ライフサイエンスコーパス: optoelectronics

1 ch as the III-V materials typically used for optoelectronics).

2 pplications in the fields of electronics and optoelectronics.

3 re essential for high-performance integrated optoelectronics.

4 the development of the better performance of optoelectronics.

5 hly efficient cathode interlayers in organic optoelectronics.

6 ed to be feasible for future electronics and optoelectronics.

7 ng potential applications in electronics and optoelectronics.

8 on are foundations of modern electronics and optoelectronics.

9 or atomically thin, flexible and transparent optoelectronics.

10 towards achieving functional electronics and optoelectronics.

11 n carrier in next-generation electronics and optoelectronics.

12 al layers play a key role in electronics and optoelectronics.

13 ing performance of prior nanostructure-based optoelectronics.

14 ioprobes and tunable/stretchable electronics/optoelectronics.

15 nformation technology, materials science and optoelectronics.

16 the semi-metallic graphene is attractive for optoelectronics.

17 eposition of quantum-confined thin films for optoelectronics.

18 ncy performance of photoconductive terahertz optoelectronics.

19 ultrathin, high-performance electronics and optoelectronics.

20 g material system for future electronics and optoelectronics.

21 hindered by attributes of existing terahertz optoelectronics.

22 gh-throughput processing of quantum-dot (QD) optoelectronics.

23 horus applications in infrared photonics and optoelectronics.

24 us building blocks of modern electronics and optoelectronics.

25 cations of plasmonic polymers in sensing and optoelectronics.

26 engineered architectures for applications in optoelectronics.

27 ide is crucial to the performance of organic optoelectronics.

28 layers of thin TMDCs in nanoelectronics and optoelectronics.

29 r application in the general area of organic optoelectronics.

30 considered as a very promising material for optoelectronics.

31 ve optical properties and great potential in optoelectronics.

32 pects for future advances in electronics and optoelectronics.

33 m information processing and integrated nano-optoelectronics.

34 as of catalysis, astrochemistry, and organic optoelectronics.

35 ultifunctional materials for electronics and optoelectronics.

36 adio-frequency electronics and most forms of optoelectronics.

37 ir potential applications in electronics and optoelectronics.

38 e for application in next-generation organic optoelectronics.

39 e towards GO-based thin-film electronics and optoelectronics.

40 integrated circuits, medical diagnostics and optoelectronics.

41 for new applications in infrared optics and optoelectronics.

42 aterials to complement graphene for advanced optoelectronics.

43 new pathways towards spin-dependent quantum optoelectronics.

44 est new strategies for achieving 'invisible' optoelectronics.

45 f the critical building blocks for nanoscale optoelectronics.

46 ns the established technology for integrated optoelectronics.

47 ions in high-speed, high-efficiency infrared optoelectronics.

48 uilding blocks for nanoscale electronics and optoelectronics.

49 InP) nanowires to define their potential for optoelectronics.

50 raft other solution-printed perovskite-based optoelectronics.

51 ing intensity of light in displays and other optoelectronics.

52 their applications in solar cells and other optoelectronics.

53 As is of primary importance to space applied optoelectronics.

54 nductors offering new strategies for quantum optoelectronics.

55 emergence of a new field of research coined optoelectronics.

56 mising properties for near- and mid-infrared optoelectronics.

57 -gap semiconductors play the central role in optoelectronics.

58 of key importance to enable high-performance optoelectronics.

59 key cross-cutting issue in photovoltaics and optoelectronics.

60 ry, anion sensing, photodynamic therapy, and optoelectronics.

61 mising applications in the area of terahertz optoelectronics.

62 d its applications, e.g., in spintronics and optoelectronics.

63 or emergent technologies beyond conventional optoelectronics.

64 pealing candidates for quantum computing and optoelectronics.

65 promising candidates for nanoelectronics and optoelectronics.

66 ductors with applications in electronics and optoelectronics.

67 carriers may enable the development of novel optoelectronics.

68 rest for energy storage, nanoelectronics and optoelectronics.

69 promising building blocks for new generation optoelectronics.

70 potential applications in nanophotonics and optoelectronics.

71 e dynamics, is a major need in photonics and optoelectronics.

72 lications such as in bioimaging, sensing, or optoelectronics.

73 rties for potential applications in flexible optoelectronics.

74 indirect bandgap limits the applications in optoelectronics.

75 s, including gas separations, catalysis, and optoelectronics.

76 transient or implantable bioelectronics and optoelectronics.

77 uble perovskites for photovoltaics and other optoelectronics.

78 Our results may blaze a trail to PHz-rate optoelectronics.

79 locks for applications in photocatalysis and optoelectronics.

80 e spacing compatible with high-speed silicon optoelectronics.

81 ke membranes, sensors, molecular sieves, and optoelectronics.

82 ssential for next-generation electronics and optoelectronics.

83 anic semiconductor with potential in organic optoelectronics.

84 ind exciting applications in electronics and optoelectronics.

85 ms forms the basis of modern electronics and optoelectronics.

86 miconducting transport hamper application in optoelectronics.

87 catalysis, electrochemistry, electronics and optoelectronics, among others) as well as for the prepar

88 neering in Mo(1-x)WxSe2 alloy monolayers for optoelectronics and applications based on spin- and vall

89 erials are promising candidates for advanced optoelectronics and are used in light-emitting diodes an

90 ions in 2D beam steering, spectrum scanning, optoelectronics and beyond.

91 proach to controllably alter GO band gap for optoelectronics and bio-sensing applications.

92 ntageous in potential nanoscale electronics, optoelectronics and biochemical-sensing applications.

93 en key to its widespread adoption in organic optoelectronics and biotechnology.

94 h applications in very diverse areas such as optoelectronics and biotechnology.

95 e, which makes GO an attractive material for optoelectronics and biotechnology.

96 chemical properties, with the corresponding optoelectronics and catalysis application being actively

97 have a potential to be employed in sensing, optoelectronics and catalysis.

98 promise as flexible electrodes for wearable optoelectronics and energy devices-exemplified by its us

99 imensional layered crystal that is ideal for optoelectronics and flexible devices.

100 e a broad range of potential applications in optoelectronics and imaging, but their photon-conversion

101 sign the next generation of high-performance optoelectronics and integrated flexible circuits by opti

102 can enable novel two-dimensional devices for optoelectronics and light harvesting.

103 wo dimensional materials for applications in optoelectronics and nanoelectronic devices.

104 te materials, chemical sensing, biomedicine, optoelectronics and nanoelectronics.

105 eteronanostructures emerging in the field of optoelectronics and nanophotonics.

106 otential for thin-film electronics, infrared optoelectronics and novel devices in which anisotropic p

107 active, layered materials promising for fast optoelectronics and on-chip photonics.

108 properties applicable to different kinds of optoelectronics and photonic devices.

109 ally thin black phosphorus shows promise for optoelectronics and photonics, yet its instability under

110 edicine and current applications in enhanced optoelectronics and photovoltaics.

111 facilitated its move to the forefront of the optoelectronics and power-electronics industries.

112 nanotubes (SWNTs) in order to broaden their optoelectronics and sensing applications has been a chal

113 cal transport, which is crucial in nanoscale optoelectronics and single-molecule electronics.

114 be multimodal building blocks of integrated optoelectronics and spintronics systems.

115 ics of spins, with applications ranging from optoelectronics and spintronics, to quantum information

116 ental role in the future of nanoelectronics, optoelectronics and the assembly of novel ultrathin and

117 able the continued advancement of perovskite optoelectronics and to the improved reproducibility thro

118 gating, potentially finding applications in optoelectronics and valleytronics.

119 ronics, three-dimensional and/or curvilinear optoelectronics, and bio-integrated sensing and therapeu

120 for some applications, such as electronics, optoelectronics, and electrocatalysis, are also presente

121 fabricate suitable devices for electronics, optoelectronics, and energy conversion.

122 de range of fields such as microelectronics, optoelectronics, and energy storage.

123 e (MoS2) structures, in various electronics, optoelectronics, and flexible devices requires a fundame

124 n great potential for nanoscale electronics, optoelectronics, and photonics.

125 proving the performance of many electronics, optoelectronics, and photovoltaic devices.

126 eived applications, such as nanoelectronics, optoelectronics, and solar energy conversion, interfacin

127 ield effect transistors, low power switches, optoelectronics, and spintronics.

128 class of model nanomaterials for catalysis, optoelectronics, and the bottom-up assembly of true mole

129 w research paths in hybrid magneto-molecular optoelectronics, and the optical detection of spin physi

130 in flexible/stretchable electronics, organic optoelectronics, and wearable electronics.

131 sing candidates for flexible and transparent optoelectronics applications due to their direct bandgap

132 to infrared suggest possible energy-variable optoelectronics applications in pressurized transition-m

133 interactions has important implications for optoelectronics applications of layered materials.

134 ve feature of semiconductor quantum dots for optoelectronics applications.

135 Strain-gated flexible optoelectronics are reported based on monolayer MoS2 .

136 w opportunities in textile photovoltaics and optoelectronics, as exemplified by their photovoltaic pr

137 and low densities, and they may be useful in optoelectronics, as photocatalysts, or in the removal of

138 d and observed, opening up opportunities for optoelectronics, bio-sensing and other mid-infrared appl

139 operties and their potential applications in optoelectronics, biological imaging and therapeutics, fl

140 potential applications of these materials in optoelectronics, biological imaging, and energy conversi

141 isciplines as diverse as tribology, geology, optoelectronics, biomechanics, fracture mechanics, and n

142 nsors, large area sensor array, and tailored optoelectronics, brought intensive research on next gene

143 Triplet excitons are ubiquitous in organic optoelectronics, but they are often an undesirable energ

144 silicon for next-generation electronics and optoelectronics; but its zero bandgap associated with Di

145 an integral part of modern electrocatalysis, optoelectronics, capacitors, metamaterials and memory de

146 riety of applications including electronics, optoelectronics, catalysis, and energy.

147 large lattice mismatches for use in optics, optoelectronics, catalysis, or bioimaging.

148 their practical application in electronics, optoelectronics, composite materials, and energy-storage

149 Flexible and stretchable electronics and optoelectronics configured in soft, water resistant form

150 d for further applications in electronic and optoelectronics devices.

151 ons within individual two-terminal nanoscale optoelectronics devices.

152 including imaging, sensing, cancer therapy, optoelectronics, display, catalysis, and energy.

153 such as molecular electronics, data storage, optoelectronics, displays, sacrificial templates and all

154 al candidate for other applications, such as optoelectronics, drug delivery systems and even lithium-

155 MoS2, hold great promise for electronics and optoelectronics due to their distinctive physical and el

156 for these materials in solar cells, infrared optoelectronics (e.g. lasers, optical modulators, photod

157 ncluding catalysis, sensing, photochemistry, optoelectronics, energy conversion and medicine.

158 o contrive next-generation chemical sensors, optoelectronics, energy harvesters, and converters.

159 various applications including electronics, optoelectronics, energy storage devices, and so on.

160 aging, security protection, optical display, optoelectronics for information storage, and cell stimul

161 owing need to integrate such components with optoelectronics for telecommunications and computer inte

162 The approach uses wafer-scale optoelectronics formed in unusual, two-dimensionally com

163 sults demonstrate that prior to their use in optoelectronics further surface engineering of tin chalc

164 rmance of silicon-based electronics, silicon optoelectronics has been extensively studied to achieve

165 ull potential of graphene in electronics and optoelectronics, high-quality graphene patterns on insul

166 s bioimaging, biomedicine, photovoltaics and optoelectronics, in addition to being inexpensive additi

167 als and review some of their applications in optoelectronics, including lasing and photodetection, an

168 many important applications in electronics, optoelectronics, information processing, catalysis, biom

169 nsfer complex system where the magnetism and optoelectronics interact.

170 s and composites, the field of photonics and optoelectronics is believed to be one of the most promis

171 h as solar cells, OFETs, molecular wires and optoelectronics just to name a few.

172 increasingly in numerous disciplines such as optoelectronics, microfabrication, sensors, tissue engin

173 ng approach for electronics, plasmonics, and optoelectronics nanodevices.

174 Modern optoelectronics needs development of new materials chara

175 ich may find applications in next-generation optoelectronics or photovoltaics.

176 nd materials for use in optics, electronics, optoelectronics, photonics, magnetic device, nanotechnol

177 een studied to develop novel applications in optoelectronics, photovoltaics and green chemistry.

178 , but also in applications of plasmonics for optoelectronics, photovoltaics and related technologies.

179 great promise for potential applications in optoelectronics, photovoltaics and thermoelectrics.

180 oble metals are promising for application in optoelectronics, plasmonics and renewable energy.

181 ery small regions could have applications in optoelectronics, plasmonics and transformation optics.

182 With this in mind, a purpose-built optoelectronics probe station capable of simultaneous op

183 a comprehensive study on the electronics and optoelectronics properties of the AlN/GaN DA for mid- an

184 interest for their visible and near-infrared optoelectronics properties.

185 Custom laser optoelectronics provide sub-nanometer and near-microseco

186 sible applications in low-power spintronics, optoelectronics, quantum computing and green energy harv

187 m shift from hard to flexible, organic-based optoelectronics requires fast and reversible mechanical

188 d these materials to the forefront of modern optoelectronics research.

189 operties that have potential applications in optoelectronics, sensors, and imaging.

190 cludes flexible and transparent electronics, optoelectronics, sensors, electromechanical systems, and

191 s that are relevant for fields as diverse as optoelectronics, solar energy conversion, and photobiolo

192 emely difficult to achieve using established optoelectronics technologies, owing to the intrinsically

193 roduce an injectable class of cellular-scale optoelectronics that offers such features, with examples

194 f these materials in organic electronics and optoelectronics, the construction of oligothiophene-base

195 ay critical roles in today's electronics and optoelectronics, the introduction of active heterojuncti

196 Following its success in organic optoelectronics, the organic doping technology is also u

197 The emergence of optoelectronics, the recently shown possibility of stron

198 ng thermal management in nanoelectronics and optoelectronics, thermoelectric devices, nanoenhanced ph

199 Owing to their promise in photocatalysis and optoelectronics, titanium based metal-organic frameworks

200 inorganic fluorophores for applications from optoelectronics to biology.

201 ranging from quantum information science and optoelectronics to high-resolution metrology.

202 pplications spanning from smart materials to optoelectronics to quantum computation.

203 ntal interest in research areas ranging from optoelectronics to the physics of quantum confinement.

204 broad scope of applications in electronics, optoelectronics, topological devices, and catalysis.

205 considerations) yield a convenient tool for optoelectronics when the radiation field is treated clas

206 rganic components have attracted interest in optoelectronics, where high-efficiency devices with mini

207 nsulators) has ushered in an era of flatland optoelectronics whose full potential is still being arti

208 applicability in the fabrication of flexible optoelectronics with tunable light scattering effects by

209 ructures provide a route to electronics (and optoelectronics) with extremely high levels of stretchab

210 rates are ubiquitously used in photonics and optoelectronics, with glass and plastics as traditional