ライフサイエンスコーパス: stretchable

1 lectrodes, and chemotrodes that are entirely stretchable.

2 with a needle while remaining functional and stretchable.

3 s and the requirements to make these devices stretchable.

4 are robust, highly ionically conductive, and stretchable.

5 ectrically conductive, (3) flexible, and (4) stretchable.

6 the literature on what is meant by the term "stretchable."

7 ith the phase boundary effectively forming a stretchable 1D Schottky junction.

8 As a demonstration, a stretchable (260%) active matrix with integrated electro

9 ique strategy of building ultraconformal and stretchable 2D-materials-based protective skins on the s

10 a fascinating route to generate flexible and stretchable 2D/3D metamaterials and metadevices with het

11 ing from interlocked thermoelectric modules, stretchable 3D thermoelectric generators without substra

12 important progress toward the development of stretchable active-matrix displays.

13 Intrinsically and fully stretchable active-matrix-driven displays are an importa

14 Here, we show for the first time a fully stretchable active-matrix-driven organic light-emitting

15 tial applications in diverse areas including stretchable and bio-integrated electronics, microfluidic

16 The L-EES is a stretchable and breathable composite of nanomembrane ele

17 ELASTicized tissues are highly stretchable and compressible, which enables reversible s

18 s for sensors, actuators, energy harvesting, stretchable and flexible electronics, and energy storage

19 Stretchable and flexible multifunctional electronic comp

20 g electronic materials and devices are soft, stretchable and mechanically conformable, which are impo

21 nd components of such transistors need to be stretchable and mechanically robust.

22 Finally, the combined stretchable and piezoelectric nature of the composite wa

23 anti-dehydration hydrogel-elastomer hybrids, stretchable and reactive hydrogel-elastomer microfluidic

24 These tiny, stretchable and scalable sensors (5 mm x 5 mm x 250 mum)

25 A highly stretchable and sensitive wearable strain sensor which c

26 le hazard avoidance sensing platform that is stretchable and skin-like.

27 nt crosslinking (2.5 mol%), yields extremely stretchable and tough supramolecular polymer networks, e

28 Soft ionic conductors have enabled stretchable and transparent devices, but liquids in such

29 A highly stretchable and transparent electrical heater is demonst

30 of flexible electronics will require highly stretchable and transparent electrodes, many of which co

31 ectroluminescent materials, and hydrogels as stretchable and transparent ionic conductors.

32 array of applications in several domains of stretchable and wearable electronics.

33 -like gold nanowires (v-AuNW) could serve as stretchable and wearable ion-to-electron transducers for

34 respectively, are utilized to design highly stretchable and wearable random laser devices with ultra

35 Stretchable and wearable respiration sensors have recent

36 We introduce here a new type of stretchable and weavable triboelectric fibers with micro

37 e present two types of all-printable, highly stretchable, and inexpensive devices based on platinum (

38 Strong, tough, stretchable, and self-adhesive hydrogels are designed wi

39 various manufacturing processes-with strong, stretchable, and transparent adhesion.

40 rion-clay nanocomposite hydrogels as a soft, stretchable, and transparent ionic conductor with transm

41 arent stretchable conductor, surrounded by a stretchable annular conductor.

42 ) polystyrene sulfonate as a transparent and stretchable anode, a perovskite/polymer composite emissi

43 erent mu-ILEDs, relies on specially designed stretchable antennas in which parallel capacitive coupli

44 Miniaturized, stretchable antennas represent an essential link between

45 Such flexible and stretchable architectures can produce metamaterials with

46 As such, the development of stretchable batteries and supercapacitors has received s

47 There is a strong need in developing stretchable batteries that can accommodate stretchable o

48 n of these stretchable components leads to a stretchable battery with a capacity of 1.1 mAh cm(-2) th

49 Thin, flexible, and stretchable biosensors that are printed on a biocompatib

50 The resultant stretchable BNNT/PDMS composites demonstrate augmented Y

51 the first demonstration of multifunctional, stretchable BNNT/PDMS composites with enhanced mechanica

52 iety of novel applications in future such as stretchable capacitors or conductors, sensors and oil/wa

53 ology is demonstrated by a self-healable and stretchable circuit constructed from Cu-DOU-CPU.

54 Here, an all-stretchable-component sodium-ion full battery based on g

55 Combination of these stretchable components leads to a stretchable battery wi

56 This novel design integrating all stretchable components provides a pathway toward the nex

57 rinted AgNW patterns are used to fabricate a stretchable composite conductor, and a fully printed and

58 iezoelectricity of multifunctional BNNT/PDMS stretchable composites prepared via co-solvent blending

59 tion strategy for preparing an intrinsically stretchable, compressible and bendable anisotropic polyv

60 vered to form liquid-metal-based, stable and stretchable conductive patterns on rigid and soft substr

61 Here, a method to produce highly stretchable, conductive, washable, and solderable fibers

62 of its surfaces with a circular transparent stretchable conductor, surrounded by a stretchable annul

63 effect in conductivity when employed in a 3D stretchable conductor, together with a high conductivity

64 rections in the area of nanomaterial-enabled stretchable conductors and devices are discussed.

65 This property is undesirable for stretchable conductors since such composites may become

66 composite are among the state-of-the-art in stretchable conductors under large mechanical deformatio

67 ite has prospective applications in sensors, stretchable conductors, and responsive thermal interface

68 nics and devices are designed by integrating stretchable conductors, functional chips, drug-delivery

69 Moreover, in marked contrast to other stretchable conductors, the electrical conductance of th

70 hough there has been recent progress towards stretchable conductors, the realization of stretchable s

71 g nanomaterial-enabled highly conductive and stretchable conductors.

72 First, stretchable copolymer membranes that feature outstanding

73 Here, a highly stretchable cross-reactive sensor matrix is demonstrated

74 strate the rapid prototyping capability of a stretchable, crumpled graphene strain sensor and pattern

75 ere attached to 96 well plate tops to create stretchable, culture substrates.

76 iated with an increased accumulation of less stretchable demethylated pectin in the apical wall, wher

77 The stretchable device features a serpentine bilayer of gold

78 ategies that allow spatial integration of 3D stretchable device layouts are also highlighted.

79 However, the application of flexible and stretchable devices exposes materials to dynamic mechani

80 iew begins with a discussion of flexible and stretchable devices of all types, and in particular the

81 for designing and implementing flexible and stretchable devices with strain-engineered functionaliti

82 ular synthesis, have been employed to afford stretchable devices, this review surveys recent advancem

83 g applications, particularly in flexible and stretchable devices.

84 multimodal deformation decoupling through a stretchable DFOS-integrated wireless glove that can reco

85 ed total internal reflection and absorption, stretchable DFOSs can distinguish and measure the locati

86 t of chemically-orthogonal and intrinsically stretchable dielectric materials.

87 ddition, flexible electronic devices such as stretchable displays will be increasingly used in everyd

88 ing, and rolling to demonstrate their use as stretchable displays.

89 The resulting soft and stretchable EGaIn patterns offer a currently unrivaled c

90 e electronics by creating them entirely from stretchable elastomeric electronic materials, i.e., rubb

91 g rubbery electronics, including the crucial stretchable elastomeric materials of rubbery conductors,

92 croarchitected metamaterials, made of highly stretchable elastomers, are realized through an additive

93 Here, we report a new stretchable electrochemical cell-sensing platform based

94 Such stretchable electrochemical devices should be attractive

95 f the most promising strategies for enabling stretchable electrochemical energy storage.

96 has created demand for soft, compliant, and stretchable electrodes and interconnects.

97 ications of copper nanowires in flexible and stretchable electronic and optoelectronic devices.

98 t method for the fabrication of flexible and stretchable electronic circuits.

99 Moreover, intrinsically stretchable electronic devices based on these materials,

100 effect transistors are essential elements of stretchable electronic devices for wearable electronics.

101 Recently, the development of stretchable electronic devices has accelerated, concomit

102 an all-solution processed chameleon-inspired stretchable electronic skin (e-skin), in which the e-ski

103 The approach toward a stretchable electronic substrate employs multiple soft p

104 Stretchable electronic systems accommodate strain in var

105 In contrast, present solutions to prepare stretchable electronic systems are typically confined to

106 integration of neuromorphic functionality in stretchable electronic systems.

107 In the emerging field of stretchable electronics (elastronics), the main challeng

108 r possibilities for passive heat exchange in stretchable electronics and bioinspired robotics, which

109 Flexible and stretchable electronics and optoelectronics configured i

110 Stretchable electronics are attracting intensive attenti

111 Flexible and stretchable electronics are becoming increasingly import

112 nic materials, in particular semiconductors, stretchable electronics are mostly realized through the

113 On the other hand, recent development of stretchable electronics by creating them entirely from s

114 Recently, stretchable electronics combined with wireless technolog

115 loys, show enormous promise to revolutionize stretchable electronics for next-generation soft robotic

116 e easily integrated with the next generation stretchable electronics for realizing low-power, stand-a

117 Nanomaterial-enabled flexible and stretchable electronics have seen tremendous progress in

118 ocess that produces all-printed flexible and stretchable electronics is demonstrated.

119 liquid metals based on gallium for soft and stretchable electronics is discussed.

120 electronics, and the emerging development of stretchable electronics opens a new spectrum of applicat

121 Stretchable electronics outperform existing rigid and bu

122 The development of intrinsically stretchable electronics poses great challenges in synthe

123 ovel, low cost solution for high performance stretchable electronics with broad applications in indus

124 ers, 3D meshed rehabilitation structures and stretchable electronics with designed 3D anisotropic con

125 perties related to soft applications such as stretchable electronics without compromising the mechani

126 Growing interest in soft robotics, stretchable electronics, and electronic skins has create

127 aterials, their applications within soft and stretchable electronics, and future opportunities and ch

128 ording and stimulation, tissue regeneration, stretchable electronics, and mechanical actuation.

129 cular potential applications in wearable and stretchable electronics, energy-harvesting devices based

130 icance that enables applications in flexible/stretchable electronics, organic optoelectronics, and we

131 V plasmonics in biomedical imaging, sensing, stretchable electronics, photoacoustics, and electrochem

132 n advantages over elastomeric material-based stretchable electronics.

133 repurposing in applications of flexible and stretchable electronics.

134 ity impedes their application in wearable or stretchable electronics.

135 uding medical implants, wearable devices and stretchable electronics.

136 performing all the reported state-of-the-art stretchable electronics.

137 ge strains associated with soft robotics and stretchable electronics.

138 ging from cushion modulators, soft robots to stretchable electronics; however, both the manufacturing

139 This flexible and stretchable energy harvesting device is expected to be e

140 e human body necessitates the development of stretchable energy storage devices that can conform and

141 Stretchable energy-storage devices receive considerable

142 Stretchable fiber and yarn triboelectric nanogenerator a

143 the electromechanical properties of a highly stretchable fiber strain sensor made of a CNT/polymer co

144 electromechanical characteristics of highly stretchable fiber strain sensors based on CNT/polymer co

145 key challenge lies in the design of a highly stretchable fiber with high conductivity, facile enzyme

146 opically conductive meanders encapsulated by stretchable films.

147 new concept for arrhythmia treatment using a stretchable, flexible biopatch with conductive propertie

148 A stretchable, flexible, and bendable random laser system

149 ased carbons to fabricate conductive, highly stretchable, flexible, and biocompatible silk-based comp

150 lectrochemical energy storage materials into stretchable form factors.

151 abling lightweight and mechanically flexible/stretchable functions are desirable for numerous e-texti

152 A high-capacity stretchable graphitic carbon/Si foam electrode is enable

153 onsist of twisted assemblies of thin, highly stretchable (>400%) elastomer tubules filled with liquid

154 ses the emergent requirement for a smart and stretchable hazard avoidance sensing platform that is st

155 Poly-LMNs exhibit exceptional performance as stretchable heaters, retaining 96% of their areal power

156 Stretchable high-dielectric-constant materials are cruci

157 eover, living cells can grow directly on our stretchable high-surface area electrodes with strong adh

158 active hydrogel-elastomer microfluidics, and stretchable hydrogel circuit boards patterned on elastom

159 Stretchable hydrogel electronics and devices are designe

160 Dynamic crosslinking of extremely stretchable hydrogels with rapid self-healing ability is

161 r results show that cytoskeletal VIFs form a stretchable, hyperelastic network in living cells.

162 terials are desirable for the fabrication of stretchable implants and microfluidic devices.

163 lting, they became ultra soft, flexible, and stretchable in all directions.

164 rted here is the first step toward designing stretchable inertial microfluidic devices that can be im

165 diverse structural geometries developed for stretchable inorganic electronics are summarized, coveri

166 Over the past decade, the area of stretchable inorganic electronics has evolved very rapid

167 Despite significant advances in 2D stretchable inorganic structures, large scale fabricatio

168 crevices of severely damaged wires to create stretchable interconnects that heal the damage mechanica

169 A transparent, self-healing, highly stretchable ionic conductor is presented that autonomous

170 onductors, the electrical conductance of the stretchable kirigami sheets is maintained over the entir

171 Ds with complex micro-patterns, and foldable stretchable LEDs are demonstrated.

172 EDs with complex micropatterns, and foldable stretchable LEDs are demonstrated.

173 mance far exceeds all reported intrinsically stretchable LEDs based on electroluminescent polymers.

174 The stretchable LEDs consist of poly(ethylene oxide)-modifie

175 A stretchable Li4 Ti5 O12 anode and a LiFePO4 cathode with

176 iguration LIBs, in particular fully flexible/stretchable LIBs, are outlined in detail.

177 Stretchable light-emitting diodes (LEDs) and electrolumi

178 Intrinsically stretchable light-emitting diodes (LEDs) are demonstrate

179 Briefly, it is comprised of a stretchable light-emitting electrochemical cell array dr

180 ytes are ideal candidates for creating fully stretchable lithium ion batteries mainly due to their me

181 research designed to accomplish flexible and stretchable lithium-ion batteries and supercapacitors ar

182 a binder material allows for the creation of stretchable lithium-ion battery electrodes with strain c

183 We show functions and applications of stretchable living sensors that are responsive to multip

184 Technologies that use stretchable materials are increasingly important, yet we

185 able sensor systems composed of flexible and stretchable materials have the potential to better inter

186 WCNTs (as an ion-to-electron transducer) and stretchable materials that have been exhaustively charac

187 ectronics benefit from mechanically soft and stretchable materials to conform to curved and dynamic s

188 ride nanotubes (BNNT) uniformly dispersed in stretchable materials, such as poly(dimethylsiloxane) (P

189 dielectric nano-/microinclusions embedded in stretchable matrices, the limited mechanical compliance

190 me, enabling the microwires to be cured in a stretchable matrix.

191 cutting, has recently enabled the design of stretchable mechanical metamaterials that can be easily

192 rporated into elastomers to fabricate highly stretchable, mechanically robust, soft multifunctional c

193 The ESS made out of thin and stretchable metal and conductive polymer ribbons can be

194 d EGaIn droplets sinter during DEP to form a stretchable metallic microwire that retains its shape af

195 c systems are typically confined to a single stretchable metallization layer.

196 We built a flexible, stretchable microbial fuel cell (MFC) by laminating two

197 paper reports on the proof of concept for a stretchable microfluidic device that can control the len

198 The process utilizes a stretchable mold to produce the desired periodic structu

199 An intrinsically soft and stretchable multicolor display and touch interface is re

200 Here we report stretchable, multiresonance antennas and battery-free sc

201 ) and underwater performance make the bionic stretchable nanogenerator a promising sustainable power

202 iples of electrostatic induction, the bionic stretchable nanogenerator can harvest mechanical energy

203 In this work, we report a bionic stretchable nanogenerator for underwater energy harvesti

204 Underwater applications of a bionic stretchable nanogenerator have also been demonstrated, s

205 skin-inspired mechanically durable and super-stretchable nanogenerator is demonstrated for the first

206 combines a low-modulus matrix with an open, stretchable network as a structural reinforcement that c

207 The composite lamina is stretchable only in one direction due to inextensible co

208 le candidate for novel electromechanical and stretchable optoelectronic devices, and pave a way to co

209 ce integration for mechanically bendable and stretchable optoelectronics will broaden the application

210 es in which every component is intrinsically stretchable or highly flexible.

211 g stretchable batteries that can accommodate stretchable or irregularly shaped applications including

212 ted polymers crucial for the design of soft, stretchable, or flexible electronics.

213 lemented in the first reported intrinsically stretchable organic thermoelectric module.

214 a solution-processed, vertically integrated stretchable organic thin-film transistor active-matrix,

215 , we successfully fabricated a skin-inspired stretchable organic transistor operating under deformati

216 Here, a stretchable organometal-halide-perovskite quantum-dot LE

217 These new wearable sensors, based on stretchable organophosphorus hydrolase (OPH) enzyme elec

218 The stretchable perovskite LEDs are mechanically robust and

219 A stretchable photodetector with enhanced, strain-tunable

220 With intrinsically ultra-stretchable photoluminescent organogels, flexible phosph

221 d future research directions of flexible and stretchable piezoelectric devices are then discussed.

222 the challenge include the exploration of new stretchable piezoelectric materials (e.g., hybrid compos

223 the recent developments in new intrinsically stretchable piezoelectric materials and rigid inorganic

224 signals, the representative applications of stretchable piezoelectric materials and structures in we

225 ovel stretchable structures for flexible and stretchable piezoelectric sensors and energy harvesters.

226 Here, a highly stretchable polymer composite embedded with a three-dime

227 Recent progress on highly tough and stretchable polymer networks has highlighted the potenti

228 y laminating freestanding oxide films onto a stretchable polymer substrate.

229 ush structures and introducing inclusions in stretchable polymeric dielectric materials to improve el

230 With the merits of highly stretchable polymeric matrix and excellent electrical co

231 A stretchable porous nanocomposite (PNC) is reported based

232 d facile processing make Poly-LMNs ideal for stretchable power delivery, sensing, and circuitry.

233 emain challenging; consequently, no reliable stretchable printed circuit board (SPCB) method has esta

234 Microstructures with flexible and stretchable properties display tremendous potential appl

235 ations facilitated by the elastic and highly stretchable properties of the materials.

236 lectric fiber and yarn are difficult to have stretchable property.

237 est cases, the performance metrics of small, stretchable, radio frequency (RF) antennas realized usin

238 l designs of nanomaterials and platforms for stretchable respiration sensors are reviewed.

239 drug-delivery channels, and reservoirs into stretchable, robust, and biocompatible hydrogel matrices

240 set of living materials and devices based on stretchable, robust, and biocompatible hydrogel-elastome

241 ibers and gels, and the use of intrinsically stretchable scaffolds for the polymerization of PEDOT.

242 Here we present a design concept for stretchable semiconducting polymers, which involves intr

243 ) design strategies to achieve intrinsically stretchable semiconductor materials that include direct

244 s stretchable conductors, the realization of stretchable semiconductors has focused mainly on strain-

245 and conformable wearable electronics require stretchable semiconductors, but existing ones typically

246 thods for microfabrication of solderable and stretchable sensing systems (S4s) and a scaled productio

247 esentative nanomaterial-enabled flexible and stretchable sensing systems are presented.

248 An ideal strain sensor should be highly stretchable, sensitive, and robust enough for long-term

249 ides a snapshot on the recent development of stretchable sensors and wearable technologies for respir

250 Therefore, flexible and stretchable sensors combined with low-power silicon-base

251 he sensing mechanisms and design concepts of stretchable sensors for detecting vital breath signals s

252 me a promising route to produce a variety of stretchable sensors, actuators and circuits, thus provid

253 ic devices based on these materials, such as stretchable sensors, heaters, artificial muscles, optoel

254 ess and lifespan of flexible electronics and stretchable sensors.

255 of an octopus, we present a completely soft, stretchable silicone composite doped with thermochromic

256 iar form of fracture that occurs in a highly stretchable silicone elastomer (Smooth-On Ecoflex 00-30)

257 fields of research that require flexible and stretchable silicones.

258 ds such as octopuses have a combination of a stretchable skin and color-tuning organs to control both

259 using semiconductors that are intrinsically stretchable, so that they can be fabricated using standa

260 Stretchable solid polymer electrolytes are ideal candida

261 Here, an ultraconformal and stretchable solid-electrolyte interphase (SEI) composed

262 ions can induce transformation to stable and stretchable solid-liquid (S-L) dual phases on various su

263 ing structure is constructed by suspending a stretchable strain-sensing membrane over a cavity.

264 Here, the development of highly flexible and stretchable (stretchability >15% strain) energy harveste

265 erials (e.g., hybrid composite material) and stretchable structures (e.g., buckled shapes, serpentine

266 inorganic piezoelectric materials with novel stretchable structures for flexible and stretchable piez

267 k-based semiconductors" onto flexible and/or stretchable substrates have become a major research tren

268 ed Kapton film and a serpentine electrode on stretchable substrates is presented.

269 lf-powering and compatible with flexible and stretchable substrates, they can be easily integrated wi

270 k for future developments and challenges for stretchable supercapacitors and batteries.

271 -1), which is among that of state-of-the-art stretchable supercapacitors.

272 mable transformation of two-dimensional (2D) stretchable surfaces into target 3D shapes.

273 These stretchable surfaces transform from flat sheets to 3D te

274 however, demonstrates remarkable control of stretchable surfaces; for example, cephalopods can proje

275 ns, and manufacturing processes for flexible/stretchable system subcomponents, including transistors,

276 ly and integration of energy harvesters into stretchable systems are also discussed.

277 uctor, and a fully printed and intrinsically stretchable thin-film transistor array is also realized.

278 es also need to be mechanically flexible and stretchable, thus posing a significant challenge.

279 We developed entangled link-augmented stretchable tissue-hydrogel (ELAST), a technology that t

280 s of many electronic components to be highly stretchable, to be efficient to fabricate, and to provid

281 A 3D printable and highly stretchable tough hydrogel is developed by combining pol

282 Mechanically durable stretchable trans-istors are fabricated using carbon nan

283 Here, stretchable transistor arrays are patterned exclusively

284 Fully stretchable transistors are subsequently fabricated usin

285 The fully stretchable transistors exhibit high biaxial stretchabil

286 resistance and charge transport of the fully stretchable transistors.

287 Here, we demonstrate highly stretchable transparent wireless electronics composed of

288 Furthermore, the stretchable triboelectric fibers are mechanically strong

289 The stretchable triboelectric fibers can be reversibly stret

290 ing to exceptional structural stability, the stretchable triboelectric fibers show high performance r

291 PEDOT:PSS, however, is only stretchable up to around 10%.

292 repared Zn(Hbimcp)(2)-PDMS polymer is highly stretchable (up to 2400% strain) with a high toughness o

293 ors are flexible and can be made elastically stretchable (up to 30% strain) by over-twisting to produ

294 Furthermore, our stretchable v-AuNW ISEs could be seamlessly integrated w

295 road applications for tissue repair and soft/stretchable/wearable bioelectronics.

296 While the fast advancing stretchable/wearable devices require stability, flexibil

297 e to fabricate, difficult to upscale, or non-stretchable, which limits possible use.

298 r made of elastic, tough hydrogels is highly stretchable while guiding light.

299 Liquid metals have been used for stretchable wires and interconnects, reconfigurable ante

300 ctive circuits, strain and pressure sensors, stretchable wires, and wearable circuits with high yield