ライフサイエンスコーパス: electrolyte

1 pproximately 0.8M) acetic acid as background electrolyte).

2 t between the lithium metal anode and garnet electrolyte.

3 oxidation to be performed without supporting electrolyte.

4 Ir/C catalyst for an air cathode in alkaline electrolyte.

5 ctrode surface and corroborated with a mixed electrolyte.

6 plied between the device and the surrounding electrolyte.

7 present the first sputtered SiO2 solid-state electrolyte.

8 pacity of 1.2 mAh/cm(2) in a carbonate-based electrolyte.

9 separated from the superconcentrated aqueous electrolyte.

10 the redox catalyst as well as the supporting electrolyte.

11 it a very promising air cathode in alkaline electrolyte.

12 e and anode in a "water-in-salt" gel polymer electrolyte.

13 stability of the "water-in-salt" gel polymer electrolyte.

14 ORR activity after 10 h running) in alkaline electrolyte.

15 rode, using 0.30molL(-1) H2SO4 as supporting electrolyte.

16 etermined with different quaternary ammonium electrolytes.

17 olid polymer electrolyte, and organic-liquid electrolytes.

18 e optimization of new high-performance solid electrolytes.

19 not favorable in high-voltage window aprotic electrolytes.

20 he highest values yet observed for MOF solid electrolytes.

21 raightforwardly to more complex multispecies electrolytes.

22 cycling stability or performance in aprotic electrolytes.

23 d morphology scenarios for different battery electrolytes.

24 ional pores, giving rise to single-ion solid electrolytes.

25 phosphate) polymerized ionic liquid (polyIL) electrolytes.

26 ids is critical for the use of the latter as electrolytes.

27 erial crossover, and corrosive and hazardous electrolytes.

28 anism and chemical inertness towards aqueous electrolytes.

29 rone, renal function, cardiac variables, and electrolytes.

30 output (up to 10 mA/cm(2)) even in carbonate electrolytes.

31 windows, usually no more than 1 V in aqueous electrolytes.

32 igh OER activity in both alkaline and acidic electrolytes.

33 e distinct for CaCl2 compared with the other electrolytes.

34 d wind power by storing the energy in liquid electrolytes.

35 ocused on the active electrode materials and electrolytes.

36 tinct SEI nanostructures formed in different electrolytes.

37 By removing O2 in electrolyte, a dramatic decrease in Tafel slope of over

38 fusion-limited conditions in slightly acidic electrolytes: a model system to study the relative trans

39 al ventilation and intensive care unit stay, electrolyte abnormalities and repletion doses, duration

40 erious adverse events (hypotension, syncope, electrolyte abnormalities, bradycardia, or acute kidney

41 care unit stay, and inotrope use; and fewer electrolyte abnormalities.

42 IQR, 4-8] vs 4.0 [IQR, 3-6] days) and higher electrolyte abnormality scores (median, 6 [IQR, 4-7] vs

43 In this work we explore how an electrolyte additive (fluorinated ethylene carbonate - F

44 rein, we report that nanodiamonds work as an electrolyte additive to co-deposit with lithium ions and

45 e authors show that nanodiamonds serve as an electrolyte additive to co-deposit with lithium metal an

46 LZT) to increase the stability of the garnet electrolyte against moist air; the garnet LLZT-2 wt % Li

47 ant inverse barocaloric effects in the solid electrolyte AgI, near its superionic phase transition at

48 ructure and the properties of common organic electrolytes, along with their effects on the LSB perfor

49 The InGaZnO TFTs with the optimised SiO2 electrolyte also showed good air stability.

50 Chemical instability of liquid electrolytes also leads to premature cell failure as a r

51 anti-perovskite Li3OCl is a promising solid electrolyte, although there is debate concerning the pre

52 samples are exposed to an excess of aqueous electrolyte, an increase in the amount of carboxylate bo

53 king cell with a lithium metal anode, garnet electrolyte and a high-voltage cathode by applying the n

54 ystal electrolyte interphase between a solid electrolyte and a solid cathode may be extended to other

55 lid interfacial impedance between the garnet electrolyte and electrode materials.

56 on reaction is known to be a function of the electrolyte and electrode; however, electrodes modified

57 Aldosterone regulates electrolyte and fluid homeostasis through binding to the

58 thelial anion channel and a key regulator of electrolyte and fluid homeostasis.

59 The selection of the electrolyte and its functionality during charging and di

60 ing on the interfacial resistance of a solid electrolyte and Li metal anode.

61 ystal electrolyte interphase between a solid electrolyte and solid cathode particles reduces the inte

62 mV at 10 mA cm(-2) is attained in an acidic electrolyte and stable for over 30 h, which is the best

63 onal electron-transfer processes between the electrolyte and the GCE thereby improving the sensing pe

64 One barrel of the probe is filled with electrolyte and the molecules of interest and is open to

65 s the metal against parasitic reactions with electrolyte and, for fundamental reasons, inhibits dendr

66 ed contact between the semiconductor and the electrolyte and, most remarkably, preferential electrica

67 osition of inner ear fluid and regulation of electrolytes and acid-base homeostasis in the collecting

68 The influence of electrolytes and aqueous pH on colloidal stability of th

69 rogeneous interfaces between photoabsorbers, electrolytes and catalysts present in photoelectrochemic

70 the foremost research in the development of electrolytes and cathodes and discuss some of the signif

71 Throughout NEVKP, electrolytes and pH values were maintained.

72 dings, plasma markers of refeeding syndrome (electrolytes and phosphate), and acute phase reactants,

73 imizes the corrosion reaction with carbonate electrolytes and suppresses dendrite formation, enabling

74 selective measurement of sweat metabolites, electrolytes and temperature was achieved using a flexib

75 ry that relies on the immiscibility of redox electrolytes and where vanadium is replaced by organic m

76 al evolutions (induced by the addition of an electrolyte) and thus showcasing the potential of this n

77 al resistance with Li metal, a solid polymer electrolyte, and organic-liquid electrolytes.

78 ode framework, Gd:CeO2 -Li/Na2 CO3 composite electrolyte, and Sm0.5 Sr0.5 CoO3 cathode demonstrates e

79 ng an electrode in a desired Li- or Na-based electrolyte, and that ionic transport can be kinetically

80 died as solvents, cosolvents, cosurfactants, electrolytes, and adjuvants, as well as used in the crea

81 The development of electrolytes, anodes and cathodes as well as fuel source

82 Replacing pure water by electrolyte aqueous solutions enables to increase the st

83 in 1.0 m LiClO4 dissolved dimethyl sulfoxide electrolyte are reported.

84 ing in the standard ethylene carbonate-based electrolyte are suppressed in the presence of 10 vol% FE

85 and superior mechanical properties of solid electrolytes are both of critical significance for these

86 rior to the liquid electrolytes, solid-state electrolytes are considered able to inhibit problematic

87 Ion-ion interactions in supercapacitor (SC) electrolytes are considered to have significant influenc

88 Solid electrolytes are generating considerable interest for al

89 ith this device only little or no supporting electrolytes are needed, making processes less costly an

90 us and high ionic transference number, solid electrolytes are promising candidates to address both th

91 model system, which is exposed to an aqueous electrolyte, are conducted.

92 g cycle life; a Li-S cell with the LLZT-2LiF electrolyte as a separator, which blocks the polysulfide

93 s of a PPy-GOx film grown, in the absence of electrolyte, as an inner layer, and a permselective PPy-

94 on pathway of sulfur cathode in MgTFSI2 -DME electrolyte, as well as the associated kinetics are thor

95 barocaloric effects in a wide range of solid electrolytes, as well as the parallel development of coo

96 electrode and oxidize in bromide-containing electrolyte at 0.698, 0.757, and 0.943 V (vs Ag/AgCl) fo

97 Using MD simulations, we model the electrolytes at a negatively-charged amorphous silica su

98 oly(ethylene oxide)(PEO)-based solid polymer electrolytes at low temperatures, and thus the solid pol

99 s in ion transport, maintenance of water and electrolyte balance, and clearance of bacteria from the

100 0.2Mn0.2O2 cell assembled with solid polymer electrolyte based on cross-linked PEEC delivered a high

101 these materials utilizing highly fluorinated electrolytes based on a HFE solvent.

102 Our results show that chemically orthogonal electrolytes based on HFE solvents do not dissolve organ

103 high dielectric-fluidity factor, the use of electrolytes based on solvent systems that exclusively u

104 tion and a second electrode placed in a bulk electrolyte bath, to provide information on a substrate

105 inherent to the widely adopted liquid-phase electrolyte batteries.

106 a potential of 3 kV and a background running electrolyte (BGE) consisting of 10 mmol L(-1) N-cyclohex

107 the microchip by adding it to the background electrolyte (BGE) instead of the sample-thus eliminating

108 n polyphenol separation of pH and background electrolyte, BGE (borax, acetonitrile, methanol and SDS

109 poly(ethylene oxide)-like linear oligomeric electrolyte breakdown products that are observed after c

110 eaction products were detected in the liquid electrolyte by IR spectroscopy, and the effect of variat

111 ractions between photo-oxidized dyes and the electrolyte can impact device photovoltages.

112 The nanodiamond-modified electrolyte can lead to a stable cycling of lithium | li

113 ng catalysis interfaces between catalyst and electrolyte can provide valuable insights into catalytic

114 salt concentrations, which demonstrates that electrolytes can induce aggregation of strongly charged

115 uids (ILs) are a specific class of molecular electrolytes characterized by the total absence of co-so

116 n batteries have seen little change in their electrolyte chemistry since their commercialization, whi

117 We probe the influence of electrolyte composition and concentration on the adsorpt

118 udied along with surface charge at different electrolyte composition and effective pore size to eluci

119 sDNA bound to SSB was found to depend on the electrolyte concentration but not on the presence of the

120 ncy, we investigated the effect of cis/trans electrolyte concentration gradients applied over alpha-h

121 how silica wettability may be manipulated by electrolyte concentration.

122 However, at higher electrolyte concentrations the interactions are stiffer,

123 For zero or low NaCl electrolyte concentrations, interfacial repulsions are s

124 The electrolyte consists of a proton donor and acceptor slur

125 ates to address both the dendrite-growth and electrolyte-consumption problems inherent to the widely

126 echnology utilizing a newly designed cathode electrolyte containing a highly water-soluble ferrocene

127 amino acids one method utilizes a background electrolyte containing gamma-cyclodextrin and sodium tau

128 additives and were often based on metal-ion electrolytes containing Li(+) or Na(+).

129 our platform, we detected the elevated sweat electrolyte content of cystic fibrosis patients compared

130 deficit of total body water relative to body electrolyte content, are common and ascertained by plasm

131 low temperatures, and thus the solid polymer electrolyte could be successfully employed at the room t

132 An optimized metal-catalyst-electrolyte couple needs to be sought that aids LiOH oxi

133 Computer simulation of an electrolyte current density was used to investigate seve

134 th this design, we can obtain a higher total electrolyte current.

135 he TMO-like spinel phase also alleviates the electrolyte decomposition during electrochemical cycling

136 V vs Li/Li(+) on the first charge, carbonate electrolyte degradation negligibly contributes to gas ev

137 xygen flows through the woven mesh while the electrolyte diffuses along the textile fibers.

138 teries is the need to photopattern the solid electrolyte directly on electrodes.

139 perkalemia is a potentially life-threatening electrolyte disorder appreciated with greater frequency

140 ct (CCD) is highlighted by various water and electrolyte disorders that arise when the unique transpo

141 cope, 43 400 (95% CI, 39 400-47 500) serious electrolyte disorders, and 88 700 (95% CI, 80 400-97 000

142 jor complications including volume overload, electrolyte disorders, uremic complications, and drug to

143 related to the underlying illness, including electrolyte disturbances.

144 able Mg/S battery with a MgTFSI2 /MgCl2 /DME electrolyte (DME=1,2-dimethoxyethane, TFSI=bis(trifluoro

145 LIC and can avoid the excessive depletion of electrolyte during the charge process.

146 gly three times more than that with stagnant electrolytes during a 25-hour period of photocharge.

147 tively measure metabolite (e.g. lactate) and electrolytes (e.g. pH, sodium) together with temperature

148 Although structural and electrolyte effects have been separately studied, there

149 ynamic formation of interphases at the solid electrolyte/electrode interface.

150 Usual 24-hour urinary electrolyte excretion (sodium, potassium, and their rati

151 d with industrially established cathodes and electrolytes exhibit long cycle life (up to 3,000 cycles

152 Garnet-structured solid-state electrolyte exhibits great promise for SSLiBs owing to i

153 Ionic current measurements through electrolyte-filled nanopores can characterize single nat

154 eport a hydrofluoroether (HFE) solvent-based electrolyte for electrochemical processing and character

155 bacterial cells were suspended in the spacer electrolyte for injection.

156 an additive in the standard carbonate-based electrolyte for Li-ion batteries, the solid electrolyte

157 eview, the fundamental properties of organic electrolytes for LSBs are presented, and an attempt is m

158 ydrophilic analytes from background biofluid electrolytes for quantiatve mass spectrometric analysis.

159 In the search for novel solid electrolytes for solid-state batteries, thiophosphate io

160 oslufonyl)imide (KFSI)-dimethoxyethane (DME) electrolyte forms a uniform SEI on the surface of potass

161 ions form an electrode-free, dielectric- or electrolyte-free, bias-free vapor-phase top-gate that ca

162 This solid-state electrolyte gate insulator enables remarkable field-effe

163 Herein a label-free immunosensor based on electrolyte-gated organic field-effect transistor (EGOFE

164 us bisphenol A (BPA) immunoassay based on an electrolyte-gated organic field-effect transistor whose

165 The phase-changing electrolyte gel provides a pervading biocompatible inter

166 ode modified with a droplet of a gel-polymer electrolyte (GPE) was immersed directly into samples of

167 We observe that dendrites in carbonate-based electrolytes grow along the <111> (preferred), <110>, or

168 valuate the effect that multivalency of this electrolyte has on the stability and antimicrobial activ

169 m anodes, graphite cathodes and ionic liquid electrolytes has increased; however, much remains to be

170 licated procedure for the preparation of the electrolytes has significantly compromised the benefits

171 Garnet-type solid-state electrolytes have attracted extensive attention due to t

172 w-potential RAOs in a variety of non-aqueous electrolytes, highlighting the versatility of macromolec

173 With-no-lysine kinase 4 (WNK4) regulates electrolyte homeostasis and blood pressure.

174 n important role in the integration of water/electrolyte homeostasis and thermoregulation, but we hav

175 e identity of the alkali metal cation in the electrolyte; however, a satisfactory explanation for thi

176 operable on metallic Cu electrodes in acidic electrolytes: (i) electrocatalytic hydrogenation (ECH) a

177 , gastrointestinal bleeding in 1, and severe electrolyte imbalance in 1, all of which were associated

178 sk factors and the impact of dehydration and electrolyte imbalance will improve health outcomes.

179 ten salts, have been employed as solid-state electrolytes in batteries, improved thermoelectrics and

180 erfluoro-sulfonic acid compounds employed as electrolytes in fuel cells.

181 Transport of fluid and electrolytes in the intestine allows for appropriate adj

182 electrochemical stability window of aqueous electrolytes, in this work we create a unique Li-ion/sul

183 The selection of the proper electrolyte, including solvents and salts, for LSBs stro

184 direct contact among carbon, electrode, and electrolyte, inhibit the performance and result in poor

185 Undesired electrode-electrolyte interactions prevent the use of many high-en

186 t this example of engineering an adaptive Li/electrolyte interface brings about a new and promising w

187 ppressing the deterioration of the electrode/electrolyte interface during high-voltage cell operation

188 due to accumulation of ions at the electrode/electrolyte interface is an inevitable phenomenon while

189 icle, interfacial impedance at the electrode/electrolyte interface is investigated considering channe

190 icochemical transformations at the electrode/electrolyte interface of atomically thin monolayer/few-l

191 e transfer of the cation across the particle-electrolyte interface.

192 confirm halogen bonding can exist at the dye-electrolyte interface.

193 rge potentials mainly takes place at Li2 O2 /electrolyte interfaces and has obvious correspondence wi

194 ependent rates of charge transfer at polymer/electrolyte interfaces remain poorly understood.

195 of electron transfer processes at electrode/electrolyte interfaces, originally developed for homogen

196 d hydroxyl *OH) at electrified metal-aqueous electrolyte interfaces.

197 ctrolyte synthesis, gives enhanced electrode-electrolyte interfaces.

198 on of inactive materials, and good electrode-electrolyte interfaces.

199 er-based polymeric components into the solid-electrolyte interphase (SEI) but also to accommodate Li

200 Solid-electrolyte interphase (SEI) films with controllable pro

201 electrolyte for Li-ion batteries, the solid electrolyte interphase (SEI) formed during electrochemic

202 An artificial solid electrolyte interphase (SEI) is demonstrated for the eff

203 ed with PDA to construct a passivating solid-electrolyte interphase (SEI) layer.

204 to their high reactivity and unstable solid electrolyte interphase (SEI).

205 tal atoms and their interface with the solid electrolyte interphase (SEI).

206 The application of a plastic-crystal electrolyte interphase between a solid electrolyte and a

207 The introduction of a plastic-crystal electrolyte interphase between a solid electrolyte and s

208 the authors show that a NaBr enriched solid-electrolyte interphase can lower the surface diffusion b

209 ever, the key issue is that the static solid electrolyte interphase cannot match the dynamic volume c

210 life, due to the formation of a robust solid electrolyte interphase consisting of Li2 CO3 -LiF, which

211 s the thickness and composition of the solid electrolyte interphase formed over a silicon anode in si

212 self-formation of stable and flexible solid-electrolyte interphase layers which serve to address bot

213 results in cracks and fractures of the solid electrolyte interphase, low Coulombic efficiency, and de

214 ing chemistry to create durable hybrid solid-electrolyte interphases (SEIs) on metal anodes.

215 e to the increased distance between adjacent electrolyte ions at the electrode surface.

216 odeposition of Si films from a Si-containing electrolyte is a cost-effective approach for the manufac

217 patterning of a lithium-ion conducting solid electrolyte is demonstrated by modifying a well-known ne

218 ference when a polycationic or a polyanionic electrolyte is used to direct collagen mineralization, w

219 The thickness of this thin electrolyte layer (dTL) was estimated by performing a sc

220 R spectrometer cause the formation of a thin electrolyte layer between the internal reflection elemen

221 line) electrodes in 0.1 M alkaline hydroxide electrolytes (LiOH, NaOH, KOH, RbOH, CsOH) between 0 and

222 e show that in the superconcentrated aqueous electrolyte, lithiation of sulfur experiences phase chan

223 chloride (KCl), sodium chloride (NaCl)], 2:1 electrolytes [magnesium chloride (MgCl2), calcium chlori

224 development is limited by the lack of solid electrolyte materials that can reach the practically use

225 Polymer electrolyte membrane fuel cells (PEMFCs) running on hydr

226 gas diffusion media (GDM), ionomers, polymer electrolyte membranes (PEMs), and electrode structures d

227 Polymer electrolyte membranes employed in contemporary fuel cell

228 Proton conductivity of the polymer electrolyte membranes in fuel cells dictates their perfo

229 urability.The proton conductivity of polymer electrolyte membranes in fuel cells dictates their perfo

230 e SNPs were proved to be associated with the electrolytes metabolism that may result in the formation

231 ride (MgCl2), calcium chloride (CaCl2)], and electrolyte mixtures (KCl + CaCl2) through a gated nanof

232 es can be significantly improved via organic electrolyte modification, Li-metal interface protection,

233 ion of various biomarkers, such as minerals, electrolytes, most polyphenols, and BPA, is reasonably r

234 r membranes to regulate muscle excitability, electrolyte movement across epithelia, and acidification

235 A Na-ion solid-state electrolyte, Na3 P0.62 As0.38 S4 , is developed with an

236 ueous electrolyte/silica interface, for four electrolytes: NaCl, KCl, MgCl2, and CaCl2.

237 In a solid electrolyte, neither the reaction mechanism at the catho

238 show that, due to ionic correlations in the electrolyte, NPs pairs at high monovalent salt concentra

239 at 300 mV, with high durability in alkaline electrolyte of 1 M KOH even after 10,000 cycles, represe

240 ins high CaSiO3 solubility, and a supporting electrolyte of CaO, which facilitates the transport of O

241 eling effect caused by the adsorption of the electrolytes on the electrode surface at negative potent

242 tion of oxidative decomposition of carbonate electrolytes on TMO surfaces and, more generally, the re

243 ads to decoupled pathways for oxygen gas and electrolyte: oxygen flows through the woven mesh while t

244 his phenomenon is strongly influenced by the electrolyte pH and buffer capacity and not limited to BD

245 tationary phases and 28 levels of background electrolyte pH in CE.

246 ematic comparison of transport of monovalent electrolytes [potassium chloride (KCl), sodium chloride

247 aided muscles, which do not require a liquid electrolyte, provide tensile contractions of 11.6% and 5

248 area and efficient pathways for electron and electrolyte/reactant transports.

249 membranes are produced using Li- or Na-based electrolytes, respectively.

250 arge injection experiments in the nonsolvent electrolyte reveal decomposition pathways that are relat

251 e support this hypothesis by showing that an electrolyte salt modification can lead to an adsorption

252 l control of electrode material, solvent and electrolyte salt, it should therefore be possible to att

253 Furthermore, the superconcentrated KFSI-DME electrolyte shows excellent electrochemical stability up

254 tively-charged alkylammonium, at the aqueous electrolyte/silica interface, for four electrolytes: NaC

255 on reaction involves complex interplay among electrolyte, solid catalyst, and gas-phase and liquid-ph

256 Superior to the liquid electrolytes, solid-state electrolytes are considered ab

257 serted inside a nanopipette probe containing electrolyte solution and a second electrode placed in a

258 tinum UME remains unchanged from the aqueous electrolyte solution mixed potential until approximately

259 cts on characteristic time scale in a binary electrolyte solution using parallel plate electrode conf

260 fusion of shed blood, crystalloids (balanced electrolyte solution), and norepinephrine support.

261 ween the nanochannel surface and the aqueous electrolyte solution, causing significant changes in mea

262 fabrication until dissolved by an ultrapure electrolyte solution.

263 -supported interfaces between two immiscible electrolyte solutions (ITIES) as tips.

264 ctions between proteins and nanoparticles in electrolyte solutions is crucial for advancing biologica

265 nt dissolved manganese cation in LiPF6-based electrolyte solutions of Li-ion batteries with lithium m

266 out electron transfer between two immiscible electrolyte solutions, but to the best of our knowledge,

267 cles at the interface between two immiscible electrolyte solutions.

268 face-adsorbed dye and a soluble redox-active electrolyte species in the dye-sensitized solar cell has

269 The garnet-based solid state electrolyte (SSE) is considered a promising candidate to

270 t as high as 46 mg cm(-2) and 70 wt% with an electrolyte/sulfur ratio of as low as only 5.

271 Electrolyte supplements and indomethacin were used frequ

272 metallic lithium in contact with the garnet electrolyte surface and the lithiated-alumina interface

273 d PEDOT coating, paired with in situ ion gel electrolyte synthesis, gives enhanced electrode-electrol

274 e.g., a composition and pH of the supporting electrolyte, the conditions of bismuth film deposition,

275 activities toward oxygen reduction in acidic electrolyte, the rational design of sacrificial metal-or

276 A preliminary in silico analysis using an electrolyte thermodynamic model indicated that MD of 10

277 ode modification, ratio of PEDOT: PSS, pH of electrolyte, time required for AuNP deposition, and 1-m-

278 0.3microm MnCl2.4H2O in non-buffered aqueous electrolyte under stirring whereas under non-stirring, T

279 between a lithium metal anode and the garnet electrolyte using ultrathin aluminium oxide (Al2O3) by a

280 ated in noncorrosive neutral NaCl supporting electrolytes using a low-cost anion-exchange membrane.

281 EDL behaviour, a sputtered 200 nm-thick SiO2 electrolyte was incorporated into InGaZnO TFTs as the ga

282 A cross-linked solid polymer electrolyte was synthesized by photo cross-linking react

283 ods tested, the analysis of aq LS containing electrolytes was simplest by LS DESI MS.

284 Using Li3OCl as a model polycrystalline electrolyte, we apply large-scale molecular dynamics sim

285 nostatic deposition of copper from an acidic electrolyte, we find that the growth front initially evo

286 wt %) after synthesis, and not the carbonate electrolyte, we further show that, up to 4.8 V vs Li/Li(

287 By examining a series of electrolytes, we find that the adsorption energy changes

288 ons that initially contained only supporting electrolyte where the OCP is a mixed potential governed

289 ride Complex was synthesized and utilized as electrolyte, where non-reversible features during in sit

290 al ions, i.e., Mg(2+) and Ca(2+), in aqueous electrolytes, where the van der Waals structure is intri

291 potential in the Debye screening layer of an electrolyte, which represents a key physicochemical surf

292 Electrolytes, which are a key component in electrochemic

293 ed materials also represent a class of solid electrolytes, which are widely employed in all-solid-sta

294 rgy densities of a SC using an ionic mixture electrolyte with different types of ionic interactions.

295 ptional charge storage capability in aqueous electrolyte with high specific capacitance ( approximate

296 distinct insight into pairing ionic mixture electrolytes with materials with confined porous charact

297 e general understanding, highly stable solid electrolytes with metal anodes in fact promote fast dend

298 gn of next-generation high-performance solid electrolytes with nacre-like architecture.

299 current density 10 mA cm(-2) in an alkaline electrolyte, with the Tafel slope of 32 mV dec(-1) and i

300 reaction in either strongly basic or acidic electrolytes without degradation of the semiconductor ph