ライフサイエンスコーパス: visible range

1 anarrow linewidth of 2 nanometers within the visible range.

2 nsic blood serum fluorophores excited in the visible range.

3 tailor for structural color anywhere in the visible range.

4 cation of Epsilon-Near-Zero materials to the visible range.

5 ttering, and allows combining with probes of visible range.

6 bsorption peak is tunable from the UV to the visible range.

7 th and to characterize the dispersion in the visible range.

8 3-1.4 eV as well as potent absorption in the visible range.

9 trical controllability of astigmatism in the visible range.

10 tes exceptionally bright fluorophores in the visible range.

11 resulting palette spanning almost the entire visible range.

12 with extraordinary optical properties in the visible range.

13 ng incoherent long-wavelength light into the visible range.

14 uorescent signal from the ultraviolet to the visible range.

15 nd particularly switching wavelengths in the visible range.

16 d quantum efficiencies that spans the UV and visible range.

17 result, enables low-loss performance in the visible range.

18 an increase of optical transmittance in the visible range.

19 from ultraviolet to infrared throughout the visible range.

20 ance and a high optical transmittance in the visible range.

21 absorption coefficients >10(5) cm(-1) in the visible range.

22 while still having a peak absorption in the visible range.

23 79,000 M(-1) cm(-1)), and fluorescent in the visible range.

24 lity of the optical response over the entire visible range.

25 nt nucleoside analogues with emission in the visible range.

26 with an average transmittance of >80% in the visible range.

27 exhibit an average transmittance >80% in the visible range.

28 ent[hi]aceanthrylene 2c extend well into the visible range.

29 with fluorescence colors spanning the entire visible range.

30 polar distortion and optical gap across the visible range.

31 s in the atmosphere to the near-infrared and visible ranges.

32 zero, and are easily tuned across the IR and visible ranges.

33 to stimulating light in the 400- to 720-nm (visible) range.

34 the sensor is 400-1100 nm thus it covers the visible range (400-780 nm) and the short-wave near infra

35 NCs bearing near-unity PL QYs in almost full visible range (460 to 620 nm) and enhanced photochemical

36 Although quite active in the visible range (500-600 nm), 1 exhibits very little photo

37 llowed the synthesis of molecules exhibiting visible-range absorption, near-unity fluorescence quantu

38 the synthesis of molecules exhibiting strong visible-range absorption.

39 atures (e.g., absorption and emission in the visible range and a good quantum yield).

40 Here we extend the approach to the visible range and directly measure electronic couplings

41 of cone photoreceptors, covering most of the visible range and into the UV.(1)(,)(2) Additionally, th

42 materials, such as high absorption over the visible range and long diffusion length.

43 rongly absorbing light on the borders of the visible range and showing a solvatochromic effect.

44 strongly from the ultraviolet throughout the visible range and tails into the near-IR to ~800 nm, per

45 most prominent absorption phenomenon in the visible range and the irradiation cause significant decr

46 olor gamut, including both the monochromatic visible range and the purple line.

47 es measurements of optical properties in the visible range and thus allows for characterization of th

48 r glasses that are transparent in the UV and visible ranges and do not crystallize when they are prep

49 material to the exciting laser heat source (visible range) and multiple reflections at the film surf

50 llent transmittance (90% at 550 nm, 84% over visible range), and an ultrathin form factor ( approxima

51 g low LUMO levels, a broad absorption in the visible range, and a twisted conformation make them good

52 ase the light trapping and absorption in the visible range, and dramatically inhibit the charge carri

53 luorescence quantum yields up to 92 % in the visible range, and even for the NIR dyes, the values of

54 s excitation and emission wavelengths in the visible range ( approximately 500 nm), a dissociation co

55 e excitation and emission wavelengths in the visible range ( approximately 500 nm), dissociation cons

56 se photoluminescence band, discovered in the visible range around 425nm, caused by the immobilized pr

57 range and 0.01 nm spectral resolution in the visible range, as well as a uniform efficiency of diffra

58 entally a gauge potential for photons in the visible range based on the photon-phonon interactions in

59 her explored to extend the absorption to the visible range by incorporating W into TiO(2), and 0.83%

60 orption properties of these materials in the visible range can be tuned by changing the number of ino

61 ns indicate that the absorption bands in the visible range can be tuned using different Lewis acids,

62 terial loss suppression in a-Si:H NPs in the visible range caused by hydrogenation-induced bandgap re

63 Circular dichroism peaks in the visible range change from negative to positive during tr

64 containing IR-820 dye) and the other for the visible range [containing fluorescein isothiocyanate (FI

65 vered a crossover energy in the infrared and visible range, corresponding to a metal-to-dielectric tr

66 infrared light and that emit photons in the visible range depending on the ion composition of the cr

67 prohibited by limited absorption within the visible range derived from its wide band gap value and t

68 ting intense absorption bands over the whole visible range due to flavin-MTA charge transfer (CT) int

69 etic spectrum, thus avoiding ultraviolet and visible ranges due to absorption of chalcogenide glasses

70 be activated with longer wavelengths in the visible range (e.g. 440-475 nm) and rapidly returns to i

71 rovskites (LHPs) have disrupted the field of visible-range emitting colloidal semiconductor nanocryst

72 bit a structure-specific fluorescence in the visible range even in the absence of aromatic amino acid

73 Using thermal fluctuations as a probe and visible-range Fabry-Perot resonances as an optical reado

74 The visible-range fluorescence dipole of the probe is approx

75 Surface Plasmon Resonance (LSPR) peak in the visible range for biomarker detection.

76 ama Desert may be high enough (up to 0.25 in visible range) for considerably boosting the performance

77 esponse range of the device covers the whole visible range from 380 to 800 nm.

78 strated large absorption capabilities in the visible range, good accepting abilities with low LUMO le

79 ap with strong photoluminescence emission in visible range has gained wide attention in applications

80 However, emission in the visible range has remained elusive.

81 r, metamaterial absorbers in the infrared or visible range have been fabricated using lithographicall

82 ability by their size and composition within visible range have garnered surging interest.

83 early growth response and was captured using visible range imaging.

84 ion relation for the cornea is linear in the visible range, implying that the cornea is transparent.

85 tical colors and tunable bandgaps across the visible range in photoluminescence, with one of the mate

86 ting their emission wavelengths in the UV to visible range in response to external stimuli can offer

87 be used for efficient photodetection in the visible range, in which a responsivity of 0.16 mA/W was

88 Spectrophotometric data in the UV-visible range indicates that hydroxyl groups on the B-ri

89 cal effects in both the ultraviolet and full visible range into R-CDPB and S-CDPB.

90 Pushing these concepts to the visible range is hindered by their larger absorption coe

91 user relies solely on strong broadband (full visible range) lossless multiple light scattering events

92 s exhibit localized plasmon resonance in the visible range matching the sensitivity of the complement

93 -infrared range and lower reflectance in the visible range may be used by females for host selection.

94 metasurface is achieved by integrating a Au visible-range metasurface on top of the planar AZO infra

95 Our devices are capable of accurate, visible-range monochromatic and broadband light reconstr

96 ally in the range 230-330 nm and emit in the visible range of 400-420 nm.

97 e reflectivity down to less than 2.5% in the visible range of 450-700 nm and an average reflectance o

98 t molar electronic circular dichroism in the visible range of any molecule.

99 the eye, transcends mere information in the visible range of electromagnetism and serves as an agent

100 m of the sediment during illumination in the visible range of light (400-700 nm), even in the presenc

101 ional tuning of the emitted color across the visible range of the electromagnetic spectrum and switch

102 transparent compound its band gap is in the visible range of the electromagnetic spectrum and the io

103 nductor (i.e., shift its response toward the visible range of the electromagnetic spectrum) in situ b

104 SOLFT imaging has only been performed in the visible range of the electromagnetic spectrum.

105 They exhibit a charge transfer band in the visible range of the electronic spectrum.

106 ai-surface and intense absorption across the visible range of the solar spectrum.

107 (ii) The emission colors of DBAs fall in the visible range of the spectrum (blue to orange), while an

108 tem exhibiting intense emission bands in the visible range of the spectrum and also offers a convenie

109 The bubbles are transparent in the visible range of the spectrum, and can be used as "cuvet

110 The emission of 5 is in the visible range of the spectrum, i.e., red-shifted by 150

111 spectra, the absorption properties in the UV-visible range of two wine samples as well as their laser

112 lexed metasurface holograms operating in the visible range, offering increased potential for real lif

113 itions are nondegenerate semiconductors with visible-range optical absorption onsets (1.8 to 2.1 eV)

114 lightweight materials with greater than 99% visible-range optical transparency and approximately 10

115 elied on single-wavelength absorbance in the visible range, our platform collects full UV-vis spectra

116 neous electric and magnetic responses in the visible range pave a way for a plenty of new application

117 llows us to design NPLAs covering the entire visible range, paving the way for efficient atomically-t

118 y red-shifted photoluminescence and enhanced visible-range photocurrent generation compared to soluti

119 egative permittivity in semiconductors where visible range plasmonics can be directly integrated with

120 nisotropies at a specified wavelength in the visible range, rising from the particular design and fab

121 These findings open a pathway for extending visible-range SERS applications of novel 2D hybrid mater

122 Circular dichroism in both the UV and visible ranges shows that Triton can disturb both the se

123 cofactors with electronic transitions in the visible range, such as retinal or heme proteins.

124 nitude while maintaining transparency in the visible range, suggesting the use of ionic liquid gating

125 have white-light, broadband emission in the visible range that was attributed mainly to the role of

126 In the visible range, the engineered surface morphology of the

127 nge can be sensitized upon excitation in the visible range through Ru(II)-centered metal-to-ligand ch

128 ) of {Ru-NO} (6) nitrosyls can be tuned into visible range via careful alteration of the ligand frame

129 and length scales, including several in the visible range via colloidal self-assembly.

130 eflectance spectroscopic measurements in the visible range (VIS-RS).

131 Using 8 narrow spectrum light sources in the visible range, we demonstrate that all wavelengths induc

132 t pure photons at telecom wavelengths to the visible range while compressing the bandwidth by a facto

133 ing in tunable emission peaks throughout the visible range with increasingly narrow bandwidth in the

134 wo-channel field synthesizer in the infrared-visible range, with a full-width at half-maximum duratio