ライフサイエンスコーパス: optical activity

1 ires have high aspect ratio, uniformity, and optical activity.

2 responding gamma-butanolides without loss of optical activity.

3 o[b][1,4]oxazine-2,3'-xindole] retaining the optical activity.

4 systems offers a pathway to tailoring their optical activity.

5 rocrystal (perylene) and exhibiting emergent optical activity.

6 n can be conveniently studied by vibrational optical activity.

7 acid into cyclopropyl amine without loss of optical activity.

8 scribes the electronic origin of the magneto-optical activity.

9 matter including absorption, dispersion and optical activity.

10 ard the possibility of exhibiting an induced optical activity.

11 by vibrational circular dichroism and Raman optical activity.

12 ons, aromaticity is correlated to diminished optical activity.

13 hs are sufficient to account for nonresonant optical activity.

14 ward the fabrication of NPs with high chiral optical activity.

15 nanostructures with chiral shapes and large optical activity.

16 The organic phase, however, still displays optical activity.

17 ctations of the magnitudes and etiologies of optical activity.

18 n the tactoids as manifested by the observed optical activity.

19 e acceptor strength to chromophore nonlinear optical activity.

20 conditions results in significant erosion of optical activity.

21 out chiral molecules present also have large optical activities.

22 The solid VC did not lose optical activity after several mounts at room temperatur

23 the habits is correlated with single-crystal optical activity along the accessible low-symmetry direc

24 Optical activity, also called circular birefringence, is

25 Optical activity, although direct and simple, lacks sens

26 Connections between magnetic field induced optical activity and chirality have a rich and complicat

27 Optical activity and circular dichroism are fascinating

28 oretical analysis of the interaction between optical activity and electro-optic property, the optical

29 ly, the broadband behaviors of nondispersive optical activity and high transmission are insensitive t

30 However, the weak optical activity and inhomogeneity of thin films from ch

31 ng anisotropy of DCMC results in anisotropic optical activity and rotary power, which can be experime

32 and birefringent properties, yet its lack of optical activity and semiconducting transport hamper app

33 es, yield a new kind of relationship between optical activity and temperature, and also reveal unusua

34 This correlation between the optical activity and the CISS effect indicates that the

35 s connected to the chromophore ring in their optical activity and the important role of pyridyl group

36 superimposable molecules that differ only in optical activity and their interaction with other chiral

37 warf LP944-20, whereas previous searches for optical activity (and one X-ray search) yielded negative

38 ion, thermal and/or electrical conductivity, optical activity, and capability to direct cell growth.

39 rality of molecules is associated with their optical activity, and circular dichroism is commonly app

40 parallel fibers evoked a transverse beam of optical activity, and stimulation of the contralateral i

41 ls (LCs), which can impart optical isotropy, optical activity, and sub-millisecond EO response of BPI

42 finds no difference, aside from the expected optical activity, arising from the difference in stereoc

43 dichroism signal confirm the origin of this optical activity as the chiral supramolecular organizati

44 Optical activity associated with retinal binding to TL w

45 overlapping anisotropic lamellae, a kind of optical activity associated with the mesoscale stereoche

46 Our data show a giant natural optical activity at terahertz frequencies, characterized

47 ble, but the resolved enantiomers exhibit no optical activity at the alphaD-line.

48 p the possibility of controlled induction of optical activity at the nanosecond time scale for exploi

49 uning the active layer's thickness increases optical activity at wavelengths greater than 600 nm, ach

50 There are no Raman optical activity bands characteristic of extended second

51 rossing zero at the nematic temperature, the optical activity becomes so large that it may be observe

52 A marked difference in optical activity between the former 1a and 1b) and latte

53 y Mueller matrix microscopy shows that their optical activity can be individually measured and that t

54 ngular momentum fiber modes, giant, scalable optical activity can be obtained, and that we can use th

55 loids, whose nanoscale geometry and rotatory optical activity can be reversibly reconfigured and cycl

56 Their multiscale chirality and optical activity can be varied across the broad spectral

57 s nevertheless clearly show that vibrational optical activity combined with spectral simulations appe

58 ions form a basis for making broad structure-optical activity correlations from inspection of molecul

59 of such materials should lead to interesting optical activity effects.

60 th new material capabilities such as tunable optical activity, essential for multiple emerging techno

61 Two of the aggregates show very high optical activity even though the isolated chromophores b

62 optically active substrate with its loss of optical activity, F, the fraction of the initially forme

63 The loss in optical activity for these reactions was shown to occur

64 erchain interactions, and topology-amplified optical activity has also been observed for chiral (1S,

65 We demonstrate that optical activity in amorphous isotropic thin films of pu

66 ral magnetic conductivity (DCMC) and natural optical activity in an inversion-broken tilted Weyl semi

67 While natural optical activity in crystals belonging to specific achir

68 demonstrates the induction of chirality and optical activity in solid materials by CPL and opens new

69 As a result, efficient induction of optical activity in the chromophoric system is observed.

70 Our results show strongly enhanced magneto-optical activity in the infrared and terahertz ranges, c

71 CD spectroscopy did not detect any optical activity in the seed polymer.

72 The carotenoid in ethanol has very weak optical activity in the visible region of the spectrum.

73 gnetic dipole polarizability contribution to optical activity in which the sense of electric dipoles

74 The approach is to monitor the optical activity induced by a Kagome-lattice hollow-core

75 Incorporating optical activity into time-resolved spectroscopies has p

76 tive understanding of the vexing property of optical activity is forthcoming for the following reason

77 nerates 'natural' optical activity, magnetic optical activity is generated by breaking time reversal

78 Designing polymeric systems with ultra-high optical activity is instrumental in the pursuit of smart

79 The relationship between aromaticity and optical activity is investigated in comparisons of heter

80 The induction of optical activity is reversible and only depends on the l

81 Optical rotation, a form of optical activity, is a phenomenon employed in various me

82 optical manifestations of birefringence and optical activity (linear and circular birefringence and

83 their magnetooptical effects, birefringence, optical activities, linear and circular dichroism, are p

84 etry of chiral molecules generates 'natural' optical activity, magnetic optical activity is generated

85 caused by magneto-electric coupling (natural optical activity), not structural chirality as previousl

86 While circular dichroism (CD) and optical activity (OA) are well established as optical ef

87 These films exhibited optical activity (OA) at 380 nm and in the range of 200-

88 of the strong inherent resonances, the giant optical activity obtained via chiral metamaterials gener

89 ter (2, 3, 4a,b) dendrons is mirrored in the optical activities of model compounds 12a, 12b, 19a, and

90 k is directly applicable for quantifying the optical activities of optically complex materials where

91 Also in S1 in solution, the induced optical activity of a fluorescein probe linked to SH1 sh

92 nd binding was monitored using the intrinsic optical activity of bound retinol.

93 We probe directly the plasmonic optical activity of chiral gold nanorods (c-AuNRs) embed

94 Because of the optical activity of chiral molecules, it has been hypoth

95 The optical activity of chitin was found to be levorotatory.

96 ence that cannot be explained by the natural optical activity of corresponding compounds, some of whi

97 The strong optical activity of inorganic nanoparticles (NPs) afford

98 And the optical activity of multi-layer chiral metamaterials is

99 Both the aqueous and organic phases show optical activity of near mirror image relationship.

100 c and microscopic chirality by measuring the optical activity of solutions of enantiomorphous tartrat

101 cal activity and electro-optic property, the optical activity of the crystal has no influence on the

102 Agreement between the optical activity of the model compounds and that of the

103 ted that there may be a relation between the optical activity of the molecules and their spin selecti

104 The optical activity of the photo-induced phases is comparab

105 state is obtained at high temperatures, the optical activity of the supramolecular stack self-assemb

106 the anisotropic absorption property and the optical activity of the twist alignment nematic cell, sp

107 The optical activity of these chiral dendritic structures is

108 The optical activity of these chiral dendritic structures wa

109 Environmentally induced optical activity of Trp/Tyr/Phe (2:4:12) detected by nea

110 The changes in the optical activity of Trp510 and SH1 bound fluorescein in

111 In myosin S1 in solution, the optical activity of Trp510 senses conformation change in

112 avity-enhanced polarimetry for detecting the optical activity of two enantiomers of a chiral molecule

113 of VC was related to isomerization (loss of optical activity) of the l-enantiomer either to d-enanti

114 Surface-enhanced Raman optical activity offers potential capabilities for sensi

115 yet unexpected, dependence of the dispersive optical activity on the nature (phase) of the surroundin

116 for obtaining either highly confined modes, optical activity, or a low-scattering signature, but at

117 lucose sensing system based on the glucose's optical activity property which rotates linearly polariz

118 Unlike the Faraday effect, the optical activity provokes rotation of the linear polariz

119 l use in areas such as wave manipulation(4), optical activity related to circular polarization(5) and

120 o-band simulations of the fibril vibrational optical activity remain challenging.

121 aveguide with a low-visibility and broadband optical activity represents a transformative wave manipu

122 nd can therefore avoid the highly dispersive optical activity resulting from resonances.

123 ), have been studied using vibrational Raman optical activity (ROA) and ultraviolet circular dichrois

124 o conformational mobility, vibrational Raman optical activity (ROA) has provided new insights into th

125 , and Er) complexes were recorded on a Raman optical activity (ROA) instrument.

126 Raman optical activity (ROA) is an advanced technique capable

127 Raman optical activity (ROA) is effective for studying the con

128 the first observations of vibrational Raman optical activity (ROA) on intact viruses.

129 We report the collection of Raman optical activity (ROA) spectra of adenine in silver coll

130 e report calculations of the Raman and Raman optical activity (ROA) spectra of methyl-beta-D-glucose

131 Here we analyze Raman optical activity (ROA) spectra of N-acetylalanine-N'-met

132 Vibrational Raman optical activity (ROA) spectra of the wheat proteins alp

133 l circular dichroism (VCD), Raman, and Raman optical activity (ROA) spectra of various PGA forms and

134 Raman and Raman optical activity (ROA) spectra were collected for four R

135 The CPL spectra were measured on a Raman optical activity (ROA) spectrometer, which ensured high

136 The Raman optical activity (ROA) spectroscopic technique has been

137 m incident circular polarization (ICP)-Raman optical activity (ROA) to explore the chiroptical activi

138 Here, we utilized Raman spectroscopy, Raman optical activity (ROA), circular dichroism (CD), and tip

139 brational circular dichroism (VCD) and Raman optical activity (ROA), expands the number and types of

140 Vibrational Raman optical activity (ROA), measured as a small difference i

141 uch higher order structure, we applied Raman optical activity (ROA)-a spectroscopic technique that is

142 degrees C at pH 2.0, was studied using Raman optical activity (ROA).

143 brational circular dichroism (VCD) and Raman optical activity (ROA).

144 a combination of Raman scattering and Raman optical activity (ROA).

145 brational circular dichroism, VCD, and Raman optical activity, ROA) provide more reliable assignments

146 Resonance Raman optical activity (RROA) is commonly measured as the diff

147 al solution, that is, surface-enhanced Raman optical activity (SEROA) using considerably shorter data

148 The optical activity spans 2 orders of magnitude depending o

149 irror image surface enhanced resonance Raman optical activity spectra for the two enantiomers of both

150 The Raman optical activity spectra of all these proteins are very

151 We report Raman and Raman optical activity spectra of hyaluronan polymer, the hyal

152 The hyper-Rayleigh optical activity study reveals important charge-transfer

153 these proteins has been provided by a Raman optical activity study, supplemented with differential s

154 ervations using the novel technique of Raman optical activity suggest that individual residues in unf

155 Both methods allowed us to observe nonlinear optical activity that was quantified, for the first time

156 Optical activity, used here for the first time to gain i

157 Optical activity was fully preserved throughout.

158 The optical activity was reduced (100%) to zero after 6 and

159 The structure and optical activity was sensitive to imidazole concentratio

160 irst proposed by Hohn and Weigang for linear optical activity, we presented a dynamic coupling model

161 derivatives can exhibit excellent nonlinear optical activity when extended through pi-bridges.

162 hat one of the diastereomers has very strong optical activity, which overrules the cancelation of the

163 le crystals display both linear and circular optical activity with a large anisotropy factor of up to

164 amaterial can achieve nondispersive and pure optical activity with high transmittance in a broadband

165 synthetic material are identical (except for optical activity) with respect to structure and biologic