ライフサイエンスコーパス: electronic device

1 assess the robustness of QDCs as a practical electronic device.

2 faces relevant to the response of an organic electronic device.

3 ansport properties of BAs for application in electronic devices.

4 tracted attention for realizing carbon-based electronic devices.

5 nformation that can be monitored by standoff electronic devices.

6 uch as wearable, implantable, and large-area electronic devices.

7 ell-known semiconductors used in optical and electronic devices.

8 pen up opportunities for potential molecular electronic devices.

9 ration with multifunctional and multichannel electronic devices.

10 itable for fabricating flexible and wearable electronic devices.

11 position between specific electrode pairs in electronic devices.

12 ysis, and pattern recognition techniques for electronic devices.

13 ing topological materials in next-generation electronic devices.

14 currents and may enable low-energy-consuming electronic devices.

15 s are promising n-type materials for organic electronic devices.

16 ping next-generation integrated photonic and electronic devices.

17 ension of infection, and cardiac implantable electronic devices.

18 population that is increasingly dependent on electronic devices.

19 interest for use in flexible and transparent electronic devices.

20 dissipationless quantum Hall edge states in electronic devices.

21 ive way to achieve flexibility of functional electronic devices.

22 tions, in particular for a new generation of electronic devices.

23 ctrocatalysts, energy storage materials, and electronic devices.

24 ides which are important for next generation electronic devices.

25 ritical for continuous advancement of modern electronic devices.

26 technology for integration with conventional electronic devices.

27 bling technology for the design of nanoscale electronic devices.

28 how minute chemical modifications can affect electronic devices.

29 integrated RF components in various flexible electronic devices.

30 are meaningful for the development of future electronic devices.

31 biologically and environmentally degradable electronic devices.

32 henomena and in the design of reconfigurable electronic devices.

33 t the fabrication of novel Li-ion controlled electronic devices.

34 mtowatt light signals using micrometer-scale electronic devices.

35 to the ones of unipolar, physically-doped 2D electronic devices.

36 the way toward ion-liquid-gating spintronic/electronic devices.

37 tronics is a potential solution to nanoscale electronic devices.

38 tion, impeding their application in flexible electronic devices.

39 discrete nanodot arrays to fabricate various electronic devices.

40 que properties essential for next-generation electronic devices.

41 te to the fabrication of silicene-based opto-electronic devices.

42 red as viable candidates for next-generation electronic devices.

43 role in the fabrication of efficient organic electronic devices.

44 erformance random access memory for portable electronic devices.

45 in degree of freedom in very fast, low-power electronic devices.

46 molecular chemistry, and the construction of electronic devices.

47 ibilities for fabricating self-powering, bio-electronic devices.

48 perties, particularly at heterointerfaces in electronic devices.

49 ntamination are desired for high-performance electronic devices.

50 e to harness solar energy for powering small electronic devices.

51 itating the full-inkjet-printing of flexible electronic devices.

52 barrier is a key requirement for implantable electronic devices.

53 integration of MOFs as active interfaces in electronic devices.

54 ibers, show potential utility in optical and electronic devices.

55 nses for use as chiral components of organic electronic devices.

56 in people with HFrEF and cardiac implantable electronic devices.

57 tial for developing high-performance organic electronic devices.

58 thesis, biomedical applications, and optical/electronic devices.

59 high-performance and nonvolatile switchable electronic devices.

60 uctivities and mobilities toward novel (opto)electronic devices.

61 step in the utilization of these samples in electronic devices.

62 is important to understand its impact toward electronic devices.

63 ve led to the development of integrated soft electronic devices.

64 rds the development of magnetic, optical and electronic devices.

65 ons in fuel cells, chemical sensors, and bio-electronic devices.

66 y influence the performances of 2D-TMD based electronic devices.

67 y excellent properties and is widely used in electronic devices.

68 eight, portable, and compact next-generation electronic devices.

69 ucial for the design and fabrication of most electronic devices.

70 to develop increasingly complex and powerful electronic devices.

71 are promising candidates for next-generation electronic devices.

72 y be of benefit for waste heat management in electronic devices.

73 (-1) ) and sufficient power to drive various electronic devices.

74 d for fabrication of flexible and disposable electronics devices.

75 however, limit its integration with flexible electronics devices.

76 ong 10 212 patients with cardiac implantable electronic devices, 4570 (45%), 3969 (39%), 3263 (32%),

77 the form of a biofuel cell, with a flexible electronic device - a circuit-board decal fabricated wit

78 ted patients with cardiovascular implantable electronic devices (age, 68.6+/-12.7 years; 63% male), b

79 atic improvement of mechanical robustness in electronic devices along with high-resolution implemente

80 ystalline materials offer for application in electronic devices, although actively developed, are oft

81 interventions and cardiovascular implantable electronic device and cardiac resynchronization therapy

82 ance and reliability of applications such as electronic devices and batteries.

83 esponsive, with the aim to integrate them in electronic devices and better control or mimic different

84 the feasibility of using them in futuristic electronic devices and can provide a physical platform f

85 integration of metal-organic frameworks with electronic devices and chemical sensors' by Ivo Stassen

86 ential for constructing increasingly complex electronic devices and circuits from synthetic semicondu

87 d organs of a plant, we manufactured organic electronic devices and circuits in vivo, leveraging the

88 th industrial revolution marked by a boom of electronic devices and digital technologies.

89 n can facilitate the implementation of oxide electronic devices and discovery of exotic low-dimension

90 understanding the physics of two-dimensional electronic devices and enable new classes of experiments

91 under external forces and can power various electronic devices and even charge a cellphone.

92 transparent substrates as the base for opto-electronic devices and in situ optical measurement syste

93 in solids have been extensively exploited in electronic devices and in the development of spintronics

94 e included patients with cardiac implantable electronic devices and remote monitoring from 2011 to 20

95 ed substrates, will enable their use in opto-electronic devices and scientific investigations.

96 , dust, and surface films that accumulate on electronic devices and skin, including hands.

97 he functionality/energy-efficiency of future electronic devices and smart systems.

98 ks has highlighted the potential of wearable electronic devices and structural biomaterials such as c

99 rapid development of wearable and disposable electronic devices and the rising awareness of environme

100 e on self-powered cardiovascular implantable electronic devices and wearable active sensors.

101 The widespread use of cardiac implantable electronic devices and wearable monitors has led to the

102 tic understanding of structural materials in electronic devices and will serve as inspirations for sm

103 promise in medical implants, reconfigurable electronic devices and/or temporary functional systems.

104 e of applications, including nanocomposites, electronic devices, and all-liquid microfluidic devices.

105 Embedded optical elements, like in glass7, electronic devices, and better electronic-photonic integ

106 eady employed in heavy electric vehicles and electronic devices, and can complement batteries in a mo

107 Integrated circuits are present in all electronic devices, and enable signal amplification, mod

108 neck limiting down-scaling and speed of nano-electronic devices, and harvesting ohmic heat for signal

109 , infections relating to cardiac implantable electronic devices, and indwelling catheters are effecti

110 ess chiral edge currents in energy-efficient electronic devices, and opens up opportunities for devel

111 flexible perovskite solar cells in portable electronic devices; and perspectives of commercializatio

112 This promise has led to only limited electronic device applications due to the lack of an ene

113 potential of the doping method in functional electronic device applications.

114 hat is attracting considerable attention for electronic device applications.

115 ly for decades due to its great potential in electronic-device applications.

116 es for the progress of single-molecule-based electronic devices are a better understanding of the ele

117 terials for fabrication of various 2D and 3D electronic devices are also briefly discussed.

118 ectric efficiency and performance of various electronic devices are also discussed, such as the therm

119 Implications for the use of CP 3 in electronic devices are discussed based on its density of

120 The photonic and electronic devices are integrated on a standard 180 nm c

121 Currently, bioresorbable electronic devices are predominantly fabricated by compl

122 In printed electronics, devices are built layer by layer and conven

123 in patients with cardiovascular implantable electronic devices as a function of both CHA(2)DS(2)-VAS

124 romising candidates for application in (opto)electronic devices as they allow control of the morpholo

125 tant for integration of MOFs into switchable electronic devices as well as in other applications such

126 agnetic means is highly desirable for future electronic devices, as such means typically have ultra-l

127 rformance of conjugated materials in organic electronic devices, as they heavily influence their opto

128 Limited performance and reliability of electronic devices at extreme temperatures, intensive el

129 often earlier in adolescence and the use of electronic devices at night increases, leading to disrup

130 terization, processing and implementation in electronic devices.Atomically precise graphene nanoribbo

131 ly to the development of flexible functional electronic devices based on 2D materials.

132 strategy to create submicron-scale, all-soft electronic devices based on eutectic gallium-indium allo

133 Moreover, intrinsically stretchable electronic devices based on these materials, such as str

134 tallurgical quenching and thermal control of electronic devices, but may also be harnessed to reduce

135 alt (CuPcTs) enables fabrication of flexible electronic devices by low cost inkjet printing.

136 ngs overcome key challenges of bioresorbable electronic devices by realizing lifetimes that match cli

137 to reversibly modulate the output signal of electronic devices by using light as a remote control.

138 ics aims at advancing the miniaturization of electronic devices, by exploiting single molecules to pe

139 More importantly, the thread-like fiber electronic devices can be achieved using a simple reel-t

140 The existing electronic devices can perform inference with high speed

141 eLink database of cardiovascular implantable electronic devices capable of continuous AF monitoring.

142 dical-prescribed devices as well as consumer electronic devices capable of detecting AF.

143 dical therapy and with a cardiac implantable electronic device (cardiac resynchronization therapy or

144 Real-time Raman measurements show these electronic device characteristics are directly affected

145 tanding of the impact of cardiac implantable electronic device (CIED) infection is based on retrospec

146 Most cardiovascular implantable electronic device (CIED) recipients are elderly, have mu

147 Cardiovascular implantable electronic device (CIED) removal and interrogation are r

148 The use of cardiac implantable electronic devices (CIED) is increasing, and their assoc

149 Cardiovascular implantable electronic devices (CIEDs) are associated with procedure

150 tions after placement of cardiac implantable electronic devices (CIEDs) are associated with substanti

151 Cardiac implantable electronic devices (CIEDs) chronic infection diagnosis i

152 Cardiac implantable electronic devices (CIEDs) have been among the best-inve

153 tion of explanted cardiovascular implantable electronic devices (CIEDs), is a higher-yield specimen c

154 onsequences using cardiovascular implantable electronic devices (CIEDs).

155 Electronic devices contain important resources, includin

156 y, we show that plastics casings of electric/electronic devices containing TBBPA contain also a compl

157 A wearable consumer electronic device could provide long-term assessment of

158 ctice to maintain cardiovascular implantable electronic device detection and therapies after LVAD imp

159 are poised to be at the core of low-voltage electronic device development.

160 Among veterans with cardiac implantable electronic devices, device-detected AF is common.

161 an be used as a platform to build integrated electronic devices directly in textiles.

162 als are of importance in developing flexible electronic devices due to relatively large surface force

163 y-storage capability is increasing for power electronic devices due to the rapid development of elect

164 est as elementary building blocks for future electronic devices due to their intrinsic few-nanometre

165 ons for functionalization or construction of electronic devices, due to their specific binding, catal

166 nd applications in emerging field-controlled electronic devices (e.g., Mottronics).

167 e applications such as filtration membranes, electronic devices, electrochemical electrodes, composit

168 ummarizes the most recent reports concerning electronic devices enabled by either of the two primary

169 th elimination of open heart surgery and new electronic devices enabling, for example, multisite paci

170 science and nanotechnology for production of electronic devices, energy generators, biosensors, and b

171 s disciplines of materials science including electronic devices, environmental sensors, energy saving

172 e results suggest a novel class of ballistic electronic devices exploiting the unique transport chara

173 Electronic devices fabricated on such smooth graphene ex

174 patients with HFrEF with cardiac implantable electronic devices favorably influences exercise capacit

175 heir individual roles in computers and other electronic devices, flaws in their properties mean that

176 nt sensors that communicate with and actuate electronic devices for improving plant productivity, opt

177 nt sensors that communicate with and actuate electronic devices for monitoring and optimizing individ

178 spintronic devices in flexible and wearable electronics devices for a plethora of biomedical sensing

179 ials provides low-cost inks enabling printed electronic devices, for example by inkjet printing.

180 dy, as well as specific environments, unique electronic devices formed by "ink-based semiconductors"

181 pt of constructing a complex single-molecule electronic device from two coupled functional units.

182 The presence of a cardiovascular implantable electronic device has long been a contraindication for t

183 Recently, the development of stretchable electronic devices has accelerated, concomitant with adv

184 Mechanical flexibility of electronic devices has attracted much attention from res

185 The current trend in the miniaturization of electronic devices has driven the investigation into man

186 So far, most research on quantum dot electronic devices has focused on materials based on Pb-

187 Flexible electronic devices have attracted a great deal of attent

188 Cardiovascular electronic devices have enormous benefits for health and

189 detrimental to driver safety, with handheld electronic devices having high use rates and risk.

190 of care in patients with cardiac implantable electronic devices; however, relatively little is known

191 sthetic valves (PVs) and implantable cardiac electronic devices (ICEDs).

192 prosthetic valve IE and cardiac implantable electronic devices IE, with improving performance over t

193 prosthetic valve IE and cardiac implantable electronic devices IE.

194 prosthetic valve IE, and cardiac implantable electronic devices IE.

195 79-0.88, 75.2%); and for cardiac implantable electronic devices IE: sensitivity 0.72 (0.61-0.81, 76.2

196 Wireless electronic devices illustrate the capacity to integrate

197 s complication of cardiovascular-implantable electronic device implantation and necessitates removal

198 verse events (death, reintervention, cardiac electronic device implantation, infection, thromboemboli

199 ed patients with de novo cardiac implantable electronic device implantations between January 1, 2000,

200 % (in terms of pieces) of the total stock of electronic devices in 2014.

201 will discuss the use of cardiac implantable electronic devices in heart failure with primary focus o

202 -response programming of cardiac implantable electronic devices in patients with HFrEF on the basis o

203 iew the current applications of self-powered electronic devices in the cardiovascular field, which ha

204 he explosive growth of portable and wearable electronic devices in the fifth-generation (5G) network

205 e explore the past and current quantities of electronic devices in the in-use stock and storage stock

206 ents have been made in the field of flexible electronic devices in the last two decades and will cert

207 rtual substrates opens a path to develop new electronic devices in the More than Moore era and silico

208 the ability to fabricate "bulk" and scalable electronic devices in which function derives from the el

209 The future of cardiac implantable electronic devices includes pacing and perhaps defibrill

210 endocarditis, as well as cardiac implantable electronic devices including pacing devices and left ven

211 port a variety of pencil-paper-based on-skin electronic devices, including biophysical (temperature,

212 racteristics and performance of various opto/electronic devices, including, light-emitting diodes, so

213 Use of electronic devices increased the amount of time spent on

214 Cardiac implantable electronic device infection is a major complication that

215 a 40% reduction of major cardiac implantable electronic device infection without increased risk of co

216 f prosthetic valve IE or cardiac implantable electronic device infection.

217 educing the incidence of cardiac implantable electronic device infection.

218 led subjects with cardiovascular-implantable electronic device infections at multiple institutions in

219 434 patients with cardiovascular-implantable electronic device infections were prospectively enrolled

220 l micropatterning techniques on new types of electronic devices is required to fully utilize the uniq

221 The performance of GaN-on-Silicon electronic devices is severely degraded by the presence

222 Although the safety of these electronic devices is still not fully known, there is ev

223 ovided by metal electrodes, commonly used in electronic devices, it is wise to investigate if curling

224 ducing energy consumption and dissipation in electronic devices, lab-on-a-chip platforms and energy h

225 The potential for cardiac implantable electronic device leads to interfere with tricuspid valv

226 materials for the next generation thin film electronic devices like field-effect transistors, light-

227 Cardiovascular implantable electronic devices measure impedance to assess the struc

228 building blocks is one promising approach to electronic device miniaturization.

229 However, implementation of SiGe in nanoscale electronic devices necessitates suppression of surface s

230 ashing cycles has impeded the fabrication of electronic devices on textile with fully printed 2D hete

231 c radiation produced by a number of everyday electronic devices on the measurements made by an eyemat

232 of the operation state of a micrometer sized electronic device or material.

233 have preexisting cardiovascular implantable electronic devices or cardiac resynchronization therapy,

234 burners, microelectromechanical systems, and electronic device packaging.

235 possible applications, such as novel vacuum electronic devices, particle detectors, accelerators and

236 Electronic devices placed in the gastrointestinal (GI) t

237 tion of multiple functionalities in a single electronic device remains the key challenge.

238 n serviced patients with cardiac implantable electronic device remote monitoring data and at least on

239 were managed with cardiovascular-implantable electronic device removal and reimplantation during the

240 opment of smaller, faster, and more powerful electronic devices requires effective cooling strategies

241 6983 patients undergoing cardiac implantable electronic device revision, replacement, upgrade, or ini

242 tection frequencies in surface wipes of most electronic devices sampled, including devices in which t

243 promising use as wearable and self-healable electronic devices, sensors and structural biomaterials.

244 en used in applications ranging from organic electronic devices, sensors, polymer film additives to m

245 of patients with cardiovascular implantable electronic devices show a relationship between atrial fi

246 The decrease in electronic device size necessitates greater understandin

247 help improve the efficiency of a variety of electronic devices such as solar cells, LEDs, sensors, a

248 In addition, flexible electronic devices such as stretchable displays will be

249 g suitable COF materials for applications in electronic devices such as transistors, photovoltaic cel

250 sustainable power source for cardiovascular electronic devices, such as cardiac pacemakers.

251 ment of advanced features for cardiovascular electronic devices, such as extended life, miniaturizati

252 Electronic devices, such as field effect transistors (FE

253 nt obesogenic environment we often eat while electronic devices, such as smart phones, computers, or

254 central role in the operation of high-speed electronic devices, such as transistors and light-emitti

255 within 1 year following cardiac implantable electronic device surgery.

256 me and thus may be more prevalent in organic electronic devices than previously thought.

257 The design of an ultrathin, conformal electronic device that integrates electrotactile stimula

258 e procedure, or a cardiovascular implantable electronic device that would inhibit TriClip placement.

259 Consequently, energy sources for implantable electronic devices that do not rely on, or at least miti

260 Self-powered implantable medical electronic devices that harvest biomechanical energy fro

261 via printed conductive traces to yield soft electronic devices that may find potential application i

262 evelopment of a new family of ENZ-based opto-electronic devices that take full advantage of the ENZ b

263 etrically, some patients might fear that the electronic devices that they use on a daily basis might

264 ading candidate for the design of functional electronic devices that use single molecules, yet its el

265 Using a ubiquitous electronic device - the field-effect transistor - as a p

266 Striving for applications in oxide-electronic devices, the lateral homogeneity of such samp

267 ls have transmitted molecular information to electronic devices, the potential for bidirectional comm

268 le sensors have been produced on optical and electronic devices, their rigorous operation and equipme

269 nvolving medications and cardiac implantable electronic device therapies.

270 rocess directs the reliability assessment of electronic devices to be frustratingly slow and expensiv

271 a wide range of potential applications from electronic devices to energy storage and conversion.

272 usage in applications ranging from powering electronic devices to harvesting large-scale blue energy

273 ion, along with the rapid development of the electronic devices toward higher speed and performance.

274 isk score in the largest cardiac implantable electronic device trial to date, warranting validation i

275 Our study reports the patterns of electronic device usage by school children, evaluates fa

276 an schools who were surveyed regarding their electronic device usage.

277 structure) and reader characteristics (e.g., electronic device use habits).

278 rvey, spending more than 60 minutes daily on electronic devices was associated significantly with bot

279 To emulate this fundamental process in electronic devices, we developed diffusive Ag-in-oxide m

280 ote monitoring data from cardiac implantable electronic devices, we sought to evaluate if machine lea

281 nd the joint thickness on the reliability of electronic devices; we will illustrate that the thermal

282 Electronic devices were fabricated on thin samples of th

283 ransition of TIPS-P, flexible single-crystal electronic devices were obtained that can tolerate strai

284 trochemical energy storage and shed light on electronic devices where ion-selective behavior plays a

285 will allow us to design a new family of opto-electronic devices where ITO can be used as the cladding

286 from emission sources and dust to hand-held electronic devices, which accumulate phthalates due to i

287 fit from the advantages of gas-plasma/vacuum electronic devices while preserving the integrability of

288 the successful fabrication of metal nanowire electronic devices, while multiscale characterization of

289 troduce a pair of ultrathin, soft, skin-like electronic devices whose coordinated, wireless operation

290 is donor from the drift layer of Ga2O3 power electronics devices will be key to pushing the limits of

291 able the intimate biointegration of wearable electronic devices with human skin in ways that bypass t

292 ctronic properties but also high-performance electronic devices with improved environmental stability

293 ope of enabling low-cost, solution-processed electronic devices with mechanical, optoelectronic, and

294 The use and fabrication of electronic devices with MOF-based components has not bee

295 ture, and open up an opportunity to engineer electronic devices with new functionalities by manipulat

296 What are the strategies to construct electronics devices with engineered phages?

297 t promise to be integrated with the flexible electronic devices, with negligible performance change a

298 the difficulty in powering millimeter-sized electronics devices without using batteries, which compr

299 mplify, mix and modulate sound in one simple electronic device would open up a new world in acoustics

300 ow more versatility in the design of organic electronic devices; yet, controlling the diffusion of do