ライフサイエンスコーパス: optics

1 l-optical information processing and quantum optics.

2 surements using custom-engineered microscope optics.

3 ithin a single compact assembly of in-vacuum optics.

4 ity to explore many-body physics and quantum optics.

5 pite their tiny brains, by using specialized optics.

6 ns in analogy to the birefringence effect in optics.

7 applications in electronics, mechanics, and optics.

8 ization camera without standard polarization optics.

9 gineering, solar energy conversion, and nano-optics.

10 amplified receivers with or without adaptive optics.

11 further expand their impact on the field of optics.

12 constructed into images without conventional optics.

13 highly versatile new components for adaptive optics.

14 of topological photonics and chiral quantum optics.

15 flat lens based upon multilevel diffractive optics.

16 idden scene that can be modelled through ray optics.

17 what is currently possible with conventional optics.

18 ances in spintronics and solid-state quantum optics.

19 as switches, routers and reconfigurable meta-optics.

20 ge, nano-composites, nano-magnetism, to nano-optics.

21 ge reconstruction or enhancement problems in optics.

22 coherence tomography enhanced with adaptive optics.

23 ns in intelligent sensing, radar and quantum optics.

24 nic standing waves by means of infrared nano-optics.

25 found applications in classical and quantum optics.

26 solutions down to 100 nm without using X-ray optics.

27 ial of azimuthal multiplexing 3D diffractive optics.

28 ys are caused by limitations in conventional optics.

29 ty which have opened up new avenues for flat optics.

30 ematical operation which arises naturally in optics.

31 ve flat waveplates, and adaptive diffraction optics.

32 d with the application of soft components in optics.

33 novel quantum phenomena in extreme nonlinear optics.

34 ral retina of human observers using adaptive optics.

35 etection with standard wide-field microscope optics.

36 solitary wave propagation in nonlinear fibre optics.

37 imaging, optical communications and quantum optics.

38 effect, presenting a unique tool for quantum optics.

39 y of planar-fabricated dielectric integrated optics.

40 devices that couple ionics, electronics, and optics.

41 optical properties is crucial for nonlinear optics.

42 ure fundamental and applied research in nano-optics.

43 ed to detect the position of the haptics and optics.

44 significant practical importance in quantum optics.

45 h fields has not previously been possible in optics.

46 These phenomena are beyond the realm of ray optics.

47 istry, cellular biology, bioengineering, and optics.

48 ve been made to extend these techniques into optics.

49 perties of individual domains with far-field optics.

50 trol coatings to epsilon-near-zero nonlinear optics.

51 ast switching, nano-photonics, and nonlinear optics.

52 urs in vivo using a smartphone with modified optics.

53 nd communications as well as without complex optics.

54 am after propagating through split-and-delay optics.

55 ials in soft matter, medicine, pharmacy, and optics.

56 exciting development to the field of magneto-optics.

57 nitude smaller than the diffraction limit in optics(1).

58 single-electron sources(1), electron quantum optics(2-4), qubit control(5-7), quantum sensing(8,9) an

59 the elements are fixed, including some basic optics (3 lenses and 2 filters), a laser diode and a cus

60 With the advances in optics, a periodic structure called diffraction grating

61 review recent work on incorporating adaptive optics, a technology originally applied in astronomical

62 ation of the Baerveldt (BGI) (Abbott Medical Optics, Abbott Park, IL) or the Molteno3 glaucoma implan

63 We investigated whether coral optics affects variable chlorophyll (Chl) fluorescence m

64 nipulation and placement of components using optics alone promises a route towards increasingly dynam

65 ture in influencing floral light capture and optics, analysing colour, gloss and polarization effects

66 While much is known about how the eye's optics and anatomy contribute to spatial resolution, pos

67 a pathway towards on-chip many-body quantum optics and applications in quantum technology.

68 ultrahigh vacuum environment of the electron optics and detector.

69 stems covers push-pull systems for nonlinear optics and dye-sensitized solar cells, DTT polymers in l

70 which gives rise to high-efficiency quantum optics and electroluminescent devices.

71 e range of technical applications such as in optics and electronics.

72 plications in healthcare, micro-engineering, optics and electronics.

73 red for potential applications in polarizing optics and EO modulation.

74 act nature of the correlation between ocular optics and eye development is not known because of the p

75 interest both for fundamental exploration in optics and for application in functional colloidal inks

76 herent diffractive imaging, non-linear x-ray optics and high field physics, and single molecule imagi

77 ld have enhanced function via gradient-index optics and increased control of lens shape.

78 tterned pixels, or conventional polarization optics and may enable the widespread adoption of polariz

79 head fixation approaches, and innovations in optics and microscopy technology.

80 tonics, including optical sensing, nonlinear optics and nanolasers, where the broad resonant modes ca

81 emained challenging despite advances in nano-optics and nanomaterials.

82 late light are highly sought after in modern optics and nanophotonics.

83 ological opportunities not only for adaptive optics and photonics but also for any platform that can

84 tion in the emerging fields of non-Hermitian optics and photonics, this suggests considering more gen

85 en dissipative systems have been explored in optics and photonics.

86 PLL parameters we reproduce the experimental optics and resistivity over a wide range of doping and n

87 t properties, with applications ranging from optics and sensing to information processing and catalys

88 nsors and a 45-degree field of view, and its optics and sensors are contained within a 2,000 mum x 20

89 s probability that is achievable with linear optics and single photons, making this attractive for in

90 of elasto-optic metamaterials that combines optics and solid mechanics.

91 applications in areas ranging from nonlinear optics and spintronics to biology and pharmaceuticals.

92 th that puts stringent requirements on X-ray optics and their metrology.

93 detection schemes rely on complex free-space optics and typically require high-power lasers as local

94 wn measurements using histology and adaptive optics and/or OCTA, the selected CC parameters must be p

95 concentration, using fluorimeter-compatible optics, and can detect biomolecules at sub-100 fmol mL(-

96 in imaging, photo-dynamic therapy, nonlinear optics, and catalysis are assessed.

97 , wavelength-division multiplexing, enhanced optics, and diode lasers to maximize light capture and m

98 optical communications, microscopy, quantum optics, and microparticle manipulation.

99 pplications in optical manipulation, quantum optics, and optical communication.

100 r super-hard coatings, structural materials, optics, and others.

101 lectrics, barocalorics, magnetics, nonlinear optics, and so on.

102 e variety of multifocal and EDOF IOLs, their optics, and their respective impact on patient quality o

103 artificial muscle, small mechanical devices, optics, and various opto-electro-mechanical devices due

104 gnal contribution originating from the X-ray optics; and (iii) procedures for minimizing the effect o

105 This study used adaptive optics (AO) microperimetry to assess visual sensitivity

106 Adaptive optics (AO) visual simulators based on deformable mirror

107 Our findings open a way to scalable quantum optics applications with TMDCs.

108 ure for infrared optoelectronics and quantum optics applications.

109 Here we present transformation optics applied to thermoelectric phenomena, where therma

110 Classical diffractive optics are 2D diffractive optical elements (DOEs) and co

111 Here, ultrastable electron-optics are combined with a high-speed 2D electron detect

112 line-focused laser and wide-field collection optics are used to excite and collect the fluorescence e

113 Transformation optics, as the underlying mathematical tool, has proven

114 m parametric mode sorting based on nonlinear optics at the edge of phase matching to improve the trad

115 We utilise nano-optics at the sub-5nm scale to reveal rapid (on the mill

116 could find applications in numerous consumer optics, augmented reality components, and all applicatio

117 se results suggest the application of a wave-optics based formalism to correct the deviations.

118 Here we demonstrate that dynamic X-ray optics based on micro-electro-mechanical-system resonato

119 e potential research avenue of SPR and fiber optics based SPR for chemical and biological sensing.

120 ls with potential in sensing, detection, and optics-based applications.

121 Here, we describe a prototype dispersive optics-based array AFM capable of simultaneously monitor

122 Fiber-optics-based cuvetteless micro-spectrophotometry has bee

123 e of the most distinctive aspects of quantum optics, being the trigger of multiple nonclassical pheno

124 ications in areas as diverse as electronics, optics, bioengineering, medicine, and even fashion.

125 ations of inorganic nanoparticle colloids in optics, biology, and energy, their surface chemistry has

126 entally friendly devices and applications in optics, biology, electronics, etc.

127 ormation encoding and combining functions of optics, biomaterials, and environmental interfaces in a

128 ing systems can surpass the limits of linear optics, but nearly all rely on physical media and atomic

129 and color-tunable single emitters in quantum optics, but they have typically suffered from prohibitiv

130 Next, we use microfocusing optics by compound refractive lenses to probe the diffra

131 incorporating both refractive and plasmonic optics, by creating SiO(2) nanospheres fused to plasmoni

132 the governing equations of charged particle optics cannot be solved in closed form.

133 erence microscopy and computational adaptive optics (CAO) to enable the quantitative reconstruction o

134 nanotechnology, biology, medicine, geology, optics, catalysis, art conservation and other fields are

135 w applications spanning flexible electronics/optics, catalysis, responsive coatings, and soft robotic

136 tion, light harvesting materials, non-linear optics, charge storing materials, and homogeneous acid-b

137 In refractive optics, chromatic dispersion is a significant problem an

138 ials-based approach generates 2D diffractive optics composed of 3D nanophotonic lattices that allow s

139 tion of Apoptotic Retinal Cells and Adaptive Optics confocal Scanning Laser Ophthalmoscopy which have

140 of a high-efficiency telescope and follow-up optics crucially improved the link efficiency.

141 tomography (PS-OCT) with a conical scanning optics design.

142 Custom freeform IOL-optics-design may become a promising option for the corr

143 gress made in the hard X-ray split-and-delay optics developments now brings a very promising prospect

144 ns is essential for a more advanced electron optics device.

145 Integrated optics devices are one of the most promising technologie

146 ilar to what has been reported with adaptive optics devices.

147 Its impact in optics due to its interaction with electromagnetic waves

148 a team of several researchers experienced in optics, electronics, digital signal processing, microflu

149 -derived assemblies and materials for use in optics, electronics, optoelectronics, photonics, magneti

150 of soft photonics and biologically inspired optics, emphasizes the ties between the two fields, and

151 ical operators and photonic elements in wave optics enables quantitative analysis of light manipulati

152 challenges in applied nonlinear and quantum optics, enabling manipulation and interaction of quantum

153 and applications across chemistry, physics, optics, energy harvesting, and medicine.

154 ng center experts, retinal histologists, and optics engineers.

155 However, current diamond quantum optics experiments are restricted to single devices and

156 oned challenges, as indicated in recent bulk-optics experiments.

157 by far what is possible with typical linear optics filters, with outstanding performance in isolatin

158 Adaptive optics findings, obtained over the retinal area where th

159 endoscopy (CE) system featuring two advanced optics for 344 degrees -viewing and a prolonged operativ

160 platform, which combines high-energy source optics for improved collision induced unfolding (CIU) ex

161 , current implementations rely on free-space optics for ion control, which limits their portability a

162 The holy grail of reconfigurable optics for microscopy, machine vision and other imaging

163 ncide with hydration events, microstructural optics for reversible readout of sweat loss, and efferve

164 n extension of Fourier optics-matrix Fourier optics-for understanding these devices and apply it to t

165 unctions of the dispersive element and relay optics found in practical Raman and Brillouin spectromet

166 y, a distinct imaging modality for scalable, optics-free mapping of relative biomolecule positions.

167 Advances in molecular biology, optics, genetics, and bioinformatics have opened the doo

168 Recent advances in biology, optics, genetics, and pharmacology have resulted in the

169 y the Wigner model in the 10(-14) s range in optics had to await femtosecond lasers to be detected wi

170 Integrated quantum optics has the potential to markedly reduce the footprin

171 he large-scale manufacturing of dynamic flat optics has the potential to revolutionize many emerging

172 Diffractive optics have increasingly caught the attention of the sci

173 Recent advances in nonlinear optics have revolutionized integrated photonics, providi

174 o break this barrier, we use 15 kHz adaptive optics imaging to noninvasively measure single-cell bloo

175 is near-field information through wide-field optics in a spatially resolved manner, and this function

176 study of non-Hermitian physics and nonlinear optics in high-quality-factor microresonators.

177 Our analysis provides a paradigm for optics in the atomistic near-field.

178 realization of polariton refractive and meta-optics in the mid-infrared by exploiting the properties

179 es not require the fine alignment of complex optics in the THz path.

180 he Catalys femtosecond laser (Abbott Medical Optics, Inc., Santa Ana, CA).

181 Previous research on transformation optics indicated that such absorption cannot easily be i

182 hort pulse widths using methods of nonlinear optics is a well-established technology of modern laser

183 Accessing guided modes by conventional optics is challenging due to the limited spatial resolut

184 A central goal of quantum optics is to generate large interactions between single

185 o ultraviolet light via integrated nonlinear optics is usually hampered by the strong material disper

186 nity structure, which strongly affects ocean optics, is likely to show one of the clearest and most r

187 orth, Texas, USA), or ZA9003 (Abbott Medical Optics Johnson & Johnson Vision, Inc) IOLs were included

188 he-bag implantation of ZCB00 (Abbott Medical Optics Johnson & Johnson Vision, Inc, Abbott Park, Illin

189 material under test, specialized collection optics, large sample areas, spatially uniform excitation

190 nstrated by mid-Infrared (mid-IR) integrated optics made by aluminum nitride (AlN) waveguides on flex

191 However, the much higher frequencies of optics make for very different requirements.

192 We propose a new precision additive freeform optics manufacturing (AFOM) method using an pulsed infra

193 ndamental phenomenon in electromagnetics and optics, material absorption has been extensively investi

194 tential for realizing on-chip transformation optics, mathematical operations and spectrometers, with

195 We present an extension of Fourier optics-matrix Fourier optics-for understanding these dev

196 Geometric electron optics may be implemented in solids when electron transp

197 Unlike any existing adaptive-optics method by applying compensating modulation direct

198 Adaptive optics microperimetry at locations spanning these border

199 The method utilizes a wave optics model to account for the dominant diffraction eff

200 We developed multi-pupil adaptive optics (MPAO), which enables simultaneous wavefront corr

201 readily available building blocks of quantum optics, namely coherent states, single photons, beam spl

202 Despite such interest in nano-optics, no experimental evidence of Fano interference wa

203 a simple analytical model based on Gaussian optics, numerical propagation calculations, and experime

204 ee PhC, respectively, in agreement with wave-optics, numerical simulations.

205 open up new areas of relativistic nonlinear optics of plasmas, impulse IR spectroscopy and pump-prob

206 rogressing mid- and long-wavelength-infrared optics of the atmosphere.

207 Despite its clarity, imperfections in the optics of the eye blur microscopic retinal capillaries,

208 The optics of the eye is the key to a functioning visual sys

209 Our simulation takes into account the optics of the eye, neural transmission and noise, as wel

210 tion by placing a spectral filter behind the optics of the eye, using genetic tools.

211 The sophisticated optics of the lens and its gradient of refractive index

212 The field of optics offers valuable tools to probe the chirality of n

213 This optics-only technique generates images in a single scan,

214 afforded by recent advances in computational optics open up the possibility of creating a computing p

215 We combine adaptive optics ophthalmoscopy with calcium imaging to optically

216 culature (Joseph et al. 2019) using adaptive optics ophthalmoscopy.

217 State-of-the-art adaptive optics optical coherence tomography (AO-OCT) makes it po

218 Procedures: Eyes were examined with adaptive-optics optical coherence tomography (AO-OCT), spectral-d

219 with the unique capabilities of our adaptive optics-optical coherence tomography approach and owing t

220 roughs in multiple fields, including quantum optics, optoelectronics, and biosensing.

221 eviewed, covering four major topics: electro-optics, organic light emitting diodes, organic field-eff

222 al and ancillary testing, including adaptive optics, outcomes in autoimmune retinopathy (AIR) patient

223 nd experiment how frequency domain nonlinear optics overcomes the shortcomings arising from the convo

224 small differences with standard fluorescence optics, particularly in situations where sample volume i

225 including biointerfaces, tissue engineering, optics/photonics, and bioelectronics.

226 a fully-quantum theory of extreme nonlinear optics, predicting quantum effects that alter both the s

227 problem, the quasi-conformal transformation optics (QCTO) method can be adopted to modify the lens'

228 In atomic and molecular optics, radiation pressure can be used to trap or cool a

229 le can be conceptually understood in the ray optics regime using momentum transfer and Newton's secon

230 The success of nonlinear optics relies largely on pulse-to-pulse consistency.

231 Adaptive optics retinal imaging showed no thickening of the arter

232 Adaptive optics scanning laser ophthalmoscope (AOSLO) images of f

233 oped technique based on a dual-beam adaptive optics scanning laser ophthalmoscope to measure changes

234 re imaged with 795 nm excitation in adaptive optics scanning laser ophthalmoscopy (AOSLO) to observe

235 Adaptive optics scanning laser ophthalmoscopy and SD OCT imaging

236 We show that adaptive optics scanning laser ophthalmoscopy can visualize live

237 Imaging with an adaptive optics scanning light ophthalmoscope (AOSLO) enables dir

238 h imaging of the living retina with adaptive optics scanning light ophthalmoscopy (AOSLO) provides mi

239 Adaptive optics scanning light ophthalmoscopy images were acquire

240 l images were acquired with OCT and adaptive optics scanning light ophthalmoscopy.

241 oited in exotic laser systems, new nonlinear optics schemes, and exotic scattering features in open s

242 Recent progress in split-and-delay optics (SDO), which produces two X-ray pulses with time-

243 applications, bridging across transformation optics, sensing, and light harvesting.

244 ce, and CPU) in conjunction with complicated optics should capture, store, and process massive image

245 pose, design, and demonstrate 3D diffractive optics showing this multiplexing effect.

246 Together with the fitted phase plate the optics shows diffraction-limited performance, generating

247 ent branches of physics, including nonlinear optics, spintronics and plasmonics.

248 t in metasurface diffraction, 3D diffractive optics still remains relatively unexplored.

249 Coral optics studies have revealed the presence of light gradi

250 al metamaterials offers potential for active optics such as all-optical switching and light modulatio

251 rengthen numerous attractive applications in optics such as super-resolution imaging, enhanced sponta

252 rmation compared with the standard nonlinear optics techniques that are based on averages over many r

253 ble light (<1mWcm(-2)) with the aid of fiber optics technology.

254 on of glucose by smartphone-integrated fiber optics that overcomes existing technical limitations.

255 ared to other clustering methods (DBSCAN and OPTICS) that were used in previous metabolomics studies.

256 In optics, the abrupt nature of the phase transitions that

257 Without complex optics, the device negated large signal drifts (1/f nois

258 Using an analysis involving geometric optics, the effective prism power (EPP), measured in pri

259 Within linear optics, the system is then equivalent to a periodic arra

260 In quantum optics, the ultimate limit of a weak field is a single p

261 incorporating analogous effects into neutron optics: the generation and detection of neutron beams wi

262 Owing to its high numerical aperture optics, this microscope achieves lateral and axial resol

263 portunities to control two-dimensional moire optics through variation of the twist angle.

264 scheme can be applied to any other focusing optics, thus solving the X-ray optical problem at synchr

265 This technique opens up nonlinear optics to a regime of relaxed phase matching, with the p

266 The adaptation of freeform optics to a sub-wavelength metasurface platform allows f

267 -energy physics-can be strategically used in optics to address this problem.

268 lic metamaterials were initially proposed in optics to boost radiation efficiencies of quantum emitte

269 dextran in brain microvessels) with adaptive optics to compensate for tissue-induced aberrations in t

270 to combat sample motion and applied adaptive optics to correcting sample-induced optical aberrations

271 first successful demonstration of using DVD optics to image DNA molecules with high-speed AFM.

272 ation that generalizes the field of adaptive optics to include object-dependent patterns.

273 macular locations by: (i) marrying adaptive optics to phase-sensitive optical coherence tomography t

274 ser ophthalmoscopy with and without adaptive optics to quantify the 3D distribution and dynamics of m

275 roof-of-principle, we demonstrate the use of optics to solve several Ising Hamiltonians for up to thi

276 We exploit its electro-optics to visualize the appearance, in the absence of ap

277 Here we calculate PTIR spectra via thin-film optics, to identify subtle changes (band shifts, deviati

278 experiments are enabled by applying quantum optics tools to synthetic topological matter (here twist

279 hodology for designing analogues of freeform optics using a silicon nitride based metasurface platfor

280 etector, including mirror source and imaging optics, UV sensitive acquisition modes and revised data

281 e, we introduce a method to use polarization optics via liquid crystal photonics to improve the fovea

282 We used a binocular adaptive optics vision simulator to determine the relative percei

283 ource of spin-orbit coupling to non-paraxial optics vortices.

284 ng of a stainless steel capillary and DC ion optics was designed to conduct ions into the mass spectr

285 nstrate a macroscale (>35 mm) transformation-optics wave bender (293 mm(2)) and Luneburg lens (855 mm

286 By transferring this phenomenon to optics, we demonstrate numerically how the branched flow

287 spatial shifts were only observed in 1947 in optics, whereas the time delay values predicted by the W

288 We first review the progress in ultrafast optics, which has enabled the generation of broadly tuna

289 It combines metalens optics, which modifies the phase of incident light at a

290 mon hybridization theory with transformation optics, which yields an efficient way of simultaneously

291 into nonlinear quantum effects in microwave optics with artificial atoms.

292 c assessments are performed using free-space optics with bulky optical components.

293 display, which pass through simulated human optics with fixational eye movements, followed by cone i

294 ous solubility of diverse drugs by combining optics with fluidics, the single particle analysis (SPA)

295 r advanced adaptive and multifunctional flat optics with merits of high compactness, low loss and bro

296 c photonic platforms for ultrafast nonlinear optics with scalable bandwidth.

297 ed to demonstrate on-chip effects of quantum optics with single atoms in the microwave range.

298 The realization of quantum optics with this prototypical biomolecule paves the way

299 teStar Signature Pro machine (Abbott Medical Optics) with the Ellips FX handpiece and a 0.9-mm bent D

300 Bringing branched flow to the field of optics, with its full arsenal of tools, opens the door t