ライフサイエンスコーパス: stretchable

1 lectrodes, and chemotrodes that are entirely stretchable.

2 e conducting oxides are transparent, but not stretchable.

3 vantages of being light-weight, bendable, or stretchable.

4 with a needle while remaining functional and stretchable.

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

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

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

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

9 electrode, high-performance transparent and stretchable all-solid supercapacitors with a good stabil

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

11 hydrogel system that is extremely tough and stretchable and can be 3D printed into complex structure

12 Stretchable and flexible multifunctional electronic comp

13 e and low-cost method to fabricate extremely stretchable and high-performance electrodes for supercap

14 A general approach toward extremely stretchable and highly conductive electrodes was develop

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

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

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

18 to thin sheets of elastomer generates super-stretchable and reconfigurable metamaterials, exhibiting

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

20 The highly stretchable and transparent Au nanomesh electrodes are p

21 Here we present highly stretchable and transparent Au nanomesh electrodes on el

22 s and muscle-like transducers require highly stretchable and transparent electrical conductors.

23 A highly stretchable and transparent electrical heater is demonst

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

25 sheets and metal-nanowire meshes can be both stretchable and transparent, but their electrical resist

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

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

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

29 loped a simple approach to high-performance, stretchable, and foldable integrated circuits.

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

31 f electronic networks comprised of flexible, stretchable, and robust devices that are compatible with

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

33 Flexible, stretchable, and spanning microelectrodes that carry sig

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

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

36 Such flexible and stretchable architectures can produce metamaterials with

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

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

39 o engineered laminar ventricular tissue on a stretchable chip.

40 The liquid-filled channels function as stretchable circuit wires or capacitor electrodes with a

41 or the semiconductor provides performance in stretchable complementary metal-oxide-semiconductor (CMO

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

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

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

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

46 n one such application, nanomaterial-enabled stretchable conductors (one of the most important compon

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

48 Following this manufacturing strategy, stretchable conductors based on aligned carbon nanotubes

49 Research in stretchable conductors is fuelled by diverse technologic

50 Here we demonstrate stretchable conductors of polyurethane containing spheri

51 The best-known stretchable conductors use polymer matrices containing p

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

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

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

55 g nanomaterial-enabled highly conductive and stretchable conductors.

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

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

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

59 ual mechanics with important implications in stretchable device design.

60 The stretchable device features a serpentine bilayer of gold

61 nts for stretchable electronics) and related stretchable devices (e.g., capacitive sensors, supercapa

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

63 Furthermore, implantable devices or stretchable displays need materials with conductivities

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

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

66 We covalently couple a stretchable elastomer with mechanochromic molecules, whi

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

68 haracterization of all-printed, inexpensive, stretchable electrochemical devices is described.

69 Such stretchable electrochemical devices should be attractive

70 Here, we demonstrate the feasibility of stretchable electrochemical impedance spectroscopy (EIS)

71 hromic device enables the demonstration of a stretchable electrochromically active e-skin with tactil

72 ts to build mechanical metamaterials such as stretchable electrodes, springs, and hinges.

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

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

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

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

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

78 Stretchable electronic systems accommodate strain in var

79 integration of neuromorphic functionality in stretchable electronic systems.

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

81 e range of novel technological solutions for stretchable electronics and optoelectronic devices, amon

82 Flexible and stretchable electronics and optoelectronics configured i

83 cts, sensors, and actuators as components of stretchable electronics and soft machines.

84 Stretchable electronics are attracting intensive attenti

85 Flexible and stretchable electronics are becoming increasingly import

86 have recently gained popularity in flexible/stretchable electronics due to its low cost, simple proc

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

88 imetric temperature indicators with wireless stretchable electronics for thermal measurements when so

89 Research in stretchable electronics involves fundamental scientific

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

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

92 articles assembled by bottom-up methods, and stretchable electronics on a tissue-like polymeric subst

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

94 cost, high precision fabrication of flexible/stretchable electronics or enable the direct writing of

95 The development of stretchable electronics poses fundamental challenges in

96 Stretchable electronics provide a foundation for applica

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

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

99 rs (one of the most important components for stretchable electronics) and related stretchable devices

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

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

102 cations of controlled buckling structures in stretchable electronics, microelectromechanical systems,

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

104 uding medical implants, wearable devices and stretchable electronics.

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

106 to yield a compliant but rugged platform for stretchable electronics.

107 ctical operations of fully power-independent stretchable electronics.

108 repurposing in applications of flexible and stretchable electronics.

109 suggest a valuable route to high-performance stretchable electronics.

110 ity impedes their application in wearable or stretchable electronics.

111 nanodevices, adaptive bioprobes and tunable/stretchable electronics/optoelectronics.

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

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

114 The first stretchable energy-harvesting electronic-skin device cap

115 Stretchable energy-storage devices receive considerable

116 Stretchable fiber and yarn triboelectric nanogenerator a

117 This is demonstrated with two form factors; stretchable film appliques that interface directly with

118 A stretchable, flexible, and bendable random laser system

119 conducting polymer electrodes in a demanding stretchable format, including low electrode impedance an

120 enabled by ionic conductors that are highly stretchable, fully transparent to light of all colors, a

121 Here, we report the fabrication of a stretchable gel of blue phase I, which forms a self-asse

122 ical transmittance of extremely flexible and stretchable graphene oxide coatings with fast response t

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

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

125 The integration of the stretchable, highly tunable resistive pressure sensor an

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

127 Stretchable hydrogel electronics and devices are designe

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

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

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

131 Thus, we demonstrate the feasibility of stretchable intravascular EIS sensors for identification

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

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

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

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

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

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

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

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

140 Such stretchable liquid-crystalline polymers have previously

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

142 We have produced stretchable lithium-ion batteries (LIBs) using the conce

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

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

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

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

147 Tissue is placed directly on a stretchable membrane that, when stretched, fragments the

148 to a glass bead array that is anchored to a stretchable membrane.

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

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

151 A method to produce soft and stretchable microelectronics composed of a liquid-phase

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

153 midity sensors, electroresistive heaters and stretchable multi-electrode arrays for nerve stimulation

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

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

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

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

158 The stretchable network heater is applied on human wrists un

159 It consists of an integrated, stretchable network of sensors that relay information ab

160 A highly stretchable neural interface of concurrent robust electr

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

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

163 able resistive pressure sensor and the fully stretchable organic electrochromic device enables the de

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

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

166 The stretchable perovskite LEDs are mechanically robust and

167 A stretchable photodetector with enhanced, strain-tunable

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

169 A stretchable porous nanocomposite (PNC) is reported based

170 Microstructures with flexible and stretchable properties display tremendous potential appl

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

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

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

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

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

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

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

178 This collection of stretchable sensors and actuators facilitate highly loca

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

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

181 Electronic skins (i.e., stretchable sheets of distributed sensors) report signal

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

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

184 Stretchable solid polymer electrolytes are ideal candida

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

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

187 of pixel pressure sensors on a flexible and stretchable substrate are required.

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

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

190 ch is two times that of the state-of-the-art stretchable supercapacitor under only 100% strain.

191 onventional energy-storage devices, existing stretchable supercapacitors are limited by their low str

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

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

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

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

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

197 buckling to achieve ultralow modulus, highly stretchable systems that incorporate assemblies of high-

198 Ligands and antibodies were much less stretchable than selectins.

199 ics, ranging from transparent, flexible, and stretchable thin film conductors, to semiconducting mate

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

201 s in developing new electronic materials for stretchable thin-film transistors that are mechanically

202 Cells within this system were cultured on a stretchable, thin ( approximately 500 mum) planar membra

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

204 The LEDs are sandwiched in-between a stretchable top and bottom electrode to relieve the mech

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

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

207 The fully stretchable transistors exhibit high biaxial stretchabil

208 Existing stretchable, transparent conductors are mostly electroni

209 Ionic skins are highly stretchable, transparent, and biocompatible.

210 Furthermore, the stretchable triboelectric fibers are mechanically strong

211 The stretchable triboelectric fibers can be reversibly stret

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

213 Here we report the fabrication of highly stretchable (up to 1320%) sheath-core conducting fibers

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

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

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

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

218 elastic wires, from which high-performance, stretchable wire-shaped supercapacitors were fabricated.

219 Stretchable wireless power transmission systems provide

220 ft neural interfaces with fully implantable, stretchable wireless radio power and control systems.

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

222 These stretchable wires can be completely severed with scissor

223 le describes the fabrication of self-healing stretchable wires formed by embedding liquid metal wires

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