biochemical

58 to produce compounds that can participate in redox reactions and energy production.

59 a result of density gradients caused by the redox reactions and follow convection flow patterns.

60 ironmental conditions, it can participate in redox reactions and influence the sorption processes at

61 , rapid clogging is caused by mixing-induced redox reactions and is exacerbated by microbial activity

62 denine dinucleotide (NAD(+)) participates in redox reactions and NAD(+)-dependent signaling pathways.

63 ee radicals that may play a role in observed redox reactions and ROS generation.

64 ducting black SnO2-x , which homogenizes the redox reactions and stabilizes fine, fracture-resistant

65 ed mechanistic support for proposed cysteine redox reactions and suggested novel redox mechanisms, in

66 ation influences both the rate of cytochrome redox reactions and the balance between the reduced and

67 ) to establish proton involvement in protein redox reactions and the identity of PT sites.

68 her layered compounds can be intercalated by redox reactions and then converted chemically to suspens

69 hree orthogonal stimuli (metal coordination, redox reaction, and guest binding) is reported.

70 new insights for natural biotic and abiotic redox reactions, and explained the dominance of todoroki

71 eliminateion of nitric oxide (NO) via facile redox reactions, and the elimination dynamics was evalua

72 Protein motions control the rates of heme redox reactions, and these effects are amplified at low

73 the kinetics and electron flux of the cyclic redox reaction are key to the layer-to-tunnel structure

74 However, the compounds observed in metabolic redox reactions are a minuscule fraction of chemical spa

75 ution Cu(y)Fe(1-y)F(2), reversible Cu and Fe redox reactions are achieved with surprisingly small hys

76 Typically, cationic redox reactions are believed to dominate the electrochem

77 lso irreversible/reversible anionic/cationic redox reactions are comprehensively assigned via the com

78 Although the redox reactions are critical for efficient mitochondrial

79 ic reagents and discrete alcohol-to-carbonyl redox reactions are not required.

80 d anions are involved in the electrochemical redox reaction, are one of the most promising candidates

81 ated with surface or near-surface reversible redox reactions, as observed with RuO2.xH2O in an acidic

82 thodes for lithium batteries store charge in redox reactions associated with the transition metal cat

83 The observed surface-confined redox reaction at both CNT and N-CNT electrodes is from

84 rylamide) (GN) polymers were synthesized via redox reactions at 20-50 degrees C.

85 an electron from other substrates to mediate redox reactions at ambient temperature with high atom ef

86 Redox reactions at iron mineral surfaces play an importa

87 time, a mechanistic study for catecholamine redox reactions at LSGE as the electron transfer-chemica

88 Redox reactions at metal oxide (MO(x)) surfaces are impl

89 The improvement mostly stems from robust redox reactions at nitrogen-associated defects that tran

90 dentifying molecules that undergo reversible redox reactions at the extreme potentials required to le

91 The redox reactions at the heart of anammox are catalyzed by

92 trical and chemical potential energy through redox reactions at the interfaces between the electrodes

93 nitored by the change in current of the AgNF redox reaction before and after hybridization using cycl

94 in the increase of ferrous ions through the redox reaction between AA and IONCs.

95 we elucidate the mechanism of this important redox reaction between amines and benzoyl peroxide for t

96 The reversible non-volatile redox reaction between metal and metal oxide may provide

97 The method was based on a redox reaction between the I3(-) and SO3(2-) ions, after

98 xidation of Si is subsequently governed by a redox reaction between the ions and Si.

99 radical was examined as the analogue of the redox reaction between the PSII tyrosyl radical and the

100 ed gold electrode, which is modulated by the redox reaction between uric acid and hexacyanoferrate io

101 Interfacial redox reactions between adsorbed Mn(II) and solid-phase

102 Redox reactions between CeO2 NPs and Fe2+ lead to the fo

103 No evidence was found for redox reactions between Fe(II) and As(V) or As(III), or

104 es and between microbes and molecules, local redox reactions between molecules, and hydrolysis.

105 chanism of quenching, which occurred through redox reactions between the 11-MUA-Au NDs and the Fe(II)

106 s, but minor secondary products from coupled redox reactions between the products and reactants are a

107 n(II) often coexists with Mn(IV) oxides, and redox reactions between the two (e.g., comproportionatio

108 to the rates and extents of complexation and redox reactions between these important and complex envi

109 fficient charge separation and decoupling of redox reactions, bio-inspired artificial systems typical

110 pyridyl complexes can engage in photoinduced redox reactions but by a mechanism that is fundamentally

111 lfulvenes increases the reversibility of the redox reactions, but does not appear to further stabiliz

112 ffer sustainable alternatives to traditional redox reactions, but strategies are needed to enhance th

113 mportant role in heterogeneous catalysis and redox reactions, but their buried nature makes them diff

114 was able to detect NPY without performing a redox reaction by adsorption at the surface of the micro

115 SEED quantitatively maps the local redox reaction by scanning a laser on the array of enzym

116 ctivities of I(-)/I(3)(-) and S(2-)/S(x)(2-) redox reactions by improving absorptivity of charged ion

117 resent in these complexes can participate in redox reactions by toggling between different oxidation

118 Under laminar flow conditions, a redox reaction can be driven on the upstream generator e

119 ional entropy change of the Fe(CN)(6)(3-/4-) redox reaction can be used as the basis for a compact el

120 These redox reactions can affect the toxicity of CeO2 NPs by i

121 We tested the hypothesis that Y122OH redox reactions cause structural changes in the diferric

122 he observed electroactivity is from FAD, the redox reaction center of GOx.

123 The redox-reaction changes the magnetic susceptibility of th

124 e strategies involving thiols and associated redox reactions; comparisons to a model diatom, Thalassi

125 nd F radicals produced by this unprecedented redox reaction could be exploited as electrodes, light-e

126 phologies of manganese oxides, which undergo redox reactions coupled to sodium ion uptake and release

127 The extent and efficiency of the redox reactions depend on the oxidation state (Fe(2+)/Fe

128 For redox reactions, deuterium tracing can provide additiona

129 an important role in cancer cells mediating redox reactions, DNA replication, and telomere maintenan

130 in operando spectromicroscopy to verify that redox reactions drive the resistance change.

131 de iodine(V) complexes are unreactive toward redox reactions due to the fact that in such cases two e

132 functions in coagulation, inflammation, and redox reactions due to their unique protein cargo.

133 d formation has typically been attributed to redox reactions during precipitation from fluids or magm

134 e transitions involve a one- or two-electron redox reaction, each being thermodynamically constrained

135 trigger an intense interest in catalysis of redox reactions-electrochemical and photochemical-partic

136 In liquid cell TEM/STEM redox reaction experiments, the hydrated electrons e(-)a

137 piration and photosynthesis based on quinone redox reactions face a danger of wasteful energy dissipa

138 The method is based on the redox-reaction [Fe(CN)(6)](3-)/[Fe(CN)(6)](4-) performed

139 f the binding sites thereby facilitating the redox reaction for the detection of capsaicin.

140 effects and facilitate electron transfer and redox reactions for achieving high capacity, rate capabi

141 ed so far rely heavily upon transition-metal redox reactions for lithium transfer.

142 les, the crystallographic orientation-guided redox reaction governs the charge distribution in the lo

143 or histamine detection, the mechanism of its redox reaction has not been directly investigated.

144 can be broken and oxygen loss and/or oxygen redox reactions have been proposed to explain the phenom

145 In the vascular system, redox reactions help regulate key physiologic responses

146 a stepwise combination of disproportionation redox reactions, hydrazine reduction, or carbonyl decomp

147 able of further participating in homeostatic redox reactions (i.e., redox-deficient).

148 l chemistry in vivo Investigating biological redox reactions, I identified hydrogen peroxide (H(2)O(2

149 provide additional contribution of Faradaic redox reaction in supercapacity performance, leading to

150 The overall rate of the redox reaction in the micromodel required a three-domain

151 alcohol-derived ester, via an NHC-catalyzed redox reaction in the presence of beta-substituted vinyl

152 ty of cognate enzymes that are essential for redox reactions in all three domains of life.

153 ics-based electrochemical current imaging of redox reactions in aqueous droplets with diameters varyi

154 ution can potentially promote and homogenize redox reactions in battery materials.

155 dislocations, are reported to influence the redox reactions in battery particles through single-part

156 ive molecules, which catalyse a multitude of redox reactions in biological systems.

157 ubiquinone designed to reversibly report on redox reactions in biological systems.

158 ocesses that ultimately form the backbone of redox reactions in both anaerobic and aerobic respiratio

159 s utilized by numerous enzymes that catalyze redox reactions in carbon, nitrogen, and sulfur metaboli

160 the potential of utilizing reversible oxygen redox reactions in conventional layered oxides for high-

161 rode materials by manipulating the effective redox reactions in electrode materials for rechargeable

162 onds has potential for tuning multi-electron redox reactions in emerging energy-storage applications,

163 probe and studied the thermodynamics of its redox reactions in heterogeneous iron systems, namely go

164 indicating that dislocations may facilitate redox reactions in layered oxides during initial chargin

165 w unambiguous evidence of reversible anionic redox reactions in LiNi(1/3) Co(1/3) Mn(1/3) O(2) .

166 oorganisms and enhanced activity towards the redox reactions in microorganisms by Fe(3)C nanoparticle

167 gands to facilitate solid-state ligand-based redox reactions in nonporous coordination solids, giving

168 spectrometer is extremely powerful to study redox reactions in real time and identify unstable react

169 fide (DMTS) as a model compound to study its redox reactions in rechargeable lithium batteries.

170 w and dissolved Mn(II) on manganese-mediated redox reactions in saturated porous media.

171 Fast, reversible redox reactions in solids at low temperatures without th

172 e properties, electronic/ionic transport, or redox reactions in SRZAB upon various stimulations and e

173 ng oxidoreductases and potentially catalyzed redox reactions in the Archean oceans.

174 netic modeling of bidirectional two-electron-redox reactions in the case of molecular catalysts and e

175 patic artery of rats selectively deregulated redox reactions in tumor tissues by increasing levels of

176 TO) where ITO undergoes reduction-oxidation (redox) reaction in the presence of electrolyte in most s

177 rticles (NPs), a better understanding of the redox reaction-induced surface property changes of CeO2

178 This redox reaction inhibits the MEF2C-PGC1alpha transcriptio

179 ancillary ligand design, (2) employing mild redox reactions instead of harsh photochemical methods t

180 ol (SH)/disulfide (SS) exchange or other non-redox reactions/interactions by introducing kansui, whic

181 ts of PM species and properties on catalytic redox reactions into one measurement, and current work h

182 The redox reactions involve reduction of FeO and SiO2 to Fe

183 The O redox reaction involves the formation of localized hole

184 Understanding the extent and kinetics of redox reactions involving Fe-bearing clay minerals has b

185 Here we investigate the rate equation of redox reactions involving reduction by e(-)aq generated

186 Biologically catalysed redox reactions involving sulfate, sulfide and intermedi

187 rectification is due to the SAM, and not to redox reactions involving the Ga2O3 film, and confirms t

188 enetically encoded sensors that function via redox reactions involving thiol and disulfide groups.

189 nce spectra provide evidence that the Y122OH redox reaction is associated with a frequency change to

190 A redox reaction is conducted on a polymer film on a rotat

191 This redox reaction is deactivated in water, as the reducing

192 tability of iron-bound organic carbon in the redox reaction is limited.

193 n complex I at which energy generated by the redox reaction is used to initiate proton translocation.

194 The use of anion redox reactions is gaining interest for increasing recha

195 donors, the formal potential of the quinone redox reactions is tuned into the potential region in wh

196 al conductance switching allows the study of redox reaction kinetics and thermodynamics at single mol

197 lectrical connection is required to activate redox reactions, large arrays of electrodes can be contr

198 omplex, [Ni(Me4[12]aneN4)(CO)]PF6, effects a redox reaction leading to the diselenido dinickel(II) co

199 nine dinucleotide (NAD(+)) is a coenzyme for redox reactions, making it central to energy metabolism.

200 The redox reaction maxima, R(max) and Delta(max) from SEED-R

201 Partial(7,8) or exclusive(9) anionic redox reactions may achieve higher capacity, but at the

202 A redox reaction mechanism has also been established, wher

203 Through a fundamental understanding of the redox reaction mechanism in Li2 MnO3 , Na(Li1/3 Mn2/3 )O

204 ation, structural evolution, electrochemical redox, reaction mechanism, kinetics, and degradation.

205 s and ligands has raised the question of how redox reactions might affect ligand-controlled (hydr)oxi

206 n be extracted from biomass directly and its redox reaction mimics the bio-electrochemical process of

207 Using the anionic redox reaction (O(2-) /O(-) ), this Mn-oxide is predicte

208 logical systems as catalysts to catalyze the redox reactions occurring at an electrode.

209 imensional interplay among coupled catalytic redox reactions occurring in an EBFC-based sensor and pr

210 l electrochemical method to mimic the cyclic redox reactions occurring over long geological time scal

211 stream collector electrode where the reverse redox reaction occurs.

212 metric effect of accumulated Fe(III) against redox reaction of a suitable probe.

213 The redox reaction of complex I is catalyzed in the hydrophi

214 However, the redox reaction of Cu(2)O is still uncertain.

215 By cyclic voltammetry, the redox reaction of ferrocenemethanol was shown to take pl

216 s electron transfer rate constant (k(s)) for redox reaction of GOx were found to be 0.48 and 1.12 s(-

217 ectrode is utilized to electrically couple a redox reaction of interest to a complementary fluorogeni

218 tionally, we studied the effect of pH on the redox reaction of paracetamol at the both electrodes in

219 current of 2.60 x 10(-4) mA cm(-2) , a rapid redox reaction of polysulfide, and therefore improved su

220 veral models being studied for the efficient redox reaction of reactants with silicon through a metal

221 The redox reaction of RFN is a pH-dependent process that req

222 determine the time-constant connected to the redox reaction of the adsorbed protein assembly.

223 n kinetics, oscillating growth behavior, and redox reaction of the Cu(2)O nanocubes in the liquid pha

224 PhC(NtBu)(2)], has been synthesized from the redox reaction of the dipotassium bis(silylenyl)-nido-ca

225 nd show that the frequency dependence of the redox reaction of the protein submonolayer follows as ex

226 owed a voltammetric signal due to a one-step redox reaction of the surface-confined myoglobin, in a d

227 using concentrated solar energy mediated by redox reactions of a metal oxide.

228 sfer significantly as a result of reversible redox reactions of H2Q/Q.

229 The combination of ion intercalation with redox reactions of iodine allows for developing recharge

230 while the porous carbon skeleton facilitates redox reactions of iodine and ion intercalation.

231 Redox reactions of oxygen have been considered critical

232 of ROS in the epithelial lining fluid due to redox reactions of PM components with lung antioxidants.

233 ited by poor electrochemical kinetics of the redox reactions of polysulfide/iodide ions on graphite e

234 precedented microscopic detail regarding the redox reactions of supported oxides, which differs funda

235 Redox reactions of the chromophore methylene blue in aqu

236 dating the catalytic mechanism of this multi-redox reaction on metal-oxide photoanodes remains a sign

237 ion transport but stops further electrolyte redox reactions on the electrode surface, hence solid el

238 sing nanoscale chemical reactors for surface redox reactions on the subnanometer scale.

239 previous compounds involve a single cationic redox reaction or a cumulative cationic and anionic redo

240 o reaction pathways, either by photo-induced redox reaction or hydrolysis reaction, which are respons

241 ibility that the electron transfer is due to redox reactions or pi-stacking.

242 used to provide surface sites for selective redox reactions, or for storing information by doping sp

243 An optical method of mapping local redox reaction over a monolith electrode using simple la

244 Coenzymes of redox reactions: oxidized/reduced nicotinamide adenine d

245 e spectroscopic techniques: a three-electron redox reaction per coordination unit and one-electron re

246 ction per coordination unit and one-electron redox reaction per copper ion mechanism is demonstrated.

247 ductase (DMSOR) family catalyse two-electron redox reactions pivotal to the dissimilatory metabolism

248 Microbe-mediated arsenic (As) redox reactions play an important role in the biogeochem

249 n the emerging role of a specific reversible redox reaction, protein methionine oxidation, in vascula

250 rent energy of 32.5 kJ/mol, showing that the redox reaction rate is approximately 10(15) times slower

251 howed significant spatial variation in local redox reaction rate that was controlled by the coupled t

252 te that the temperature dependence of native redox reaction rates can be well described by the therma

253 lly high efficiency on piezoelectrocatalytic redox reactions rather than in the piezocatalytic proces

254 ify the energetics of the cysteine disulfide redox-reaction (reversible potentials for both processes

255 completely mapped the enzymatic sequence of redox reactions starting from the nonadride 5.

256 The rates and extent of these redox reactions strongly depend on the speciation of the

257 t performance for high-temperature catalytic redox reactions such as water splitting.

258 materials depends on the efficiency of this redox reaction, such that damage can be inhibited by alt

259 t that in photosynthetic organisms, specific redox reactions sustain dark metabolism, with little imp

260 gested the presence of a novel cone-specific redox reaction that generates 11-cis-retinal from 11-cis

261 t a mechanism comprising a coupled acid-base/redox reaction that leads to a proton-induced disproport

262 inked the donor to the acceptor in a coupled redox reaction that released protons into the vesicle in

263 Photoinduced and native redox reactions that contributed to the photobleaching r

264 ticular the LSPR absorption, with reversible redox reactions that do not affect the semiconductor che

265 d chemically in the electrode via reversible redox reactions that involve multiple oxidation states o

266 hloroplasts is controlled by light-dependent redox reactions that target specific enzymes.

267 functions by catalyzing oxidation-reduction (redox) reactions that are out of equilibrium.

268 trahydrofuran (THF) furnishes smoothly, in a redox reaction, the (bisNHC)(Br)Al[Fe(CO)4] complex 3, i

269 acity of this bacterium to perform difficult redox reactions, thereby multiplying its value as a plat

270 sence of DNA and can participate directly in redox reactions through DNA.

271 s)(18)] into the CV treated polymer promotes redox reactions through generation of alternative electr

272 gnal by electrically coupling a conventional redox reaction to a fluorogenic reporter reaction on a c

273 argest estuary.The potential contribution of redox reactions to acidification in coastal waters is un

274 carbon has yet to be coupled with extrinsic redox reactions to develop rechargeable batteries.

275 bifurcation uses free energy from exergonic redox reactions to power endergonic reactions.

276 is, in which solar photons are used to drive redox reactions to produce chemical fuel, is the central

277 veal the molecular design principles linking redox reactions to quinone turnover to proton translocat

278 Dehydration, carbonyl cleavage, and redox reactions turned out to have a large impact on the

279 the role that vitamin K plays in biological redox reactions ubiquitous in key cellular processes, an

280 ry cathode materials have relied on cationic redox reactions until the recent discovery of anionic re

281 Often the proteins in question catalyze redox reactions using metal cofactors that are explicitl

282 When redox reactions were carried out during lactide polymeri

283 antibodies, and DNA, by blocking a solution redox reaction when molecules adsorb and block electrode

284 catalysis by ceria in both hydrogenation and redox reactions where hydrogen is involved.

285 allows the 2e(-)/2H(+) quinone/hydroquinone redox reactions while suppressing proton reduction in th

286 We show that the peptide undergoes a redox reaction with copper ions resulting in a disulfide

287 d in copper(I) sulfide (Cu2 S) NCs through a redox reaction with iodine molecules (I2 ), which formed

288 This study investigates the impact of redox reactions with ferrous ions (Fe2+) on the colloida

289 to serve as a general materials platform for redox reactions with nanomaterials at high temperatures.

290 charge-transfer excited states that undergo redox reactions with one or more halogen species are det

291 uatic environments, where it participates in redox reactions with surrounding metals, organic compoun

292 terized methylene blue (MB)- and thiol-based redox reactions with the aim of designing an oxygen scav

293 ial (piezopotential) effectively facilitates redox reactions with the free carriers in MoS(2) .

294 s exhibiting a surface-controlled reversible redox reaction, with a fast heterogeneous electron trans

295 terized are involved in oxidation-reduction (redox) reactions, with the Sec residue located at their

296 rode simultaneously and to examine the local redox reactions within a droplet.

297 These findings provide evidence that redox reactions within beta-oxidation and the electron t

298 Cytochrome b6f catalyzes quinone redox reactions within photosynthetic membranes to gener

299 hate in the mitochondria by participating in redox reactions within the electron transport chain.

300 It is less clear, however, how redox reactions would contribute to acidification.