ライフサイエンスコーパス: photonics

1 ent frequency mixing integrated with silicon photonics.

2 aps the most ubiquitous component in silicon photonics.

3 ce between performance and sustainability in photonics.

4 'zero-change' approach to the integration of photonics.

5 al for biocompatible and flexible integrated photonics.

6 explored for applications in electronics and photonics.

7 ogies for the convergence of electronics and photonics.

8 a rich history in molecular electronics and photonics.

9 sponses to electrical signals for integrated photonics.

10 its overcoming the diffraction limitation of photonics.

11 ufacturing conflicts between electronics and photonics.

12 scribing kinetics of cyclical systems beyond photonics.

13 er Waals heterostructures in electronics and photonics.

14 is now promising to have a similar impact on photonics.

15 pread development and application of diamond photonics.

16 e to integrate them into solar powered green photonics.

17 offer an attractive approach to miniaturize photonics.

18 as microfabricated ion traps and integrated photonics.

19 rcomes a major barrier in integrated quantum photonics.

20 elatively weak, limiting its applications in photonics.

21 low-power and integrable sources for on-chip photonics.

22 omechanical systems and flexible electronics/photonics.

23 been investigated for decades in optics and photonics.

24 ly attractive properties for electronics and photonics.

25 could prove useful for many applications in photonics.

26 challenging applications such as soft X-ray photonics.

27 the fabrication of nanoscale electronics and photonics.

28 tions technology and fundamental research in photonics.

29 has been considered as a material option for photonics.

30 find applications in quantum electronics and photonics.

31 torage, light generation, microscopy and bio-photonics.

32 rvice lifetime of optics used for high-power photonics.

33 nging from cavity quantum electrodynamics to photonics.

34 diverse applications in nanoelectronics and photonics.

35 gion, is at the interface of electronics and photonics.

36 s in artificial photosynthesis and molecular photonics.

37 ls in pharmaceutics, tissue engineering, and photonics.

38 f electronics and the critical dimensions of photonics.

39 lt from advancements in soft and bioinspired photonics.

40 l biology, biophysics, synthetic biology and photonics.

41 explored in the field of ultrafast nonlinear photonics.

42 generally applied to all passive integrated photonics.

43 , which facilitates a wide range of flexible photonics.

44 on-linear components for electronics and MIR photonics.

45 omising for fast optoelectronics and on-chip photonics.

46 sing approach for increased functionality in photonics.

47 lications such as nanoimaging and integrated photonics.

48 nanoscale electronics, optoelectronics, and photonics.

49 ing biosensing, chiral catalysis, and chiral photonics.

50 ance for TMD applications in electronics and photonics.

51 rformance and potential impact of integrated photonics.

52 undamentally challenging in integrated (nano)photonics, achieving chip-based light non-reciprocity be

53 s huge potential for applications in optics, photonics, adaptive materials, nanotechnology, etc.

54 ause of the large processing bandwidths that photonics allow.

55 werful technique for fundamental research in photonics and across physical and life sciences.

56 been widely utilized in extreme ultraviolet photonics and attosecond pulse metrology.

57 of recent developments in the fields of soft photonics and biologically inspired optics, emphasizes t

58 istic scale for applications in electronics, photonics and biology.

59 hese advanced miniature "luminous pearls" in photonics and biophotonics.

60 l use in a host of applications ranging from photonics and catalysis to encapsulation for drug delive

61 mponents that can be integrated with silicon photonics and complementary metal-oxide-semiconductors (

62 d for applications in colloids, electronics, photonics and display technology.

63 ssible applications in hybrid photovoltaics, photonics and drug delivery.

64 the different length scales associated with photonics and electronics in a single nanoscale device.

65 s become a material of great interest to the photonics and electronics industries due to its numerous

66 importance in various disciplines, including photonics and electronics.

67 fields such as magnetism, superconductivity, photonics and electronics.

68 ntations are of potential value for sensors, photonics and energy-efficient memories.

69 he way for device applications in integrated photonics and information processing using spin-dependen

70 Our results enable new applications in photonics and information technology, and may enable exp

71 and bulk thin films, (ii) bottlebrushes for photonics and lithography, (iii) bottlebrushes for small

72 ptofluidics - the synergistic integration of photonics and microfluidics - has recently emerged as a

73 st because of the applications in catalysis, photonics and nanoelectronics.

74 a metamaterial approach towards topological photonics and offer a deeper understanding of topologica

75 impact in fields such as nano- and ultrafast photonics and optical metrology.

76 ogical insulators have inspired analogues in photonics and optics, in which one-way edge propagation

77 hanical devices and composites, the field of photonics and optoelectronics is believed to be one of t

78 films or substrates are ubiquitously used in photonics and optoelectronics, with glass and plastics a

79 or black phosphorus applications in infrared photonics and optoelectronics.

80 nd controllable dynamics, is a major need in photonics and optoelectronics.

81 ms for numerous applications in electronics, photonics and other areas often requires microassembly o

82 city, preserves the attractive near-infrared photonics and paramagnetism of gold quantum dots, and en

83 lighting its great potential applications in photonics and photovoltaic solar cells.

84 tting edge areas of physics as nonlinear THz photonics and plasmon excitation, because TAS plates not

85 orms, which has spawned the field of silicon photonics and promises to enable the next generation of

86 platform for integrated solid-state quantum photonics and quantum information processing, as well as

87 optical and microwave photons for microwave photonics and quantum optomechanics.

88 oaden the potential of multiferroics towards photonics and thin film acousto-optic devices, and sugge

89 hanical actuators, transistors, solar cells, photonics, and bioelectronics.

90 terials (SBMs) are widely used in catalysis, photonics, and drug delivery.

91 s biomimetic systems, in energy transfer and photonics, and in diagnostics and therapeutics for human

92 address minimal access surgery, ultrasound, photonics, and interventional MRI, identifying areas in

93 with both superconducting qubits and silicon photonics, and its noise performance is close to the qua

94 ering a range of applications in biosensing, photonics, and nanoelectronics.

95 ntial applications in molecular electronics, photonics, and porous nanomaterials.

96 ications that include molecular electronics, photonics, and precursors for nanoporous catalysts.

97 nonlinear transformation optics, topological photonics, and the broader area of surface and interface

98 s will be useful both in traditional silicon photonics applications and in high-sensitivity acousto-o

99 ilitate advances in device architectures for photonics applications in particular.

100 An increasing number of photonics applications make use of nanoscale optical ant

101 s is promising for potential electronics and photonics applications.

102 range, which is relevant for nano-optics and photonics applications.

103 key importance for energy, electronics, and photonics applications.

104 Potential applications in electronics and photonics are also discussed.

105 s or fluids-collectively referred to as soft photonics-are poised to form the platform for tunable op

106 The growing interest to all-dielectric photonics as an alternative optical technology along wit

107 tersection with quantum, thermal and silicon photonics, as well as biomimetic metasurfaces.

108 uld allow for the design of quasicrystalline photonics at multiple frequency ranges.

109 To integrate electronics and photonics at the scale of a microprocessor chip, we adop

110 egrees of freedom that may be applied to any photonics based system.

111 Highly promising photonics-based chemical sensing opened up by the new gu

112 Photonics-based solutions address a challenging scaling

113 The current photonics-based study could be vital in evaluating the f

114 the most challenging goals in silicon-based photonics because bulk silicon is an indirect bandgap se

115 MDM is rarely considered for integrated photonics because of the difficulty in coupling selectiv

116 ir potential applications in spintronics and photonics because of the indirect to direct band gap tra

117 cate nanostructures and wide applications in photonics, biology, nanofluidics, drug delivery, and so

118 ds including cavity quantum electrodynamics, photonics, biosensing and nonlinear optics.

119 hing implications in catalysis, sensing, and photonics, but a generalizable strategy for engineering

120 fer-scale fabrication technology for silicon photonics can be leveraged to form lithium-niobate based

121 ypes of resonant and wave-guiding systems in photonics, cavity quantum electrodynamics and optomechan

122 Integrated photonics changes the scaling laws of information and co

123 d as the lower bound for ultra-dense silicon photonics circuits.

124 In the planar photonics concept, it is the reduced dimensionality of t

125 At increased scale, Neuromorphic silicon photonics could access new regimes of ultrafast informat

126 nsplant the concept of doping to macroscopic photonics, demonstrating that two-dimensional dielectric

127 The term 'photonics' describes a technology whereby data transmiss

128 By exploiting the emerging non-Hermitian photonics design at an exceptional point, we demonstrate

129 ogenides in nanoelectronics, spintronics and photonics devices as they critically depend on the spin-

130 otential for applications in molecular-based photonics devices.

131 ybrid, broadband, atomically precise quantum photonics devices.

132 mance of a wide range of SWG waveguide based photonics devices.

133 These systems have found wide use in photonics, displays and biomedical systems.

134 ient nanoscale mechanical transducers in the photonics domain.

135 Silicon photonics, driven by the incentive of optical interconne

136 est in the fields of organic electronics and photonics, drug discovery, nuclear medicine and complex

137 tein as a sustainable material in optics and photonics, electronics and optoelectronic applications.

138 t after for multiple applications, including photonics, electronics, and drug delivery.

139 ty of applications ranging from catalysis to photonics, electronics, energy harvesting/conversion/sto

140 long been motivated by their applications in photonics, electronics, sensors and microlenses.

141 bes leveraging the maturing field of silicon photonics, enabling massively parallel fabrication of ph

142 esearch frontiers, ranging from electronics, photonics, energy, to medicine.

143 Our method of encoding photonics expertise into an algorithm and applying machi

144 d thin-film waveguide technology and on-chip photonics facilitating next-generation label-free chem/b

145 e is scalable and compatible with integrated photonics for on-chip optical communication technologies

146 towards three-dimensional (3D) integrated Si photonics for on-chip wavelength-division multiplex (3D

147 ng approach to the realization of integrated photonics for visible light using high throughput techno

148 egration is not yet practical using standard photonics foundry processes.

149 Photonics has become a mature field of quantum informati

150 However, shrinking photonics has come at great cost to performance, and ass

151 Silicon photonics has emerged as a leading architecture, in part

152 can be classically simulated, and integrated photonics has emerged as a leading platform for achievin

153 Silicon photonics has emerged as the leading candidate for imple

154 Rapid progress in integrated photonics has fostered numerous chip-scale sensing, comp

155 Integrated photonics has recently become a leading platform for the

156 Neuromorphic silicon photonics has the potential to integrate processing func

157 anics, nano-electromechanics, and integrated photonics have brought about a renaissance in phononic d

158 Advances in photonics have stimulated significant progress in medici

159 Novel materials and devices in photonics have the potential to revolutionize optical in

160 Silicon photonics holds great promise for low-cost large-scale p

161 of a quartz crystal microbalance through the photonics immobilization technique so that limit of dete

162 eloped concepts from conventional optics and photonics in the design of new plasmonic devices.

163 For the success of silicon photonics in these areas, on-chip optical signal-process

164 organic materials prevents the use of "soft-photonics" in applications where strong light confinemen

165 r lasers are widely used for applications in photonics, information storage, biology and medical ther

166 incorporating silicon-based electronics and photonics into fibres.

167 rent element of research and applications in photonics is a beam of light.

168 Photonics is a leading approach in realizing future quan

169 One of the current challenges in photonics is developing high-speed, power-efficient, chi

170 Photonics is frequently regarded as a potential pathway

171 An outstanding challenge in quantum photonics is scalability, which requires positioning of

172 recently developed 3DPS (C9036-02; Hamamatsu Photonics KK, Hamamatsu, Japan) for the measurement of b

173 xposure has profound implications in optics, photonics, lasing and displays and will merit further co

174 use in optics, electronics, optoelectronics, photonics, magnetic device, nanotechnology, and biotechn

175 metamaterials with major implications across photonics, material sciences, and nanotechnology.

176 to colloidal crystals with potential uses in photonics, metamaterials and transformational optics.

177 the way towards the hybridization of silicon photonics, microelectromechanical systems and CMOS signa

178 e temperature change can be used in sensing, photonics, microfluidic, optofluidic and lab-on-a-chip a

179 grate electronics with these CMOS-compatible photonics offer great promise to extend this technology

180 materials comprise the foundation of modern photonics, offering functionalities ranging from ultrafa

181 rmitian physics that paves the way to chiral photonics on a chip.

182 explosion of interest in the integration of photonics on standard electronics platforms, which has s

183 The continued convergence of electronics and photonics on the chip scale can benefit from the voltage

184 However, combining electronics and photonics on the same chip has proved challenging, owing

185 Integrated photonics, on the other hand, although largely responsib

186 romise for applications including integrated photonics, on-chip optical interconnects and optical sen

187 In contrast, almost all integrated photonics operate exclusively in the single-mode regime.

188 subwavelength spaces and are of interest for photonics, optical data storage devices and biosensing a

189 many future applications, including tunable photonics, optomechanical sensors and biomechanical and

190 n-Hermitian degeneracies in fields including photonics, optomechanics, microwaves and atomic physics.

191 lications in metrology, sensing, and quantum photonics, particularly in harsh environments that are c

192 Recent advances in photonics, particularly multi-photon microscopy (MPM) an

193 nversion nanocrystals in biological imaging, photonics, photovoltaics and therapeutics have fuelled a

194 lications in photocatalysis, (photo)sensors, photonics, photovoltaics, and drug delivery demonstrate

195 es and visualization of phenomena related to photonics, plasmonics and nanostructures.

196 haping based on 2D-fluid composites and CMOS photonics platform, while also representing a useful tec

197 broadband 1 x 3 power splitter on a silicon photonics platform.

198 rsed 2D nano-objects on silicon-on-insulator photonics platform.

199 ration with existing silicon electronics and photonics platforms.

200 ies this as an ideal material for integrated photonics platforms.

201 In the current mature status of photonics, polymers hold a pivotal role in various appli

202 within the design rules of a typical silicon photonics process, with a minimum radius of curvature of

203 Integrated photonics provides a miniaturized and potentially implan

204 an example circulant graph using a two-qubit photonics quantum processor.

205 ables a variety of important applications in photonics, quantum information technologies, imaging and

206 nductor nanowires have opened new avenues in photonics, quantum optics and solar energy harvesting.

207 s such as those in nano-electronics and nano-photonics rely on properties of nanocrystals at the indi

208 Many applications in photonics require all-optical manipulation of plasma wav

209 .Effective use of single emitters in quantum photonics requires coherent emission, strong light-matte

210 elength scale have become a central topic in photonics research.

211 erfections in periodic media is paramount in photonics research.

212 In these early stages of photonics, researchers facing an infinite array of possi

213 way to section-by-section analysis of larger photonics resources.

214 ave important implications for the fields of photonics, sensing, energy and information.

215 toms have many applications in areas such as photonics, sensing, medicine and catalysis.

216 re of technological relevance for catalysis, photonics, sensors, and of fundamental scientific intere

217 tant technological applications ranging from photonics, separation, and detection, to multimodal imag

218 an important goal of organic electronics and photonics, since these processes govern such electronic

219 ed include those in polymers, life sciences, photonics, solar cells, semiconductors, pharmaceuticals,

220 lications in quantum information processing, photonics, spintronics, and sensing.

221 lation is far more accessible for chip-scale photonics than previously thought.

222 nversion research explores a new frontier in photonics that could potentially spawn many exciting new

223 However, for silicon photonics, the indirect band gap of silicon and lack of

224 erties highly valuable to areas ranging from photonics to condensed matter physics.

225 arge-scale integration capability of silicon photonics to serve the free-space applications.

226 This work opens-up the advantages of silicon photonics to the integration and scale-up of solid-state

227 re we demonstrate a flexible form of silicon photonics using the transfer-and-bond fabrication method

228 he emerging concept of parity-time synthetic photonics, we experimentally realize spatial Bloch oscil

229 Future optical materials promise to do for photonics what semiconductors did for electronics, but t

230 nonics, which is the magnetic counterpart of photonics, where spin waves are used instead of electrom

231 n the context of non-silicon electronics and photonics, where the ability to re-use the graphene-coat

232 This is not yet true in photonics, where the limited degrees of freedom in mater

233 Engineered quantum systems--notably in photonics, where wavefunctions can be observed directly-

234 custom process to enable the fabrication of photonics, which would complicate or eliminate the possi

235 atic aberrations in metasurface-based planar photonics will find applications in lightweight collimat

236 scale on-chip integration of electronics and photonics with an efficient electric field tuning of lig

237 rsatile strategy to create metasurface-based photonics with diverse optical functionalities.

238 offering architectural choices that combine photonics with electronics to optimize performance, powe

239 ompact lightwave circuits in LN alongside Si photonics with fabrication ease and low cost.

240 e and efficient emitter material for on-chip photonics without the need for epitaxy and is at CMOS co

241 phorus shows promise for optoelectronics and photonics, yet its instability under environmental condi