ライフサイエンスコーパス: fuel cell

1 bioelectronics devices (such as sensors and fuel cells).

2 atinum utilization of 0.13 gPt kW(-1) in the fuel cell.

3 de to provide a membraneless fully enzymatic fuel cell.

4 for the commercialization of the direct DME fuel cell.

5 terial for one compartment membraneless H2O2 fuel cell.

6 casing are used to construct the paper-based fuel cell.

7 lication conditions in the hydrogen (H2)-air fuel cell.

8 zed chemical synthesis but also enzyme based fuel cells.

9 rial during the oxygen reduction reaction in fuel cells.

10 crucial for displacing Pt in low-temperature fuel cells.

11 hance the performance of Nafion membranes in fuel cells.

12 ergy technologies, particularly regenerative fuel cells.

13 ential for use in low-cost, high-performance fuel cells.

14 and coalescence can occur in low temperature fuel cells.

15 steam reforming for hydrogen production for fuel cells.

16 ne and neutral medium water electrolysis and fuel cells.

17 and degradation of Pt catalysts employed in fuel cells.

18 catalysts for the reductive side of hydrogen fuel cells.

19 incorporated into carbon and sulfur tolerant fuel cells.

20 trochemical methanol oxidation, and hydrogen fuel cells.

21 d previously for microsized MFCs and glucose fuel cells.

22 fficient electrocatalysts for application in fuel cells.

23 llent potential as an ORR electrocatalyst in fuel cells.

24 in devices such as proton exchange membrane fuel cells.

25 ysts for oxygen reduction reactions (ORR) in fuel cells.

26 d zirconia, with application for solid oxide fuel cells.

27 electrolysers and, in reverse, their use in fuel cells.

28 chemical industry and as electrocatalysts in fuel cells.

29 se of these composite materials in microbial fuel cells.

30 talysts for the oxygen reduction reaction in fuel cells.

31 ighly efficient, durable, and cost-effective fuel cells.

32 in electrochemical biosensors and biological fuel cells.

33 ysts for oxygen reduction in hydrogen/oxygen fuel cells.

34 ne- and mediator-free, transparent enzymatic fuel cells.

35 ilization of these bio-inspired complexes in fuel cells.

36 e directly used as the catalyst electrode in fuel cells.

37 c acid compounds employed as electrolytes in fuel cells.

38 stage of upgrading H2 reformate streams for fuel cells.

39 t of developed proton-exchange membranes for fuel cells.

40 catalytic performance of electrocatalysts in fuel cells.

41 l utilisation compared to all other types of fuel cells.

42 is significant for proton-exchange membrane fuel cells.

43 fast-ion conductors in super-capacitors and fuel cells.

44 catalysis to enable versatile membrane-free fuel cells.

45 rticular allow highly energetic reactions in fuel cells.

46 oxygen permeation membranes, and solid oxide fuel cells.

47 cations such as batteries, smart windows and fuel cells.

48 d environment-related applications including fuel cells.

49 future design of more efficient catalysts in fuel cells.

50 O2 reduction and a source of deactivation in fuel cells.

51 catalysis, emissions control and solid-oxide fuel cells.

52 erate at lower temperatures than solid oxide fuel cells (250 degrees to 550 degrees C versus >/=600 d

53 We have developed for fuel cells a novel proton exchange membrane (PEM) using

54 The vaCNT-based fuel cell achieves a maximal power density of 122 microW

55 n order to enable alkaline exchange membrane fuel cells (AEMFCs).

56 anion exchange membranes (AEMs) in alkaline fuel cells (AFCs); however, the commonly employed organi

57 Potential application in fuel cells also requires a WGS catalyst to be highly act

58 de of a miniature flow-through membrane-less fuel cell and showed excellent response to varying conce

59 gnificant intermediates in processes such as fuel cells and (bio)chemical oxidations, all involving s

60 d treatment process, consisting of microbial fuel cells and an anaerobic fluidized bed membrane biore

61 cal water splitting, the oxygen reduction in fuel cells and batteries.

62 e widely viewed as promising electrolytes in fuel cells and batteries.

63 2O2 reduction with scope for applications in fuel cells and biosensors.

64 ial is promising metal-free ORR catalyst for fuel cells and capacitor electrode materials.

65 ovskite-type oxides are increasingly used in fuel cells and catalysis, greater understanding of their

66 aterials, their performance and stability in fuel cells and comparisons with those of platinum are do

67 reduction electrocatalysts as components of fuel cells and electrolysers for renewable energy applic

68 se electrode structures perform well as both fuel cells and electrolysis cells (for example, at 900 d

69 ole in renewable energy technologies such as fuel cells and electrolyzers, but the slow kinetics of t

70 at are relevant for proton exchange membrane fuel cells and electrolyzers.

71 times higher than cellulose-based microbial fuel cells and is close to that of the best microbial fu

72 oxygen reduction and evolution reactions in fuel cells and metal-air batteries, activity descriptors

73 ments in bifunctional activity essential for fuel cells and metal-air batteries.

74 wable energy conversion technologies such as fuel cells and metal-air batteries.

75 idespread development of polymer electrolyte fuel cells and metal-air batteries.

76 nging from ionic gating to micro-solid oxide fuel cells and neuromorphics.

77 reaction (ORR), a PCET process important in fuel cells and O2 reduction enzymes.

78 ising strategy in developing high-performing fuel cells and other electrochemical systems via the int

79 wide variety of energy solutions, especially fuel cells and rechargeable metal-air batteries.

80 portant for electrochemical devices, such as fuel cells and resistive switches, but these effects hav

81 ts the performance and economic viability of fuel cells and sensors.

82 rrently used as electrolytes for solid oxide fuel cells and solid oxide electrolyzer cells.

83 tive in applications such as energy storage, fuel cells and various electronic devices.

84 ments are also established, encouraging the 'fuel cell' and 'battery' communities to move forward tog

85 oth energy conversion (e.g., solar cells and fuel cells) and storage (e.g., supercapacitors and batte

86 chargeable metal-air batteries, regenerative fuel cells, and other important clean energy devices.

87 ocessing such as supercapacitors, batteries, fuel cells, and separation membranes.

88 In this approach, fuel cell anode catalysts are modified with a molecularl

89 entially interesting applications beyond the fuel cell application demonstrated here.

90 (iNPs) have sparked considerable interest in fuel cell applications by virtue of their exceptional el

91 component for the successful development of fuel cell applications is hydrogen storage.

92 ng high-performance core-shell catalysts for fuel cell applications.

93 dercoordinated and enhanced active sites for fuel cell applications.

94 s promising new anode catalysts for alkaline fuel cell applications.

95 NF) toward the oxygen-reduction reaction for fuel-cell applications.

96 duction of non-platinum electrocatalysts for fuel-cell applications.

97 toward ethanol oxidation, holding promise in fuel-cell applications.

98 Fuel cells are the zero-emission automotive power source

99 presents a simple and sustainable Microbial Fuel Cell as a standalone, self-powered reactor for in s

100 The economic viability of low temperature fuel cells as clean energy devices is enhanced by the de

101 ics as compared to the drop-coated enzymatic fuel cell, as a result of the higher nanostructured surf

102 ion of methane in a proton exchange membrane fuel cell at 80 degrees C.

103 ion protocol for laboratory scale (10 cm(2)) fuel cells based on ultrasonic spray deposition of a sta

104 industrially important applications such as fuel cells, batteries, sensors, and catalysis.

105 eving high power output of benthic microbial fuel cells (BMFCs) with novel geometric anode setups (in

106 a promising alternative fuel for direct-feed fuel cells but lack of an efficient DME oxidation electr

107 lysts for oxygen reduction reaction (ORR) in fuel cells, but practical applications have been limited

108 very important for the commercialization of fuel cells, but still a great challenge.

109 offer proof of concept that electrolysis and fuel cells can be unified in a single, high-performance,

110 Biobattery, a kind of enzymatic fuel cells, can convert organic compounds (e.g., glucose

111 is illustrated by powering a hydrogen-oxygen fuel cell car by an on-board motion-based hydrogen and o

112 To make fuel-cell cars a reality, the US Department of Energy ha

113 udy is focused on development of a microbial fuel cell catalysed by E. coli, through triggering elect

114 atively engineered into active materials for fuel cells, catalysis, and electronics.

115 tive polymers have been increasingly used as fuel cell catalyst support due to their electrical condu

116 nanoparticles, are fascinating and promising fuel cell catalysts due to their high utilization of nob

117 n reduction reaction, ORR), which makes them fuel-cell cathode catalysts with exceptional potential.

118 rticles for the oxygen reduction reaction in fuel cell cathodes.

119 ity of palladium in the harsh environment of fuel-cell cathodes renders its commercial future bleak.

120 For some of these, such as fuel cells, CeO2-based materials have almost reached the

121 ohol mixtures play an important role such as fuel cells, chemical synthesis, self-assembly, catalysis

122 3 and 6 muW cm(-2) are obtained for the same fuel cell configuration, respectively.

123 ltifunctional paper layers for two-chambered fuel cell configuration.

124 polymer for electrolyte membranes (PEMs) in fuel cells, consists of a fluorocarbon backbone and acid

125 Enzymatic fuel cells containing a 15% (wt/v) maltodextrin solution

126 Fuel cells convert chemical energy directly into electri

127 A direct carbon fuel cell (DCFC) can produce electricity with both super

128 Direct carbon fuel cells (DCFCs) are highly efficient power generators

129 The fuel cell delivered a linear power output response to gl

130 The Pt-free enzyme-based fuel cell delivers approximately 2 mW cm(-2) , a new eff

131 e algae immobilized in alginate gel within a fuel cell design for generation of bioelectricity.

132 nificantly improved performances in terms of fuel cell design, bioelectricity generation, oxygen prod

133 t to environmental remediation and microbial fuel cell development.

134 vity of the polymer electrolyte membranes in fuel cells dictates their performance and requires suffi

135 uctivity of polymer electrolyte membranes in fuel cells dictates their performance, but requires suff

136 Low-temperature direct methane fuel cells (DMEFCs) offer the opportunity to substantial

137 ary (TPB) layer of a passive direct methanol fuel cell (DMFC) as biosensor transducer is herein propo

138 ficient cathode materials in direct methanol fuel cells (DMFCs).

139 The direct urea fuel cell (DUFC) is an important but challenging renewab

140 Good fuel cell durability is also observed.

141 cular hydrogen (H2 ) results in an enzymatic fuel cell (EFC) that is able to produce NH3 from H2 and

142 (RVC-Au) sponge as a scaffold for enzymatic fuel cells (EFC).

143 Enzymatic fuel cells (EFCs) hold great potential as power sources

144 0 EW Nafion ionomer in glucose/air enzymatic fuel cells (EFCs), EFCs with laccase air-breathing catho

145 ciency of 65-70%, which is comparable to the fuel cell efficiencies.

146 a strategy for the development of reversible fuel cell electrocatalysts for partial oxidation (dehydr

147 is highly desirable for lowering the cost of fuel-cell electrocatalysts.

148 re their applications may include batteries, fuel cells, electrocatalytic water splitting, corrosion

149 oxides are increasingly used in solid oxide fuel cells, electrolysis and catalysis, it is desirable

150 Electrochemical devices such as fuel cells, electrolyzers, lithium-air batteries, and ps

151 ructures designed for use in next-generation fuel cells, electrolyzers, or flow batteries.

152 on, and hydrocarbon conversion reactions for fuel cells (electrooxidation of methanol, ethanol, and f

153 l Pt nanoparticle catalyst electrode in real fuel cell environment.

154 vironmental benefits from range-extended and fuel-cell EVs over ICVs and standard EVs.

155 The hybrid microfluidic fuel cell exhibited excellent performance with a maximum

156 Hydrogen fuel cells (FC) are considered essential for a sustainab

157 first acetylcholine/oxygen hybrid enzymatic fuel cell for the self-powered on site detection of ACh

158 Besides their use in fuel cells for energy conversion through the oxygen redu

159 ode and evaluated in the hybrid microfluidic fuel cell generating 0.5 mW cm(-2) of maximum power dens

160 Microbial fuel cells harness electrical power from a wide variety

161 ces such as metal-air batteries and portable fuel cells has proven elusive.

162 emical energy-conversion devices such as HEM fuel cells, HEM electrolyzers, and HEM solar hydrogen ge

163 tive technology, hydroxide exchange membrane fuel cells (HEMFCs), has gained significant attention, b

164 ede the widespread uptake of low-temperature fuel cells in automotive vehicles.

165 en splitting such as fuel cells (solid-oxide fuel cells in particular) and for catalytic applications

166 plementation of polymer electrolyte membrane fuel cells in vehicles, high-performance electrocatalyst

167 zymatic biofuel cells (EBFCs), a subclass of fuel cells in which enzymes replace the conventional cat

168 This enzymatic fuel cell is based on non-immobilized enzymes that exhib

169 catalyst layer in an anion exchange membrane fuel cell is critical for a functioning fuel cell, yet i

170 group-metal-free hydroxide exchange membrane fuel cell is hindered by the lack of a hydrogen oxidatio

171 on present in the gas diffusion layer of the fuel cell is only of minor concern.

172 For the first time, a paper based enzymatic fuel cell is used as self-recharged supercapacitor.

173 Finally, direct utilization of methane onto fuel cells is also discussed.

174 The widespread use of fuel cells is currently limited by the lack of efficient

175 A@ZIF-8 hybrid membrane into direct methanol fuel cells, it exhibits a power density of 9.87 mW cm(-2

176 ic molecules, as well as in electrocatalysis/fuel cells, lithium-ion batteries, and experiments that

177 talysis, CO2 fixation, ionogel, electrolyte, fuel-cell, membrane, biomass processing, biodiesel synth

178 loping renewable energy technologies such as fuel cells, metal-air batteries, and water electrolyzers

179 ported by applying a two-chambered microbial fuel cell (MFC) as a power supply.

180 We built a flexible, stretchable microbial fuel cell (MFC) by laminating two functional components:

181 A microbial fuel cell (MFC) equipped with the rGO/MnO2/CF anode deli

182 ackable and integrable paper-based microbial fuel cell (MFC) for potentially powering on-chip paper-b

183 Microbial fuel cell (MFC) is a promising technology for direct ele

184 The microbial fuel cell (MFC) technology offers sustainable solutions

185 troactive behavior of a microbe in microbial fuel cell (MFC) under specific selection pressure.

186 the fabrication of a microfluidic microbial fuel cell (MFC) using nickel as a novel alternative for

187 he energy harvesting function of a microbial fuel cell (MFC) with the high-power operation of an inte

188 Microbial fuel cells (MFC) are considered as the futuristic energy

189 lectron recovery is competition in microbial fuel cells (MFC) between anode-respiring bacteria and mi

190 t of origami and the technology of microbial fuel cells (MFCs) and has the potential to shift the par

191 Microbial fuel cells (MFCs) are a promising technology for energy-

192 Microbial fuel cells (MFCs) are bio-electrochemical devices, where

193 Microbial fuel cells (MFCs) are novel bio-electrochemical device f

194 On the other hand, microbial fuel cells (MFCs) are promising devices to recover carbo

195 Long-term operation of microbial fuel cells (MFCs) can result in substantial degradation

196 mer and carbon-carbon materials in microbial fuel cells (MFCs) has been investigated.

197 The use of granular electrodes in Microbial Fuel Cells (MFCs) is attractive because granules provide

198 Microbial fuel cells (MFCs) present promising options for environm

199 bioelectrochemical reactors, like microbial fuel cells (MFCs), make accurate predictions of performa

200 tromicrobiology stem from studying microbial fuel cells (MFCs), which are gaining acceptance as a fut

201 oxygen reduction reaction (ORR) in microbial fuel cells (MFCs).

202 le and double-cell membraneless microfluidic fuel cells (MMFCs) that operate in the presence of simul

203 for storage of CO2 in deep saline aquifers, fuel cells, oil recovery, and for the remediation of oil

204 Notably, this methane microbial fuel cell operates at high Coulombic efficiency.

205 Microbial fuel cells operating with autotrophic microorganisms are

206 ed under a practical alkaline direct ethanol fuel cell operation condition for its potential applicat

207 s initial proof-of-concept, in a non-passive fuel cell operation environment.

208 a0.5MnO3-delta in fuel conditions and actual fuel cell operation is demonstrated.

209 (ORR) and oxygen evolution reaction (OER) in fuel cells or metal-air batteries.

210 udied as a material for metal-air batteries, fuel cells, or supercapacitors because of their relative

211 operate with high efficiency in two ways-as fuel cells, oxidizing a fuel to produce electricity, and

212 xhibited excellent properties as solid oxide fuel cell oxygen electrodes.

213 ance to replace the expensive Pt catalyst in fuel-cell oxygen electrodes.

214 tion (ORR) in proton exchange membrane (PEM) fuel cells, oxygen evolution reaction (OER) in PEM based

215 d to oxygen ion conduction, protonic ceramic fuel cells (PCFCs) should be able to operate at lower te

216 t)-based counterparts in polymer electrolyte fuel cells (PEFCs) but still face some major challenges,

217 rtance in advancing proton exchange membrane fuel cell (PEMFC) technology.

218 he cathode, or in a proton exchange membrane fuel cell (PEMFC) using Pt/C at the cathode.

219 onents of the basic proton exchange membrane fuel cell (PEMFC), namely the cathode catalyst and the p

220 the construction of proton exchange membrane fuel cells (PEMFC) reaching values up to 12.95 mW cm(-2)

221 reaction governing proton exchange membrane fuel cells (PEMFC), namely the oxygen reduction reaction

222 reaction (ORR) for proton exchange membrane fuel cells (PEMFCs) are thoroughly reviewed.

223 (LIBs) or proton exchange membrane hydrogen fuel cells (PEMFCs) offer important potential climate ch

224 Polymer electrolyte membrane fuel cells (PEMFCs) running on hydrogen are attractive a

225 ions has focused on proton exchange membrane fuel cells (PEMFCs), because these systems have demonstr

226 low-temperature polymer electrolyte membrane fuel cells (PEMFCs).

227 scale deployment of proton exchange membrane fuel cells (PEMFCs).

228 Such modification increases fuel cell performance due to the proton conductivity and

229 Fuel cell performance using SrFe0.8Cu0.1Nb0.1O3-delta as

230 The unprecedented fuel-cell performance of this electrocatalyst is linked

231 im, we here report the first paper microbial fuel cell (pMFC) fabricated by screen-printing biodegrad

232 A paper-based multi-anode microbial fuel cell (PMMFC) integrated with power management syste

233 content of stored hydrogen and/or introduce fuel cell poisons.

234 The fuel cell polarization results are corroborated by elect

235 Such electronic leakage reduces fuel cell power output and the associated chemo-mechanic

236 he power density of the solar-induced hybrid fuel cell powered by cellulose reaches 0.72 mW cm(-2), w

237 nductivity membrane used for direct methanol fuel cells, providing bright promise for such hybrid mem

238 The enzymatic fuel cell reaches 0.5 V at open circuit voltage with bot

239 the enzyme active site of biocathodes under fuel cell reaction conditions.

240 4H(+)/4e(-) reduction of O2 to water, a key fuel-cell reaction also carried out in biology by oxidas

241 , the lack of high-performance catalysts for fuel cell reactions remains a challenge in realizing fue

242 es the stability of the Au/CuPt catalyst for fuel cell reactions.

243 s and is close to that of the best microbial fuel cells reported in literature.

244 In this supercapacitive enzymatic fuel cell (SC-EFC), the supercapacitive features of the

245 d in a membraneless single-chamber microbial fuel cell (SCMFC) running on wastewater.

246 inating the contribution of water in a micro fuel cell sensor system.

247 The limit of detection of the fuel cell sensor was 10muM, with an average response tim

248 re (<500 degrees C) operation of solid oxide fuel cells, sensors and other ionotronic devices.

249 ectrolyte membranes employed in contemporary fuel cells severely limit device design and restrict cat

250 nd selectivity of the bioreceptor inside the fuel cell showed a clear and selective signal from the b

251 ophyte Acorus calamus and sediment microbial fuel cells (SMFC) during the degradation of high molecul

252 spectra of the mixed-conducting solid oxide fuel cell (SOFC) cathode material La2NiO4+delta, a param

253 nstrated real-time monitoring of solid oxide fuel cell (SOFC) operations with 5-mm spatial resolution

254 ow potential as electrolytes for solid oxide fuel cells (SOFC) due to their high ionic conductivity a

255 ct-conducting oxides find use in solid oxide fuel cells (SOFCs) and oxygen-deficient high-temperature

256 mospheres are in high demand for solid oxide fuel cells (SOFCs) and solid oxide electrolytic cells (S

257 Solid oxide fuel cells (SOFCs) are a rapidly emerging energy technol

258 lopment has been challenging for solid oxide fuel cells (SOFCs) owing to many reasons including poor

259 t potential as an electrolyte in solid oxide fuel cells (SOFCs), owing to its stability and near-unit

260 key step for direct hydrocarbon solid oxide fuel cells (SOFCs).

261 oxygen storage and oxygen splitting such as fuel cells (solid-oxide fuel cells in particular) and fo

262 ediated by one or a few enzymes in enzymatic fuel cells suffers from low energy densities and slow re

263 ality, the US Department of Energy has set a fuel cell system cost target of US$30 kW(-1) in the long

264 l reactions remains a challenge in realizing fuel cell technologies for transportation applications.

265 n (MOR) are at the heart of key green-energy fuel cell technology.

266 the overall efficiency and marketability of fuel cell technology.

267 the commercial viability of direct methanol fuel cell technology.

268 aqueous electrolyte and polymer-electrolyte fuel cell testing, the ternary catalyst shows much highe

269 r activity (two-fold enhancement at 0.5 V in fuel cells) than the state-of-the-art binary Pt50 Ru50 /

270 aper-based enzymatic microfluidic glucose/O2 fuel cell that can operate using a very limited sample v

271 lectrons from acetate, to create a microbial fuel cell that converts methane directly into significan

272 sh a membrane-free, room-temperature formate fuel cell that operates under benign neutral pH conditio

273 and an enhanced stability of the vaCNT-based fuel cells they have been studied in human serum samples

274 ise in applications ranging from solid oxide fuel cells to catalysts, their surface chemistry is poor

275 of applications, ranging from batteries and fuel cells to chemical sensors, because they are easy to

276 cal for applications ranging from batteries, fuel cells to electrocatalysis.

277 ccess previously as a substrate in microbial fuel cells to generate electrical current.

278 inspired nanomaterial either in an enzymatic fuel cell together with a multicopper oxidase at the cat

279 anism is based on a glucose/oxygen enzymatic fuel cell using an electrochemical energy conversion as

280 gle MMFC was tested in a hybrid microfluidic fuel cell using Pt/C as the cathode.

281 change membrane (AAEM) material for alkaline fuel cells using the electrochemical quartz crystal micr

282 The rising interest in fuel cell vehicle technology (FCV) has engendered a grow

283 pecially for application in hydrogen powered fuel-cell vehicles (HFCV's).

284 the kinetic region of cathode operation, at fuel cell voltages greater than 0.75 V, were the same a

285 The peak power generated by the fuel cell was 4nW at a voltage of 260mV and with a curre

286 A new full enzymatic fuel cell was built and characterized.

287 The enzyme fuel cell was connected with a 100 muF capacitor and a p

288 The voltage of the enzyme fuel cell was increased in a stepwise manner by the char

289 e can be applied to a range of applications (fuel cells, water splitting, and redox flow batteries) t

290 Microbial fuel cells were rediscovered twenty years ago and now ar

291 , we demonstrate a supercapacitive microbial fuel cell which integrates the energy harvesting functio

292 r advantage over more conventional microbial fuel cells which require the input of organic carbon for

293 for the development of cathodes in enzymatic fuel cells, which often suffer from poor electronic comm

294 is paper reports on a miniaturized microbial fuel cell with a microfluidic flow-through configuration

295 sing a mediatorless photosynthetic microbial fuel cell with results showing positive light response.

296 ed to three different metals using microbial fuel cells with Cr(VI) or Cu(II) as these metals have re

297 vel electrodes are needed for direct ethanol fuel cells with improved quality.

298 rane fuel cell is critical for a functioning fuel cell, yet is relatively unexplored.

299 erformance in a polymer electrolyte membrane fuel cell, yielding a maximal power density of 820 mW cm

300 electrodes were employed within an enzymatic fuel cell, yielding a self-powered biosensor for arsenit