ライフサイエンスコーパス: electronics

1 " (a neologism derived from "structure" and "electronics").

2 r cannot be easily replaced (e.g., implanted electronics).

3 ingle-crystal hBN paves the way to future 2D electronics.

4 d promise for powering flexible fabric-based electronics.

5 ing from non-volatile memories and microwave electronics.

6 potential for applications in catalysis and electronics.

7 t interest due to its potential in low-power electronics.

8 ching, and mechanically flexible sensing and electronics.

9 d extraction processes for efficient organic electronics.

10 h production for applications beyond digital electronics.

11 deformations is central to emerging wearable electronics.

12 se in next-generation deformable or flexible electronics.

13 nities for high-performance organic flexible electronics.

14 ssities for applications such as for organic electronics.

15 he development of building blocks in organic electronics.

16 l use of PSeD-U elastomers in bio-integrated electronics.

17 d offer important insights into designing 2D electronics.

18 s in the fields of catalysis, photonics, and electronics.

19 ctivity of the reaction is dictated by arene electronics.

20 t could one day power multitudinous wearable electronics.

21 ques to manufacture compliant and large-area electronics.

22 OS (complementary metal-oxide-semiconductor) electronics.

23 promise of this anisotropic 2D material for electronics.

24 demands for emerging soft and human-friendly electronics.

25 ssociated with soft robotics and stretchable electronics.

26 ergy-storage market, especially for portable electronics.

27 the design of soft, stretchable, or flexible electronics.

28 lectric characteristics for high-performance electronics.

29 t rely on classical cryptography and trusted electronics.

30 ty of vdW magnets to the field of spin-based electronics.

31 d spatially hindered integration of nanotube electronics.

32 avorable solid-state arrangement for organic electronics.

33 ed earlier to their success in organic (opto)electronics.

34 rane voltages embodied in analog solid-state electronics.

35 etection methodology and amenability towards electronics.

36 ors for high-performance large-area flexible electronics.

37 n near-junction thermal management of modern electronics.

38 ety of applications in medicine, energy, and electronics.

39 or arrays, flexible electronics and wearable electronics.

40 define the material foundation for nanowire electronics.

41 technical applications such as in optics and electronics.

42 ive medicine, drug delivery, and soft matter electronics.

43 aics (PV), optoelectronics, sensors, and bio-electronics.

44 romising candidate for flexible and wearable electronics.

45 solutions toward realizing low-cost flexible electronics.

46 otoconversion, and applications in molecular electronics.

47 e applications in catalysis, plasmonics, and electronics.

48 plications that range from catalysis to soft electronics.

49 adable, self-healing, or breathable, on-skin electronics.

50 enabled the development of flexible wearable electronics.

51 ching voltages compatible with standard CMOS electronics.

52 is a fundamental issue for future chip-based electronics.

53 aterial challenges of CPs in bio-interfacing electronics.

54 actical to integrate with actively addressed electronics.

55 new applications in implantable and wearable electronics.

56 y have seldom been used as such in molecular electronics.

57 over elastomeric material-based stretchable electronics.

58 h as magnetic recording devices and flexible electronics.

59 listic applications of halide perovskites in electronics.

60 y scales up the voltage and current to power electronics.

61 applications in smart textiles and wearable electronics.

62 tions would pave a way toward novel flexible electronics.

63 to the limited bandwidth of photodiodes and electronics.

64 promising candidates for versatile wearable electronics.

65 croscale regions of conventionally-patterned electronics.

66 in healthcare, micro-engineering, optics and electronics.

67 is a major obstacle for the down-scaling of electronics(1-3).

68 dsDNA, contrary to the common wisdom in DNA electronics(2-4).

69 laser along with their supporting lasers and electronics(4,7,8,9).

70 plications in soft robotics and self-healing electronics(5-7).

71 This works opens to supramolecular electronics, a concept already exploited in natural orga

72 hods to study how changes in heme access and electronics affect the reaction.

73 Especially, studies in soft electronics aim to attain complete measurement of the bo

74 defined structure is essential to interface electronics and advance their quantum applications.

75 al) arrays are integrated into more consumer electronics and become less expensive.

76 ctronics outperform existing rigid and bulky electronics and benefit a wide range of species, includi

77 emely low, rivaling that of state-of-the-art electronics and biological neurons.

78 ic circuit that is inspired by concepts from electronics and biology.

79 elds, such as wearable electronics, consumer electronics and biomedical devices.

80 At the interface of high-performance electronics and biomolecular self-assembly, such approac

81 cations, from gas sensing and separations to electronics and catalysis.

82 The realization of large-area electronics and circuits strongly relies on wafer-scale,

83 rmation is the progressing implementation of electronics and computer science in chemistry research.

84 chnologies in the construction of film-based electronics and devices are deeply established in the fr

85 ipresence in all electric vehicles, consumer electronics and electric grids relies on the precisely t

86 are extensively studied for applications in electronics and electric power systems.

87 (LIBs) have extensively applied to consumer electronics and electric vehicles (EVs) for solving the

88 ge that limits technologies such as consumer electronics and electric vehicles.

89 This review provides the background on the electronics and electrochemical concepts involved in the

90 chnologies, by combining highly miniaturized electronics and energy harvesters with injectable photom

91 iconducting 2D conjugated polymers for (opto)electronics and energy storage.

92 ions have broad implications in environment, electronics and energy.

93 y guide the rational design of biocompatible electronics and enhance our understanding of how membran

94 demonstrated triboelectrification-controlled electronics and established direct modulation mechanism

95 are important for applications in commercial electronics and fundamental materials research.

96 nate the stress at the interface between the electronics and growing tissue.

97 luding electrochemical energy storage, smart electronics and healthcare.

98 way for local polarization field-controlled electronics and high-performance electromechanical appli

99 mic doping", an important concept in organic electronics and in polythiophene-based solid-state elect

100 platform heterogeneously integrates silicon electronics and inorganic microlight emitting diodes (LE

101 studied since the advent of single-molecule electronics and is now well understood within the framew

102 onic band gap play an important role in opto-electronics and light harvesting.

103 cts and discomfort caused by rigid and bulky electronics and mandatory device connection on active fi

104 the nervous system, empowered by advances in electronics and materials science, has transformed neuro

105 1, but selectivity was low based on alcohol electronics and modest based on alcohol sterics.

106 ead applications of next-generation wearable electronics and multifaceted artificial intelligence sys

107 ially important semiconductors into emerging electronics and optical devices.

108 semiconductors form the foundation of modern electronics and optoelectronics(1-7).

109 which is of profound interest for nanoscale electronics and optoelectronics.

110 ge application of heterogeneously integrated electronics and optoelectronics.

111 d how to control them is critical for future electronics and optoelectronics.

112 ls that have demonstrated potential in photo-electronics and photocatalytic applications.

113 on metal dichalcogenides, are of interest in electronics and photonics but remain nonmagnetic in thei

114 nality of semiconductor devices for advanced electronics and photonics.

115 Demands stemming from consumer electronics and renewable energy systems have pushed res

116 ability, which can power miniature wearable electronics and respond to tiny weight variations.

117 sed to reduce energy consumption or to power electronics and sensors.

118 Combining flexible electronics and silicon ICs yields a very powerful and v

119 meters, the defining role of JTE and PJTE in electronics and spintronics, the origin of ferroelectric

120 The increasingly intimate contact between electronics and the human body necessitates the developm

121 of the graphene-enabled biosensors and oral electronics and their successful applications in human s

122 ly desired for applications such as portable electronics and transportation.

123 as display and image sensor arrays, flexible electronics and wearable electronics.

124 bon monoxide (CO) with the USB-EL-CO (Lascar Electronics), and black carbon with the OT21 transmissom

125 lications including energy storage, flexible electronics, and bioelectronics.

126 The convergence of materials science, electronics, and biology, namely bioelectronic interface

127 bricating multistate electrical switches for electronics, and constructing reconfigurable magnetic so

128 owing interest in soft robotics, stretchable electronics, and electronic skins has created demand for

129 energy harvesting, stretchable and flexible electronics, and energy storage, among others.

130 he sensors and secure wireless data transfer electronics, and machine learning for predictive data an

131 timulation, tissue regeneration, stretchable electronics, and mechanical actuation.

132 of science and technology such as photonics, electronics, and mechanics with a wide range of applicat

133 roelectronics thermal management, high-power electronics, and optoelectronics applications.

134 taics, detectors, infrared imaging, flexible electronics, and other applications.

135 es in interdisciplinary fields of materials, electronics, and photonics.

136 or future thermoelectric and molecular-scale electronics applications.

137 oreover, various complex functional wireless electronics are developed using near-field communication

138 s, in particular semiconductors, stretchable electronics are mostly realized through the strategies o

139 Nonetheless, flexible electronics are not as efficient as silicon ICs for comp

140 Bioinspired electronics are rapidly promoting advances in artificial

141 ometries developed for stretchable inorganic electronics are summarized, covering the designs of func

142 e development of integrated circuits for PHz electronics as well as integrated platforms for attoseco

143 adout could also be interfaced with portable electronics at a standoff distance, potentially enabling

144 rol electronic phenomena to enable lightwave electronics at terahertz or petahertz frequencies and on

145 s, reconfigurable assembly and biodegradable electronics (based on water-soluble papers) are explored

146 olymers in different fields, such as energy, electronics, biomedical, and water treatment, no reviews

147 interface electronic transport for molecular electronics but because such rearrangements are low ener

148 ther hand, recent development of stretchable electronics by creating them entirely from stretchable e

149 Such on-skin electronics can serve as the basis for future multifunct

150 Today's electronics cannot perform in harsh environments (e.g.,

151 The development of electronics capable of interfacing with the nervous syst

152 alcogenides will have broad applications for electronics, catalysis and energy storage.

153 ith emerging applications in energy storage, electronics, catalysis, and other fields due to their hi

154 the fastest growth period in rats, morphing electronics caused minimal damage to the rat nerve, whic

155 Recently, stretchable electronics combined with wireless technology have been

156 rate highly stretchable transparent wireless electronics composed of Ag nanofibers coils and function

157 e design and fabricate multilayered morphing electronics, consisting of viscoplastic electrodes and a

158 ed to many emerging fields, such as wearable electronics, consumer electronics and biomedical devices

159 he cost and performance of solid-state power electronics, conversion to HVDC could be attractive in a

160 ir conditioning and refrigeration as well as electronics cooling applications.

161 Flexible electronics could serve as an ideal platform for persona

162 Miniaturization of electronics demands electromagnetic interference (EMI) s

163 lectrical stimulation based on drawn-on-skin electronics demonstrates accelerated healing of skin wou

164 f several researchers experienced in optics, electronics, digital signal processing, microfluidics, m

165 ials, have received significant attention in electronics, due to their unusual conduction properties

166 amless bilateral communication with consumer electronics (e.g., smartwatch), contextually-relevant (s

167 Lithium-ion batteries, which power portable electronics, electric vehicles, and stationary storage,

168 earch enthusiasm with potential for portable electronics, electrical vehicles, and grid-scale systems

169 are linked in a manner that spans nanoscale electronics, electrochemistry, redox switching, and deri

170 Fiber-based electronics enabling lightweight and mechanically flexib

171 Despite recent advances in wearable electronics, existing EMG systems that measure muscle ac

172 ive applications in solid electrolytes, opto-electronics, ferroeletrics, piezoelectrics, pyroelectric

173 Flexible hybrid electronics (FHE) leverages the strengths of these two d

174 demonstration of a wireless, soft, thin-film electronics for a real-time, reliable assessment of athl

175 nd enable optical-frequency, petahertz (PHz) electronics for high-speed information processing.

176 ormance ultraflexible single-crystal organic electronics for sensors, memories, and robotic applicati

177 nd thermal extremes are critical to advanced electronics for ultrahigh densities and/or harsh conditi

178 ations such as bioelectronics and degradable electronics for which traditional semiconductor fabricat

179 In the recent development of biosensors and electronics, graphene has rapidly gained popularity due

180 ever-growing market of portable and wearable electronics has accelerated development in the construct

181 The field of organic electronics has been prolific in the last couple of year

182 Printing of electronics has been receiving increasing attention from

183 increasing interest in flexible and wearable electronics has demanded a dramatic improvement of mecha

184 st decade, the area of stretchable inorganic electronics has evolved very rapidly, in part because th

185 Electronics has made important advances to emulate neuro

186 The rapid development in wearable electronics has spurred a great deal of interest in flex

187 few flexible Li-CO(2) batteries for wearable electronics have been reported so far.

188 Rubbery electronics have gained increasing interest due to the u

189 Recent advances in molecular electronics have highlighted this deficiency due to the

190 mples of semiconductive MOFs within flexible electronics have not been reported.

191 the prevalent studies on flexible microwave electronics have only focused on individual flexible mic

192 anomaterial-enabled flexible and stretchable electronics have seen tremendous progress in recent year

193 Wearable and implantable bio-integrated electronics have started to gain momentum because of the

194 kind of indispensable components of flexible electronics, have been extensively studied.

195 heart of the functioning of modern advanced electronics; high electron mobility transistors, semicon

196 monitoring during motion shows drawn-on-skin electronics' immunity to motion artifacts.

197 robes, design of implantable ultra-low-power electronics, implementation of high-data-rate wireless t

198 The amalgamation of flexible electronics in biological systems has shaped the way hea

199 he possibility of realizing strain-modulated electronics in centrosymmetric semiconductors, paving th

200 rials and techniques for flexible and hybrid electronics in the domain of connected healthcare have e

201 be a key component of future high frequency electronics in the era of fifth-generation wireless comm

202 able energy solution for distributed on-body electronics in the era of Internet of Things.

203 ffect can be used to mechanically switch the electronics in the nanoscale with fast response (<4 ms)

204 towards the adoption of MET, and the related electronics, in environmental engineering applications.

205 materials design for use in bio-interfacing electronics including composites, conductive hydrogels,

206 cations in interfacing life sciences to nano-electronics, including electronic assays of membrane pot

207 ws the recent progress in developing rubbery electronics, including the crucial stretchable elastomer

208 All-printed electronics, incorporating machine learning, offers mult

209 s today is their dependence on silicon-based electronics, increasing their complexity and unit cost.

210 The bio-integrated electronics industry is booming and becoming more integr

211 lent in light of the development of wearable electronics, IoT devices, and drones.

212 The performance of the printed electronics is demonstrated by using real-time control o

213 his spontaneous chemistry in single-molecule electronics is demonstrated using STM-break junction app

214 th a sensing film in 3D with the transducing electronics is however difficult by conventional photoli

215 key issue for their application in molecular electronics is in the fine-tuning of their electronic pr

216 tenfold and the functional complexity of 2D electronics is propelled to an unprecedented level.

217 which are used as interconnects for wearable electronics, is reported.

218 As the field of molecular-scale electronics matures and the prospect of devices incorpor

219 ical resistance will promote applications in electronics, mechanics, and optics.

220 e is crucially important for devices in nano-electronics, nanophotonics and quantum information.

221 nce, achieving the full potential of on-skin electronics needs the introduction of other features.

222 ith the ever-increasing demand for low power electronics, neuromorphic computing has garnered huge in

223 on on a single silicon chip of the front-end electronics of NMR and ESR detectors.

224 Integration of the sensitivity-relevant electronics of nuclear magnetic resonance (NMR) and elec

225 Morphing electronics offers a path toward growth-adaptive pediatr

226 he potential of this approach for ubiquitous electronics on paper.

227 nts in solution suggests that this effect of electronics on the reaction rate results from an unusual

228 Practical high-speed electronics, on the other hand, usually demand operation

229 aged for applications in areas as diverse as electronics, optics, bioengineering, medicine, and even

230 ttention as a promising approach for tunable electronics/optoelectronics, human-machine interfacing a

231 e-molecule junction is crucial for molecular electronics or spintronics.

232 Stretchable electronics outperform existing rigid and bulky electron

233 of material properties, sensor capabilities, electronics performance, and skin integrations is provid

234 ther increase their applicability in organic electronics, photonics, and artificial photosynthesis.

235 ations in two-dimensional superconductivity, electronics, photonics, and information technologies.

236 Molecular electronics promises a new generation of ultralow-energy

237 emerging technology of colloidal quantum dot electronics provides an opportunity for combining the ad

238 The emergence of wearable electronics puts batteries closer to the human skin, exa

239 ated system of the vehicle together with the electronics required for untethered flight (a photovolta

240 ter dimensions is challenging due to complex electronics requirements, manufacturing limitations, and

241 nt developments in materials, chemistry, and electronics, researchers strive to build cutting-edge bi

242 ithium-ion batteries have aided the portable electronics revolution for nearly three decades.

243 ry, which enabled the launch of the personal electronics revolution in 1991 and the first commercial

244 pace technology, micro-fabrication, flexible electronics, robotics, and bio-integrated devices.

245 nics such as rubbery transistors, integrated electronics, rubbery optoelectronic devices, and rubbery

246 e, owing to its intuitive compatibility with electronics, seamless integration of electrochemical bio

247 complete review of emerging applications in electronics, sensing, spintronics, plasmonics, photodete

248 rial boasting attractive characteristics for electronics, sensors, quantum devices, and optoelectroni

249 Here, we introduce soft, wireless, skin-like electronics (SKINTRONICS) that offers continuous, portab

250 of materials to enhance the performances in electronics, solar cells, catalysis, sensors, and energy

251 es to the emblematic circuits of solid-state electronics: starting from the transistor and progressin

252 Thereafter, various rubbery electronics such as rubbery transistors, integrated elec

253 rical conductivity are critical for flexible electronics, such as electromagnetic interference (EMI)

254 ial solution to energizing energy autonomous electronics, such as internet-of-things sensors, that mu

255 , the recent proliferation of nontraditional electronics, such as wearables, embedded systems, and lo

256 th techniques in widespread use for consumer electronics, suggest a potential for broad adoption in n

257 stomeric electronic materials, i.e., rubbery electronics, suggests a feasible a venue.

258 ications such as anisotropic photodetection, electronics, superconductivity and thermoelectricity is

259 acting intense focus as a material for power electronics, thanks to its ultra-wide bandgap (4.5-4.8 e

260 able the production of scalable biotemplated electronics that are sensitive to local biological envir

261 en displays are an important element to skin electronics that can be applied to many emerging fields,

262 Skin-mounted soft electronics that incorporate high-bandwidth triaxial acc

263 ermanium) have dominated the field of modern electronics, their monolayer 2D analogues have shown gre

264 community for use in the research of organic electronics, there are a number of techniques that are f

265 g possibilities in various fields, including electronics, thermal management, chemical mixing, etc.

266 ignificantly extend the "range" of molecular electronics to >50 nm and avoid the usually strong tempe

267 eat variety of applications ranging from GHz electronics to photonic quantum devices.

268 ry merges microbiology, electrochemistry and electronics to provide a set of technologies for environ

269 The ability of morphing electronics to self-heal during implantation surgery all

270 rage for devices ranging from small portable electronics to sizable electric vehicles.

271 f-Things applications, ranging from wearable electronics to smart packaging.

272 Using benchtop control electronics to test this impedance-based biosensor, it w

273 rectification for fifth-generation wireless electronics, to ultraviolet-visible photodetection.

274 e applicable to designing higher performance electronics, transportation, and aerospace systems.

275 On the other hand, flexible and printed electronics use intrinsically flexible materials and pri

276 he details of structural designs of graphene electronics, use cases of salivary biomarkers, the perfo

277 voltage and power levels required to run Si electronics using common temperature differences.

278 computing, creating flexible and large-area electronics using silicon remains a challenge.

279 opportunities for developing ultrafast opto-electronics using Weyl physics.

280 gn various types of wearable flexible hybrid electronics (WFHE) for advanced human healthcare and hum

281 e introduce a soft, wearable flexible hybrid electronics (WFHE) with integrated flexible sensors and

282 It uses flexible and printed electronics where flexibility and scalability are requir

283 critical building blocks of various flexible electronics, where the wrinkles are usually designed and

284 terface has set a new platform for all-oxide electronics which could potentially exhibit the interpla

285 re, we address this limitation with morphing electronics, which adapt to in vivo nerve tissue growth

286 t the development of multifunctional on-skin electronics, which can passively cool human bodies witho

287 is amenable to integration with miniaturized electronics, which could afford a portable, low-cost, ea

288 ed the nanoscale triboelectric modulation on electronics, which could provide a deep understanding fo

289 , customizable, and deformable drawn-on-skin electronics, which is robust to motion due to strong adh

290 s has been of technical significance in nano-electronics while a challenge remains for generating sup

291 device concept for application in large-area electronics, while the growth technique can potentially

292 elieve that emerging advances in tissue-like electronics will enable minimally invasive devices capab

293 cale up and future development of "2D"-based electronics will inevitably require large numbers of fab

294 The next generation of flexible electronics will require highly stretchable and transpar

295 of-Things and more-electric aircraft require electronics with integrated data storage that can operat

296 ge-scale synthesis and fabrication of 2D TMD electronics with naturally formed TMD/metal vdW interfac

297 However, the research of making on-skin electronics with passive-cooling capabilities, which can

298 ance, ultra-stable metal oxide semiconductor electronics with simple binary compositions.

299 While new polymers that interface digital electronics with the aqueous chemistry of life are being

300 s) are carving a niche for themselves in the electronics world.