ライフサイエンスコーパス: optical property

1 nd the engineering of surface morphology and optical property.

2 nd-gap modification which exhibit tailorable optical properties.

3 ight-membered ring with their solution-state optical properties.

4 es with prominent handedness, that is, chiro-optical properties.

5 n's structural characteristics and intrinsic optical properties.

6 ations in the linker stacking geometries and optical properties.

7 advantage of their size and shape-dependent optical properties.

8 -C(3) N(4) ) possesses unique electronic and optical properties.

9 lass of materials with unique electronic and optical properties.

10 ptoelectronic devices due to their excellent optical properties.

11 nship between gate-controlled electronic and optical properties.

12 lt of their tunable morphology and intrinsic optical properties.

13 through which to tailor their electrical and optical properties.

14 plemented in media with periodically varying optical properties.

15 from screening the polymer film ground state optical properties.

16 ence assay performance beyond differences in optical properties.

17 morphology, which has a direct effect on the optical properties.

18 th useful electrical, magnetic, thermal, and optical properties.

19 formation of cloud droplets, and hence cloud optical properties.

20 eir intrinsic magnetic, electrochemical, and optical properties.

21 ls that exhibit extraordinary electrical and optical properties.

22 iomedical applications with superior in vivo optical properties.

23 s to investigate their unique size-dependent optical properties.

24 ized for their structural, morphological and optical properties.

25 y applications owing to their electrical and optical properties.

26 field provides a new method to extend their optical properties.

27 entimeters) and heterogeneous electrical and optical properties.

28 anotubes (SWNTs) offer unique electrical and optical properties.

29 ers, which helps achieve good electronic and optical properties.

30 structural coloration often yields emergent optical properties.

31 signals or distorted by variations in tissue optical properties.

32 ectronics due to their unique electronic and optical properties.

33 ove 850 degrees C without degradation of its optical properties.

34 d for decades, including how it manifests in optical properties.

35 uding excitons and trions, that dominate the optical properties.

36 f membrane textures, surface chemistries and optical properties.

37 nd their complex viewing-direction-dependent optical properties.

38 s are fascinating molecules with interesting optical properties.

39 ugates with slightly modified and adjustable optical properties.

40 vealed Kleinman symmetry-forbidden nonlinear optical properties.

41 e sigma-conjugated bridge on the chromophore optical properties.

42 which leads to unique materials with special optical properties.

43 d attention because of their highly emissive optical properties.

44 GaS(2) , a compound known for its non-linear optical properties.

45 of their desirable mechanical, thermal, and optical properties.

46 cle conformation, and how that affects their optical properties.

47 r possessing highly contrasting electric and optical properties.

48 bility (pH, lipid oxidation, lipolysis), and optical properties.

49 s challenging to predictively understand BrC optical properties.

50 yloids have unique structural, chemical, and optical properties.

51 nd strength) and interesting physical (e.g., optical) properties.

52 weathered rock where physical, chemical and optical properties abruptly change.

53 Anisotropic optical properties also give rise to a magnetic writing

54 tures (e.g. intact wood patterns), excellent optical properties (an average transmittance of ~ 80% an

55 Due to their interesting optical properties and biological compatibility, gold na

56 mbiguity and their influence on vibrational, optical properties and carrier dynamics are investigated

57 indings underscore the stacking-order driven optical properties and carrier dynamics of ReS(2) , medi

58 spacer layer, which changes the metamaterial optical properties and causes a localized increase in em

59 sition method has a significant influence on optical properties and composition of the films, but neg

60 The optical properties and excited state deactivation mechan

61 cited carrier lifetime demonstrates that the optical properties and excited state relaxation are high

62 plications for determining the origin of DOM optical properties and for enhancing our collective unde

63 rticle spectroscopy in revealing the diverse optical properties and functionalities of nanomaterials,

64 g to direct electronic bandgaps, distinctive optical properties and great potential in optoelectronic

65 perovskites, which have shown extraordinary optical properties and immense potential in light emissi

66 s the interplay between linear and nonlinear optical properties and laser energy-material coupling.

67 aspects of conjugated polymer nanoparticles optical properties and phenomena, and discuss the curren

68 that the sensitivity of cloud microphysics, optical properties and shortwave radiative effects to th

69 In addition, strategies for enhancing optical properties and stabilities of LFHP NCs as well a

70 hts into the effect of the Pt dopants on the optical properties and stability of the cluster.

71 theory calculations support the trend in the optical properties and the 1D electronic nature of the s

72 e the correlation between nanostructures and optical properties and the delicate research strategies

73 grand evolution from nonscalable to scalable optical properties and their mechanisms will greatly dee

74 ography), a non-invasive approach to measure optical properties and three-dimensional morphology of l

75 o achieve a synergy among their magnetic and optical properties and to enable their application in pr

76 ic macrocycles incorporated with interesting optical properties and tubular-shaped cavities are able

77 tune physical properties, such as nonlinear optical property and ferroelectricity, of some specific

78 devices with high optical efficiency, stable optical properties, and easy miniaturization, facilitati

79 asis on their crystal structures, synthesis, optical properties, and environmental stabilities (e.g.,

80 lling the NCF dimensionality, modulating the optical properties, and improving the thermal stability.

81 mmetry, energy level structure, magnetic and optical properties, and mutual interactions have been po

82 the density of states (DOS), band structure, optical properties, and stability of phases are also dis

83 Synthesis, optical properties, and study of the sensing mechanism o

84 lins with consequences for NMR spectroscopy, optical properties, and vibrational spectroscopy.

85 oms) show both size- and structure-dependent optical properties; and (iii) large-sized gold NCs (ca.

86 Optical properties appear to be particularly predetermin

87 the effects of CdS shell coating on the core optical properties are different between SQDs and RQDs.

88 boctahedral kernel, and correspondingly, the optical properties are dramatically changed.

89 um materials with topological electronic and optical properties are essential for realizing quantized

90 The electronic and optical properties are greatly diversified by the buckle

91 llizable when meticulously designed, and the optical properties are more affected at the single atom

92 size and shape is still in its infancy, and optical properties are not yet at the same level as othe

93 These optical properties are observed in MeCN solution and the

94 uctor nanostructures with attractive electro-optical properties are promising candidates for the cons

95 (ca. <50 Au atoms) are nonscalable as their optical properties are strongly dependent on the structu

96 ons) showing the evolution of electronic and optical properties as a function of composition.

97 ay side of PBI led to significant changes in optical properties as compared to the model PBIs (M(1) a

98 llic structures lead to distinct wetting and optical properties as well as surface-enhanced Raman sca

99 icle-based materials and devices with unique optical properties at the macroscale.

100 nt modification in electrical resistance and optical properties being capable of multi-modal readout.

101 reening quantum dots not only based on their optical properties, but also their surrounding surface t

102 h crystalline quality with excellent electro-optical properties, but at prohibitive costs and through

103 y fabricated from solutions exhibit the same optical properties, but with improved PLQY of 36%, for a

104 e, we investigate the grand evolution of the optical properties by comparing the steady-state absorpt

105 s that have the ability to reversibly change optical properties by electric charge insertion/extracti

106 The tunable optical properties by precise control of WS2 layers coul

107 several research fields where their superior optical properties can make differences.

108 lymer LED array and demonstrate its improved optical properties compared with a purely inorganic micr

109 rophase gold nanorods demonstrate a distinct optical property compared to that of the conventional fc

110 ctor alloys offer a uniquely broad pallet of optical properties, complementary to those of existing m

111 que group of materials featuring exceptional optical property contrast upon a solid-state phase trans

112 (0.014-0.041 mug/ml in phantoms), and (III) optical-property corrected PpIX estimates were more high

113 tion kinetics, structure, and electronic and optical properties depend on material thickness and late

114 en developed on the nanoscale with excellent optical properties (e.g., semiconductor quantum dots, pe

115 ous due to its highly tunable electrical and optical properties, ease of fabrication into multiple fo

116 d carbon nanotubes (SWCNTs) can modify their optical properties, enabling applications as single-phot

117 combined with large-area monolayer MoS2 for optical property enhancement and array processing, our r

118 luorescent protein reporters, which lack the optical properties essential for sensitive dynamic imagi

119 -tracking NIR fluorophores (CTNFs) with high optical properties, excellent cell permeation and retent

120 re, we present an image analysis algorithm, "optical properties extraction (OPE)," which improves the

121 h-rich particles dominate the volcanic cloud optical properties for the first 60 days.

122 family of chromophores with broadly varying optical properties from a single and readily available s

123 ing, which allows independent control of the optical properties from the electronic properties of flu

124 The coupling of both optical properties fundamentally limits the performance

125 growth on the produced cores enhances their optical properties, furnishing particles with center emi

126 possess common features including excellent optical properties, good photostability and biologically

127 The particles were characterized for their optical properties, growth rate, elemental composition,

128 , the influence of the moire superlattice on optical properties has not been investigated experimenta

129 yloid nucleation, the understanding of their optical properties has remained rather limited.

130 osphide (GaP) is a material that, due to its optical properties, has the potential to become a primar

131 Dissolved organic matter optical properties have been attributed to a charge-tran

132 rganic spacer molecules did not affect their optical properties; however, it has a pronounced effect

133 Leaf optical properties impact leaf energy balance and thus l

134 ications are contingent upon retaining their optical properties in an aqueous environment.

135 ctive trace gases, particle composition, and optical properties in fresh western US wildfire smoke in

136 , can produce novel electronic, magnetic and optical properties in many materials.

137 exhibit very large and fast changes in their optical properties in response to external stimuli.

138 cessing advantages but suffers from inferior optical properties in the LWIR spectrum.

139 bly separated will be subjected to different optical properties in the media through which they trave

140 ns further validate the differences in their optical properties in the solution and powder states.

141 ISOCT enables measurements of optical properties in the visible range and thus allows

142 thography-based process, producing predicted optical properties in transmission and reflection measur

143 lattices (direct and inverse) have promising optical properties, including a wide and complete photon

144 )BB'Cl(6) double perovskites with remarkable optical properties, including large and tunable exciton

145 The optical properties indicate a strong enhancement of lumi

146 ion with their electronically reconfigurable optical properties, inorganic, WO(3)/LiNbO(3)/NiO Electr

147 uctures were designed and fabricated and the optical properties investigated in the wavelength region

148 lation in chemical, electronic, magnetic and optical properties, mediated by the reversible transfer

149 We determine the optical properties, molecular composition, and stable is

150 However, the intrinsic nonlinear optical properties of 2D layered GeAs have not been expl

151 Recent studies of the optical properties of 2D materials have reported unique

152 ns and Coulomb effects on the electronic and optical properties of [Formula: see text]-plane GaN/AlGa

153 l, and can be understood with analogy to the optical properties of a 2D anisotropic metasurface atop

154 eted changes in the electronic, magnetic and optical properties of a material, triggering ferroelectr

155 mbination is a crucial process governing the optical properties of a semiconductor.

156 fects of pH and borohydride reduction on the optical properties of a series of humic substances and a

157 By taking advantage of the optical properties of a thin birefringent coating on the

158 dielectric function model and the intriguing optical properties of alpha-MoO(3) are provided.

159 Unique structural and optical properties of atomically thin two-dimensional se

160 of vital importance in determining the basic optical properties of atoms, molecules and semiconductor

161 otential avenue to fully exploit the electro-optical properties of blue phases, which have been hinde

162 For instance, the optical properties of BODIPY dyes are inherently related

163 ack of technologies to measure the intrinsic optical properties of both compartments in live corals.

164 g growth may be used as a way to improve the optical properties of both the GaAs and ZnSe layers on e

165 Measurements of the optical properties of both the printed ITO film and the

166 The effects of night-time aging on the optical properties of BrC aerosols are less known.

167 This study shows that the optical properties of BrC change because of transformati

168 etic strategy is presented for enhancing the optical properties of CO(2) -based polycarbonates by mod

169 Optical properties of compressed fluid hydrogen in the r

170 We report the study of the nonlinear optical properties of copper oxide nanoellipsoids using

171 The electronic and optical properties of CPPL combine features more charact

172 of chromophore orientation on the nonlinear optical properties of crystalline network compounds and

173 ind a close agreement between structural and optical properties of designed chiral architectures.

174 sity Functional Theory (DFT) analysis of the optical properties of dilute-As GaN1-xAsx alloys with ar

175 for the first time, the observed changes in optical properties of DNA-wrapped SWCNTs with ionic stre

176 lyze trends in the electronic structures and optical properties of expanded, contracted, and isomeric

177 Reliable quantification of the optical properties of fluorescent quantum dots (QDs) is

178 The evolution of the optical properties of gold nanoclusters (NCs) versus siz

179 aterial which complements the electronic and optical properties of graphene and the transition metal

180 The electronic and optical properties of graphene are greatly dependent on

181 Here, by taking advantage of the intrinsic optical properties of haemoglobin, we show that raster-s

182 Furthermore, we will review the fundamental optical properties of halide perovskite nanocrystals by

183 and impact of quinones/hydroquinones on the optical properties of HS and CDOM.

184 experimental and computational study of the optical properties of individual silicon telluride (Si(2

185 Due to optimized thickness and optical properties of ITO film, a lossy-mode resonance (

186 We investigated the optical properties of ITO thin films at high temperature

187 ia opsins by modifying fundamental nonlinear optical properties of light interacting with the retinal

188 ngineering of the macroscopic electronic and optical properties of materials such as semiconductors b

189 The optical properties of metals such as Y and Mg can be rev

190 influence of chirality on the conducting and optical properties of molecules or materials containing

191 However, the intrinsic optical properties of monolayer boron nitride remain lar

192 ntibody-antigen interactions, and the unique optical properties of nanomaterials provide excellent pr

193 arrangement of constituent amino acids, the optical properties of nanoparticle (NP) assemblies are i

194 The unique structural and optical properties of nanostructured Si(2)Te(3) hold gre

195 rangements can have a profound impact on the optical properties of nanostructures and, in particular,

196 hile some work has been done in studying the optical properties of NCs of certain individual sizes, t

197 tical description of the electrochemical and optical properties of Ni and NiFe oxyhydroxide electroca

198 ical structures of NIR-II dyes, chemical and optical properties of NIR-II dyes, bioconjugation and bi

199 rs has critical influences on electronic and optical properties of optoelectronic devices.

200 ymmetry-broken states and low energy magneto-optical properties of other nano and quantum materials.

201 The optical properties of particularly the tungsten-based tr

202 ate the excellent luminescence and nonlinear optical properties of perovskite QDs from the solution s

203 ovide exciting opportunities for controlling optical properties of photonic devices dynamically.

204 d can no longer affect the conformations and optical properties of PTAA.

205 artphone, enabled by the highly advantageous optical properties of QDs.

206 o the high coordination numbers and distinct optical properties of RE-elements.

207 re, strength of electronic interactions, and optical properties of reported dyads closely resemble th

208 The microscopic structure and the optical properties of round and flattened fibers are rep

209 ime domain solver to simulate the near field optical properties of self-assembled microsphere arrays

210 A detailed understanding of the optical properties of self-catalysed (SC), zinc blende (

211 ghlighting that the influence of BSFs on the optical properties of semi-polar InGaN LEDs is different

212 The current work leverages the unique optical properties of semiconducting single-wall carbon

213 uantum confinement and strain effects on the optical properties of semiconductor nanostructures.

214 The equilibrium and non-equilibrium optical properties of single-layer transition metal dich

215 was to establish a relationship between the optical properties of soil dissolved organic matter (DOM

216 The optical properties of subwavelength arrays of atoms or o

217 The leveraging of light to program the chiro-optical properties of such mesogenic helical soft materi

218 ity to rapidly and reversibly manipulate the optical properties of supramolecular inclusion complexes

219 The optical properties of the chlorin-, bacteriochlorin-, an

220 omal collagen is closely associated with the optical properties of the cornea, the absence of any lar

221 The electrochemical and optical properties of the diazapentacenes were evaluated

222 oyed to gain insight into the electronic and optical properties of the experimentally studied [Formul

223 n confirmed that the LMR response depends on optical properties of the external medium, as well as po

224 pupil is a consequence of the anatomical and optical properties of the eye, and the relative position

225 The optical properties of the Fe(2)GeS(4) NPs are consistent

226 Both structural and optical properties of the final materials were investiga

227 s work, we studied the linear and non-linear optical properties of the halogenated ethers sevoflurane

228 ations to elucidate the strongly anisotropic optical properties of the highly-porous Si-Au slanted co

229 A comparison of the optical properties of the lead halide series reveals a s

230 We find that the optical properties of the moons' surfaces are determined

231 orphology, crystal structures, chemical, and optical properties of the MoS2 QDs were characterized by

232 ted by attenuation from the intrinsic tissue optical properties of the patient, which in breast, rang

233 ons on the structure and consequently on the optical properties of the perovskite materials.

234 The optical properties of the probe were characterized using

235 the photoacid generators and changes in the optical properties of the QDs at each patterning step.

236 e used to study the chemical composition and optical properties of the resultant QDs as well as inves

237 h regard to controlling the shape, size, and optical properties of the resulting nanocrystals.

238 mage quality is still largely limited by the optical properties of the sample.

239 The optical properties of the single QD in the devices are c

240 se), and these have a profound effect on the optical properties of the system, for both one and two p

241 We investigate the optical properties of the TiN films and their dependence

242 Furthermore, the spectrally matching optical properties of the UCNPs and the dyes allow the U

243 n is a molecular chaperone important for the optical properties of the vertebrate eye lens.

244 We experimentally characterize the optical properties of the VO(2) film and use the results

245 Both the lattice structures and optical properties of these 2D films were directly contr

246 We find that the optical properties of these ATMS are quite distinct from

247 he molecular structure, we vary the spin and optical properties of these compounds, indicating promis

248 By studying the crystal structures and optical properties of these materials and combining our

249 interactions that give rise to the observed optical properties of these materials.

250 Cancer is known to alter the local optical properties of tissues.

251 sing method to manipulate the electronic and optical properties of two-dimensional (2D) materials.

252 e basis of future investigations linking the optical properties of various habitats and the variabili

253 or both normal and hemispherical as well the optical properties of VO(2) as determined via infrared s

254 vitro phantom models were used to model OCT optical properties of water, mineral oil, and intralipid

255 of the art morphologies, particle sizes, and optical properties of YAG:Ce on the nanoscale.

256 hlight how a specific chemical, physical and optical property of 2D materials can influence the perfo

257 The refractive index is a basic optical property of materials.

258 This study demonstrates the high optical property of SC InAs NWs which is compatible with

259 he electronic structure-and consequently the optical properties-of organic semiconducting building bl

260 ite nanocrystals by focusing on their linear optical properties, on the effects of quantum confinemen

261 ) promises deterministic characterization of optical properties over a broad spectral range at the na

262 Uncertainties in the contrail age, coverage, optical properties, radiative forcing, and energy forcin

263 ealed a high degree of similarity between RI-optical property relationships across DOM samples of div

264 ion of two (207)Pb NMR resonances, while the optical properties resemble those of other 2D perovskite

265 bs with immobilized microalgae and with bulk optical properties similar to those of different types o

266 thin metasurface coating can control several optical properties simultaneously over a broad frequency

267 considerable attention owing to their unique optical properties, size and quantum confinement.

268 e-sized gold NCs (ca. >100 Au atoms) exhibit optical properties solely dependent on size, and the str

269 ecently in the literature highlighting their optical properties, structures, and applications.

270 More importantly, optical property studies revealed that terpolymers with

271 ical moieties has a negligible impact on the optical properties, styryl substituents allow a welcomin

272 rials, as it can enable a range of appealing optical properties, such as high-sensitivity circular di

273 Nonlinear optical properties, such as two-(or multi-) photon absor

274 Optical properties suggest that permanganate oxidation d

275 ns because they used measurements of aerosol optical properties that are not directly related to clou

276 Microring resonators have optical properties that are sensitive to changes in refr

277 n the relationship between the structure and optical properties that may improve the material's poten

278 used as a knob to control the dielectric and optical properties the QWs.

279 icantly influence electrochemical and linear optical properties, the orientation of the pyrimidine ri

280 Despite significant development of their optical properties, the synthesis of InAs QDs still rout

281 switch that allows for electrical control of optical properties through electrochemical hydrogen gati

282 lizing possibility of creating extraordinary optical properties through the careful design and arrang

283 ization is the key to lens formation and its optical properties throughout all life stages.

284 hod for SCT that allows its conductivity and optical properties to be controlled over orders of magni

285 own to limit the field enhancement and cause optical properties to deviate from the local description

286 well as a quantum chemical assessment of its optical properties to distinguish our result from classi

287 locally-addressable and dynamically tunable optical properties underpin emerging technologies such a

288 Finally, a red shift of the optical properties was evidenced upon introduction of ni

289 The stabilized colloids' optical properties were studied through optical absorpti

290 This structural evolution fine-tunes the optical properties where the larger the Pb-Br-Pb angle,

291 tion of the substitution also influenced the optical properties, where the introduction of phenyl gro

292 exchange providing facile tunability of the optical properties, which is usually achieved by mixing

293 ydrothermal treatment and exhibit pronounced optical properties with a high quantum yield of 0.23.

294 pounds give rise to interesting physical and optical properties with applications in biomedicine and

295 idate the dynamic changes in DOM composition/optical properties with molecular weight within individu

296 on of circularly polarized light and display optical properties with prominent handedness, that is, c

297 nodroplets show good mechanical, thermal and optical properties, with a remarkable suppression of cry

298 y studied for their structural coloration or optical properties within the visible spectrum, their pr

299 obtaining polymeric materials with enhanced optical properties without compromising thermal performa

300 excellent physical, chemical, electronic and optical properties, Xenes have been regarded as promisin