ライフサイエンスコーパス: battery

1 ed with the Penn Computerized Neurocognitive Battery.

2 a cathode-active material for a rechargeable battery.

3 g an established vibrotactile psychophysical battery.

4 volumetric power density with the microbial battery.

5 subsequently assessed them on a touchscreen battery.

6 tyl viologen as the anolyte to yield a 2.0 V battery.

7 facturing of high energy density solid-state batteries.

8 ectrolyte-starved (4.7 muL mg(S) (-1) ) Li-S batteries.

9 h for the rational design of next-generation batteries.

10 rvice of Li anodes in high energy and safety batteries.

11 es, ranging from solar cells to rechargeable batteries.

12 es for practical applications of Li/Na-CO(2) batteries.

13 g cycle life and high-power lithium-selenium batteries.

14 hemical similarities with lithium (Li) based batteries.

15 d the infrared camera are both operated with batteries.

16 teries, zinc-air batteries, and aluminum-air batteries.

17 , all-solid-state batteries, and multivalent batteries.

18 ctivity for high-energy-density rechargeable batteries.

19 scalable, and high-performance rechargeable batteries.

20 uch as water splitting devices and metal-air batteries.

21 ntercalating cathodes are to be used in such batteries.

22 m remains a critical issue for lithium metal batteries.

23 anodes for 'Rocking-Chair' alkali metal-ion batteries.

24 e critical to the development of solid-state batteries.

25 rd high-energy, long-life, and safe Li metal batteries.

26 for next-generation high-energy lithium-ion batteries.

27 -performance P2-type cathodes for sodium-ion batteries.

28 t-generation high-energy, cobalt-free Li-ion batteries.

29 organic liquid electrolyte-dominated Li-ion batteries.

30 r their applications in alkali metals-sulfur batteries.

31 ganic solid electrolytes for all-solid-state batteries.

32 ghts for the design of future lithium-sulfur batteries.

33 ies are key components of wearable metal-air batteries.

34 ential catholytes for non-aqueous redox flow batteries.

35 sign strategy for other types of solid-state batteries.

36 des for fast-charging, long-life lithium-ion batteries.

37 allenges for stretchable supercapacitors and batteries.

38 ainly govern the lifetime and reliability of batteries.

39 solid-state electrolytes and all solid-state batteries.

40 in engineering better interphases for future batteries.

41 dendrite formation of lithium-sulfur (Li-S) batteries.

42 rvive harsh cycling conditions in sodium ion batteries.

43 d for rechargeable high-temperature Li metal batteries.

44 commercial devices such as Pb-acid and Ni/MH batteries.

45 mploying the air cathode in superoxide-based batteries.

46 e of more than 2000 cycles for lithium metal batteries.

47 al batteries, especially for Li-NMC 811 full batteries.

48 tion of a lithium metal anode in solid-state batteries.

49 gh energy-density rechargeable lithium metal batteries.

50 high-energy-density cathodes for lithium-ion batteries.

51 structural stability of Si-based lithium-ion batteries.

52 s attractive alternatives beyond lithium-ion batteries.

53 gy efficiency in aprotic Li-O(2) and Na-O(2) batteries.

54 catalysis, supercapacitors, and rechargeable batteries.

55 layered oxides for high-capacity lithium-ion batteries.

56 ctrode/electrolyte interfaces in solid-state batteries.

57 role in understanding and controlling these batteries.

58 opment of solid electrolytes and solid-state batteries.

59 to enable the next-generation lithium-metal batteries, a "fail safe" mechanism for internal short is

60 al fibers, but their use of head stages with batteries adds bulk and weight that can affect behaviors

61 i-ion" technologies: Na-ion batteries, K-ion batteries, all-solid-state batteries, and multivalent ba

62 used as electrode materials in rechargeable batteries and are expected to advance the development of

63 studied paths to enable high-energy-density batteries and high-efficiency solar cells.

64 nterest in the development of new sodium-ion batteries and new analytical methods to non-invasively,

65 for electrochemical reactions in solid-state batteries and provides crucial insights into underlying

66 based electrolytes for conventional "sealed" batteries and redox-flow systems.

67 rview of the general operating principles of batteries and supercapacitors and the requirements to ma

68 hielding coatings and current collectors for batteries and supercapacitors.

69 situ dynamic nuclear polarisation studies of batteries and the selective enhancement of metal-solid i

70 on of an aqueous alkaline quinone redox flow battery and a hydrogen PEM fuel cell.

71 Using a comprehensive neuropsychiatric battery and a virtual casino to assess impulsive behavio

72 categories of oxide cathodes for lithium-ion batteries, and a personal perspective on the future of t

73 r batteries, lithium-air batteries, zinc-air batteries, and aluminum-air batteries.

74 batteries, K-ion batteries, all-solid-state batteries, and multivalent batteries.

75 rfacial issues commonly exist in solid-state batteries, and the microstructural complexity combines w

76 lent energy efficiency in a high rate Li-air battery, and iv) high break-down current density for int

77 issue becomes more severe for aqueous Na-ion batteries (ANIBs) owing to the relatively lower solubili

78 e first report of successful potassium metal battery anode cycling with an aluminum-based rather than

79 degradation mechanisms and mitigations, and battery architectures and integrations.

80 Solid-state batteries are a proposed route to safely achieving high

81 sion reactions with alkali ions in secondary batteries are comprehensively summarized.

82 Potassium metal batteries are considered as attractive alternatives beyo

83 However, many next-generation batteries are limited by electrolyte selection because h

84 Rechargeable lithium metal batteries are next generation energy storage devices wit

85 Rechargeable batteries are notoriously difficult to examine nondestru

86 Aqueous Zn batteries are promising energy storage devices for large

87 ater-based electrolytes, aqueous lithium-ion batteries are resistant to catching fire.

88 oday's state-of-the-art lithium-air (Li-air) batteries are their low energy efficiency and limited cy

89 or at least mitigate, the requirement for a battery are emerging at an astonishing pace.

90 s such as electrolysers, fuel cells and flow batteries, as well as in operando studies of ion distrib

91 diagram to unveil their reaction pathways in batteries, as well as the molecular origin of their slug

92 ogress in the development of all-solid-state batteries (ASSBs).

93 The aqueous rechargeable Zn-air batteries assembled with this carbon aerogel exhibit a r

94 and a comprehensive neuropsychological test battery assessing executive function, processing speed,

95 days 9 and 10, participants completed a task battery assessing psychophysiological indices of fear le

96 All-solid-state lithium ion batteries (ASSLBs) are considered next-generation device

97 nistered a comprehensive neurocognitive test battery at baseline and 2 y.

98 Aqueous zinc (Zn) batteries (AZBs) are widely considered as a promising ca

99 y for practical applications in rechargeable batteries based on metal anodes.

100 Now, the first K-air (dry) battery based on reversible superoxide electrochemistry

101 S) has been developed to charge a cell phone battery based on sediment microbial fuel cells (SMFCs).

102 sting (Alzheimer Disease Research Center UDS battery), basic and instrumental activities of daily liv

103 Technologies such as batteries, biomaterials and heterogeneous catalysts have

104 play a key role in advanced lithium (Li)-ion batteries, but it suffers from moisture sensitivity, sid

105 itical to tune the cell chemistry of Li-O(2) batteries by designing a simple system to promote LiOH f

106 olyte interface in solid-state lithium metal batteries can be overcome using this architecture.

107 phite anodes is a critical reason for Li-ion battery capacity decay and short circuit.

108 e utility of active particles towards higher battery capacity.

109 n and detection, cannot easily penetrate the battery casing due to the skin depth.

110 of transition metal oxide (TMO) lithium-ion battery cathode nanomaterial, lithium cobalt oxide (LCO)

111 Superior performance is achieved as a Li-ion battery cathode with a high reversible capacity (387 mA

112 demonstrates that it is possible to use the battery cell as a resonator in a tuned circuit, thereby

113 energy storage materials for a wide range of battery chemistries.

114 ethods to non-invasively, directly visualise battery chemistry.

115 er acceptance of EQCM-based methods from the battery community.

116 trochemical performances in potassium-sulfur batteries compared with bare potassium metal anodes.

117 application in various types of solid-state battery concepts (e.g., Li-ion, Li-S, and Li-air), and w

118 temperature Li metal batteries with a simple battery configuration and high safety, which is differen

119 Aluminium batteries constitute a safe and sustainable high-energy-

120 A classical battery converts chemical energy into a persistent volta

121 uding hypothetical policy tweaks, oil price, battery cost and charging infrastructure for the Chinese

122 and the low discharge potential of Na-CO(2) batteries create obstacles for practical applications of

123 iew state-of-the-art developments in organic batteries, current challenges, and prospects, and we dis

124 inute fast-charging protocols for maximizing battery cycle life, which can alleviate range anxiety fo

125 For a better understanding of battery cycling and degradation, operando analytical mea

126 owing an "anti-aging" effect in high-voltage battery cycling and successfully stopping the escape of

127 evere volume change of active materials upon battery cycling, which largely limit the large-scale app

128 e severe volume change during lithium-sulfur battery cycling.

129 tional safety of commercial lithium (Li)-ion batteries demand further improvement.

130 Consequently, battery demand has exploded along with the need for ores

131 can be generalized to other applications in battery design and, more broadly, other scientific domai

132 torage requires a diversity of purpose-built batteries designed to meet disparate applications.

133 Breakthroughs in electrode and battery designs, stimulation paradigms, closed-loop and

134 may open a pathway towards safer lithium-ion battery designs.

135 Lithium-sulfur (Li-S) batteries, despite having high theoretical specific ener

136 olid-state batteries largely lead the future battery development.

137 Dual-ion batteries (DIBs), in which both cations and anions are i

138 ) are promising next-generation rechargeable batteries due to the high gravimetric energy, low cost,

139 ess and control optimization for lithium-ion batteries during materials selection, cell manufacturing

140 ts are ripe for electrification, adoption of battery electric vehicles (BEVs) in fleet applications h

141 e in mixed capacitive deionization (CDI) and battery electrode deionization (BDI) systems because the

142 isely quantifying the evolving nature of the battery electrode's microstructure with statistical conf

143 om commercial carbon fibers and a structural battery electrolyte, and uses lithium-ion insertion to p

144 computational design, electrochemistry, and battery engineering, all to propel the Ca battery techno

145 e the key to highly reversible lithium metal batteries, especially for Li-NMC 811 full batteries.

146 mance, assessed by the NIH Toolbox Cognition Battery Fluid Cognition Composite.

147 a promising approach for developing Li||LCO batteries for practical applications.

148 96) on cognitive ability (Kaufman Assessment Battery for Children, second edition [KABC-II]), attenti

149 ssessed global cognition with the Repeatable Battery for the Assessment of Neurologic Status and exec

150 We measured the Repeatable Battery for the Assessment of Neuropsychological Status

151 otential energy applications of off-grid and battery-free lighting and sensing.

152 Continuous, battery-free operation of sensor nodes requires ultra-lo

153 Potential candidates include batteries, fuel cells, energy harvesters and supercapaci

154 r, practical development of lithium-selenium batteries has been hindered by the low selenium reaction

155 The battery has been fully charged in 26 h using 72 SMFCs.

156 nt in the 1970s, the rechargeable alkali-ion battery has proven to be a truly transformative technolo

157 ition metal oxide based cathode for a Li-ion battery, has garnered much attention due to the enhanced

158 Lithium-ion batteries have aided the portable electronics revolution

159 Solid-electrolyte-based molten-metal batteries have attracted considerable attention for grid

160 Lithium-oxygen (Li-O(2) ) batteries have attracted extensive research interest due

161 le-crystal cathode materials for lithium-ion batteries have attracted increasing interest in providin

162 Metal-CO(2) batteries have attracted much attention owing to their h

163 anodes in high-energy-density lithium metal batteries have been hindered by their formation and grow

164 Sodium-ion batteries have captured widespread attention for grid-sc

165 Rechargeable sodium (Na) based batteries have gained tremendous research interest becau

166 gh-capacity alloy anode materials for Li-ion batteries have long been held back by limited cyclabilit

167 Lithium-ion batteries have proven themselves to be indispensable amo

168 Lithium-ion batteries have remained a state-of-the-art electrochemic

169 iation, which is the evaluation criterion of battery homogeneity, was 2.14% based on CiS while it was

170 N) cycling to the function of HSs as a redox battery, however, remains poorly understood.

171 mprove the high-voltage performance of other batteries in a broad temperature range.

172 Here, lithium metal batteries in a novel nonflammable ionic-liquid (IL) elec

173 functional Li||lithium iron phosphate (LFP) batteries in which LFP cathodes with high capacity (5 to

174 the Adult Memory and Information Processing Battery in 145 unilateral refractory TLE patients underg

175 ort and the Penn Computerized Neurocognitive Battery in the PNC.

176 constraint on the supply chain of the Li-ion battery industry.

177 Superoxide-based K-O(2) batteries, invented in 2013, adopt the one-electron redo

178 two solvent-based electrolytes for Mg-metal batteries is investigated through a grand canonical dens

179 The performance of such batteries is limited by available electrode materials, e

180 Similarly, a phase battery is a quantum device that provides a persistent p

181 material used in a lithium-ion or sodium-ion battery is alkali-rich, this can increase the battery's

182 Further, the cell phone battery is continuously charged using the two parallel-c

183 ectrolytes, even during the periods when the battery is not in use, i.e., when no current is flowing,

184 portant "beyond Li-ion" technologies: Na-ion batteries, K-ion batteries, all-solid-state batteries, a

185 s the first review on potassium-sulfur (K-S) batteries (KSBs), which are emerging metal battery (MB)

186 s the most critical component in solid-state batteries largely lead the future battery development.

187 a can be wirelessly transmitted from simple, battery-less tags using Radio Frequency Identification (

188 Lithium-ion batteries (LIBs) are of tremendous importance for our so

189 Commercial lithium-ion batteries (LIBs), limited by their insufficient reversib

190 nce the sealing structure adopted by current batteries limits the dissipation of heat and pressure wi

191 itors, lithium-ion batteries, lithium-sulfur batteries, lithium-air batteries, zinc-air batteries, an

192 ng fiber-shaped supercapacitors, lithium-ion batteries, lithium-sulfur batteries, lithium-air batteri

193 , the practical application of lithium-metal batteries (LMBs) is still impeded by the instability of

194 ape to improve the reversibility of Li metal batteries (LMBs) is studied.

195 High-energy rechargeable lithium (Li) metal batteries (LMBs) with Li metal anode (LMA) were first de

196 e, high-energy-density rechargeable Li metal batteries (LMBs).

197 ical performance (Short Physical Performance Battery), loneliness (modified UCLA Loneliness Scale), a

198 Lithium sulfur batteries (LSBs) are promising next-generation rechargea

199 ults demonstrate the value of EIS signals in battery management systems.

200 Here we show the potential for "Li-free" battery manufacturing using the Li(7)La(3)Zr(2)O(12) (LL

201 dy provides critical insights into designing battery materials for extreme irradiation environments a

202 ues for the study of rechargeable alkali-ion battery materials, followed by a critical review of the

203 y and computation of rechargeable alkali-ion battery materials.

204 ly promote and homogenize redox reactions in battery materials.

205 nsights for improved design of high-capacity battery materials.

206 g the electrochemical properties of advanced battery materials.

207 hemomechanical properties of polycrystalline battery materials.

208 al discrete interfacial contact, solid-state batteries may still display homogeneous lithium-ion tran

209 ) batteries (KSBs), which are emerging metal battery (MB) systems.

210 termining the life and safety of lithium-ion battery modules or packs.

211 Currently, all reported liquid metal batteries need to be operated at temperatures above 240

212 ransport mechanism in solid electrolytes for batteries, not only the periodic lattice but also the no

213 A neuropsychological battery of 11 tests covering domains of attention/proces

214 Female, Long Evans rats experienced a battery of adverse adolescent experiences (n = 12), whil

215 s were assessed for functional activity in a battery of assays, including binding assays and an assay

216 fspring (8 weeks old) were assessed across a battery of behavioral assessments followed by region-spe

217 At day 15, survivor mice completed a battery of cognitive and behavioral tasks.

218 e-Extended (GOSE), the Short Form-12v2 and a battery of cognitive tests.

219 We measured cognition using a battery of conventional instruments assessing orientatio

220 nsport of IGO:PVA film are investigated by a battery of experimental and theoretical techniques, incl

221 of cognitive and behavioral symptoms using a battery of neuropsychologic tests and then classified as

222 lthy controls (n = 64) using a comprehensive battery of nine value-based decision-making tasks which

223 those neuronal representations to support a battery of orthographic processing tasks.

224 wdsourcing, we presented participants with a battery of questions about their recent social media use

225 There is now a growing battery of sophisticated empirical and computational tec

226 We conducted a battery of stress-sensitive behavioral paradigms in free

227 A battery of tests was conducted to characterize the diffe

228 estigated as electrode materials for various batteries on account of their resource abundance, low co

229 lithium metal anodes for high-energy-density batteries, one fundamental challenge is the slow lithium

230 failure; and treatment duration >10 min), a battery-operated thermal ablator that is lightweight and

231 se techniques to yield crucial insights into battery operation and performance.

232 s failure mechanism during commercial Li-ion battery operation, including both slow and fast charging

233 applied as the cathode catalyst for Li-O(2) battery operations with a record-high current density pe

234 Generally, the homogeneity of a battery pack is evaluated by characterizing the cells in

235 reported to influence the redox reactions in battery particles through single-particle, multimodal, a

236 mporal discounting, the Arizona life history battery, past and current health, disgust sensitivity, a

237 iating volume expansion, leading to superior battery performance.

238 udies demonstrate a powerful in situ optical battery platform for unraveling the complex reaction mec

239 We have developed a portable, automated, battery-powered, and remotely operated ME instrument cou

240 Depending on fuel, electricity, and battery prices, our findings suggest that FCEVs could co

241 superoxide-based potassium-oxygen (K-O(2) ) batteries, prior studies were limited to pure oxygen.

242 derive the theoretical relationships for key battery properties, such as voltage, capacity, alkali di

243 discharge) and when comprehensive cognitive batteries rather than Mini-Mental State Examination were

244 bility is one of the central aims of current battery research.

245 Aqueous redox flow batteries (RFBs) are promising alternatives for large-sc

246 ane (PEM) fuel cells (PEMFCs) and redox flow batteries (RFBs).

247 attery is alkali-rich, this can increase the battery's energy density by storing charge on the oxide

248 ction impairment (Short Physical Performance Battery score <=10), and 6% (4%, 9%) were frail and 42%

249 hniques enable electrolyte decomposition and battery self-discharge to be explored in real time, and

250 ypyrrole on a sponge bioanode of a microbial battery, showing rapid biocatalytic current development

251 h anode and cathode materials for sodium-ion batteries (SIBs).

252 Compared to using new batteries, SLB reduced the levelized cost of electricity

253 od pressure (BP), Short Physical Performance Battery (SPPB), Montreal Cognitive Assessment (MoCA), an

254 performance-based Short Physical Performance Battery [SPPB]; continuous version; range 0 to 3; higher

255 Solid-state Li-ion batteries (SSLIBs) have recently attracted substantial a

256 ace area graphene potential usages including batteries, supercapacitors, compression devices, electro

257 nce of illumination-a process we call "solar battery swimming"-lasting half an hour and possibly beyo

258 tom catalytic electrodes design for advanced battery systems is addressed.

259 Advanced battery systems with high energy density have attracted

260 carbon material concepts and carbon-derived battery technologies towards commercial implementation.

261 us operation is often limited by traditional battery technologies with a limited lifespan, creating a

262 lopment beyond that of other next generation battery technologies.

263 om past attempts to develop a (rechargeable) battery technology based on Ca via crucial breakthroughs

264 nd battery engineering, all to propel the Ca battery technology to reality and ultimately reach its f

265 (LMA) is an important milestone for improved battery technology.

266 e LiNi(0.6) Co(0.2) Mn(0.2) O(2) (NCM) || Li batteries that are able to overcome both challenges.

267 extensive neuropsychological/aphasiological battery that assesses a wide range of language and cogni

268 Similar to silicon anodes for lithium-ion batteries, the electrochemical performance of red phosph

269 As the air electrode in zinc-air batteries, the SA-Fe-NHPC demonstrates a large peak powe

270 ture studies should use modern comprehensive batteries to better delineate the natural history of cog

271 capabilities, development of "anode-free" Li batteries to minimize the interaction between LMA and el

272 ensive neuropsychological and aphasiological battery, to identify fundamental domains of post-stroke

273 guided by computation for next-generation Li batteries toward higher energy density and better safety

274 Fast-charging batteries typically use electrodes capable of accommodat

275 ferent from traditional molten-salt Li metal batteries using a pristine metallic Li anode.

276 picture of the SEI formation in lithium-ion batteries using in operando liquid secondary ion mass sp

277 Detailed neuropsychological battery was administered at baseline (n = 227) and the M

278 colate, spinach, infant milk substitute) and battery wastewater.

279 Using a standardized neuropsychological test battery, we assessed processing speed, executive functio

280 ith this knowledge, rechargeable K-air (dry) batteries were successfully demonstrated by employing dr

281 a multilayer (rolled) commercial pouch cell battery were obtained.

282 perfusion, age and cognitive scores (COGNITO battery) were explored.

283 rating this chemistry-agnostic approach into batteries whatever the chemistry within.

284 etrology to study "anode-free" lithium metal batteries where lithium is plated directly onto a bare c

285 sonance (NMR) methods of studying redox flow batteries, which are applied to two redox-active electro

286 Li metal anode for high-temperature Li metal batteries with a simple battery configuration and high s

287 Solid-state batteries with desirable advantages, including high-ener

288 imiting components in the path toward Li-ion batteries with energy densities suitable for electric ve

289 rochemical cells to form solid-state polymer batteries with good interfacial charge-transport propert

290 vides an effective route towards lithium-ion batteries with high energy density for a broad range of

291 Rechargeable lithium-ion batteries with high energy density that can be safely ch

292 there are tremendous demands for lithium-ion batteries with high volumetric energy densities.

293 Here, highly stable lithium (Li) metal batteries with LCO cathode, through the design of in sit

294 g and important solid-state electrolytes for batteries with potential benefits in energy density, ele

295 olecule plays a prescribed role in realizing batteries with unique performance profiles suitable for

296 Herein, we report the first K-CO(2) battery with a carbon-based metal-free electrocatalyst.

297 wo-chamber microbial fuel cell and microbial battery with a solid-state NaFe(II)Fe(III)(CN)(6) (Pruss

298 Here, we report a safe aqueous lithium-ion battery with an open configuration using water-in-salt e

299 is the most promising rechargeable metal-air battery with the combined advantages of low costs, high

300 eries, lithium-sulfur batteries, lithium-air batteries, zinc-air batteries, and aluminum-air batterie