ライフサイエンスコーパス: blue shift

1 g of the protein bands to lower wavelengths (blue shift).

2 rom Chlamydomonas augustae (CaChR1) caused a blue shift.

3 rgy gap increases, resulting in the observed blue shift.

4 ay absorption should exhibit at least a 1 eV blue shift.

5 fficiency channelrhodopsins (ChRs) result in blue shifts.

6 including emission enhancements and red- and blue-shifts.

7 tential, which in turn leads to the observed blue-shifts.

8 in response to increased volume, emission is blue shifted.

9 ctronic confinement is stronger, shorter and blue-shifted.

10 gment lineages whose lambda(max) values were blue-shifted.

11 e, except for the ortho derivative, which is blue-shifted 10 nm.

12 While blue shifts (14 +/- 2 nm) were observed for the photolum

13 while the SL structures have an even greater blue-shift (2.53 eV for m = 4, 2.74 eV for m = 3, and 2.

14 The dye's fluorescence emission spectrum is blue-shifted 60 nm in liquid-ordered phases compared wit

15 asing solar angle is accompanied by a strong blue shift [9-11].

16 A large blue shift (96 nm) was also observed in the absorption s

17 imarily TPQ at lower pH and a species with a blue-shifted absorbance at high pH (lambda(max) = 400 nm

18 Its blue-shifted absorption enables optogenetics at waveleng

19 retinyl is likely to be responsible for the blue-shifted absorption in the blue cone vision pigment.

20 of steric bulk and charge repulsion led to a blue-shifted absorption when compared to that of BDB.

21 Twisted tethered tolane conformers showed blue-shifted absorption; emission spectra were all torsi

22 e increase in quantum yield and a pronounced blue shift, addition of the Ca(2+)-bound protein is with

23 The blue-shifts also show a high degree of correlation with

24 ate fluorescence quenching measurements, and blue shift analysis of acrylodan-labeled cysteine mutant

25 me, which resulted in an approximately 13 nm blue shift and approximately 30 mV decrease in the heme

26 wed that the G band of the GNM experiences a blue shift and broadening compared to pristine graphene,

27 TA reveals a sub-100-fs blue shift and decay of the Franck-Condon bright state a

28 0.5%) under Ar, representing ca. 3600 cm(-1) blue shift and doubled radiative decay efficiency vs the

29 Fluorescence blue shift and quenching experiments revealed that Trp r

30 escence peak does not exhibit any additional blue shift and the quantum yield drops abruptly with fur

31 in the visible region, photoluminescence is blue shifted and electronic conductivity increases by up

32 e in emission energies yielding fluorescence blue shifts and helps develop an understanding of the or

33 rate suggesting a link between the observed blue-shift and a thermal noise decrease.

34 lino-1-naphthalenesulfonate (ANS) reflects a blue-shift and fluorescence enhancement on decreasing so

35 itself in the 2D IR spectrum as a frequency blue-shift and intensity decrease of the diagonal and cr

36 l under broadband illumination to reversibly blue-shift and significantly dampen gold SPR absorption.

37 erting and in situ immobilizing chlorides to blue-shift and stabilize the emission.

38 frequency domain are identified and shown to blue-shift and strengthen upon inhibitor binding.

39 With the PCB chromophore GAF-FP becomes blue-shifted and absorbs at 625 nm and fluoresces at 657

40 primarily 13-cis light-adapted state with a blue-shifted and lower extinction absorption spectrum, o

41 resonance line shapes of labeled mutants are blue-shifted and more immobilized, respectively, with th

42 ading to a Raman O-H stretching band that is blue-shifted and narrower than that of bulk water.

43 ssurizing each metal, the phonon spectra are blue-shifted and the net electron-phonon interaction is

44 Upon binding to TTP, NBD-TOH fluorescence is blue shifted, and its intensity is greatly enhanced.

45 of a thin, epitaxial layer of CuO, which is blue-shifted, and appears to increase in energy as a fun

46 es of the acetone ligands were progressively blue shifted as the number of ligands increased from two

47 show a maximum at longer wavelength, however blue shifts as time evolves, which provides the first di

48 Abnormally, these MLCT bands blue-shift as n increases, and beta(0) maximizes at n =

49 to-ligand charge-transfer bands unexpectedly blue-shift as the number of E-ethylene units (n) increas

50 -shifts with increasing lattice constant and blue-shifts as the network filling fraction increases.

51 ys, ultra-violet emission with large Doppler blue shifts associated with plasma upflows, and Halpha h

52 roxyl bound to water oxygen) and a resolved, blue shifted band (hydroxyl bound to BF(4)(-)).

53 n of Fe(3+), Cr(3+), and Al(3+) caused a new blue-shifted band in 2a-d that was ascribed to a prefere

54 that such structural deformation leads to a blue-shifted bandgap, sub-bandgap trap states with wider

55 and the absorption position of the farthest blue-shifted beta-carotene was attributed entirely to th

56 amined and found to be more prominent in the blue-shifted bioluminescence produced by R. reniformis l

57 cavity transmission spectra exhibit distinct blue-shifted bistability behavior when temperature cross

58 Specifically, it exhibits a blue-shifted broad absorption band around 500 nm and a r

59 size decreases from d approximately 20 nm it blue-shifts but then turns over near d approximately 12

60 rominent absorption peak at 330 nm, which is blue shifted by 100 nm relative to F430.

61 y a 16 cm(-1) red-shifted C=C stretch, which blue shifts by 5 cm(-1) coincident with the rise of the

62 bond with a C-H stretch vibration frequency blue-shifted by 14 cm(-1) and d(F-H) = 2.13 A.

63 of magnitude (Phi = 0.12, tau = 0.7 ns) and blue-shifted by 35 nm.

64 on spectra of TTF-OXD hybrids 10d and 11 are blue-shifted by 80 nm compared to the bithienyl-bridged

65 e carbonyl stretching band at 1970 cm(-1) is blue-shifted by approximately 200 cm(-1) compared to the

66 g interface, the Anap emission wavelength is blue-shifted by EGFR-binding in a titratable manner, up

67 -x)Sn(x)S(2) nanocrystals (0.52-0.57 eV) are blue-shifted by quantum confinement relative to that of

68 on, more tryptophan quenching and wavelength blue-shift (by 10nm), in parallel with increased zeta po

69 The phosphorescence band is blue-shifted ca. 20 nm in the aggregate/gel, and the shi

70 luded a red shift in fluorescence (Ag(+)), a blue shift (Cd(2+)), strong quenching (Pd(2+), Pt(2+)),

71 hat FlicR1 can be used in conjunction with a blue-shifted channelrhodopsin for all-optical electrophy

72 ed an optimized variant (eTsChR) of the most blue-shifted channelrhodopsin reported to-date with a nu

73 itivity was at 445 nm, making PsChR the most blue-shifted channelrhodopsin so far identified.

74 The animals expressed a blue-shifted channelrhodopsin, CheRiff, and a near infra

75 ent light-gated cation channels and the most blue-shifted channelrhodopsin, was studied by time-resol

76 emission maximum is 523 nm, an unusual 37 nm blue shift compared to that of the natural substrate.

77 ethoxy group at the 4-position were slightly blue shifted compared to the unsubstituted parent comple

78 p-RStil(6-7)Ph(2-1)OS](8), the emissions are blue-shifted compared to those of the fully substituted

79 is for a firm assignment of the red-shifted (blue-shifted) conformer of both molecules to the syn (an

80 nce emission maxima of its single tryptophan blue shifts considerably.

81 frameworks, the C-O stretching frequency is blue-shifted, consistent with nonclassical metal-CO inte

82 to prevent oxidative degradation and promote blue-shifting deplanarization.

83 Two mutants were created with blue-shifted (E254D, lambdamax = 390 nm; D380N, lambdama

84 rse Onsager process, where the field induces blue-shifted emission and increases the efficiency of th

85 igh pH, ESIPT is interrupted to yield a new, blue-shifted emission band.

86 The blue-shifted emission maximum, centered near 335 nm, per

87 ional mutagenesis results confirmed that the blue-shifted emission of the double mutants was determin

88 er lifetimes, the remaining pools also had a blue-shifted emission spectrum consistent with immobiliz

89 At this site, DC6C displayed a strongly blue-shifted emission spectrum, higher intrinsic fluores

90 ssion spectrum to long lifetime species with blue-shifted emission spectrum; the activation energy fo

91 double mutant supported the notion that the blue-shifted emission was due to localized changes that

92 y injection mass spectrometry) resulted in a blue-shifted emission wavelength maximum (approximately

93 the GAF or with Cys in both PAS and GAF show blue-shifted emission with long fluorescence lifetimes.

94 diative hydrodynamic models account well for blue-shifted emission, but struggle to reproduce closely

95 To establish the basis of the unusual blue-shifted emission, we determined that a simple addit

96 the HOMO (but not of the LUMO), leading to a blue-shifted emission.

97 anion generates a 2:1 sandwich complex with blue-shifted emission.

98 Our results indicate that the formation of blue-shifted emissive photoproducts can have implication

99 the HOMO-LUMO gap and an enhancement of the blue-shifted emissive properties with respect to its all

100 dispersed in poly(methyl methacrylate) gave blue-shifted emissive Pt(IV) complexes.

101 ssion events, we identified a very promising blue-shifted emitter (548 nm) that contained the mutatio

102 : a spherical outflow, a tightly collimated, blue-shifted expansion, and a directed, red-shifted flow

103 Instead of the continuous blue shift expected from a gradual decrease in NC dimens

104 are shown to exhibit enhanced pH-responsive blue-shifted fluorescence emission intensities compared

105 absorption profiles, they exhibit a trend of blue-shifted fluorescence emission with the decrease in

106 d to Cys in the GAF are the origin of bright blue-shifted fluorescence.

107 en mediated photochemical cleavage, yielding blue-shifted fluorescent products.

108 between virtual excitons produce a dominant blue-shift for photoexcitation detuned from resonance by

109 rease in metmyoglobin correlated well with a blue shift from 410 to 408 nm for myoglobin.

110 fluorescence enhancement of PVD with a 13nm blue shift from 458 to 445nm.

111 regions of these spectra are similar to, but blue-shifted from that of bulk water, whereas the free-O

112 xhibits emission maximum at 685 nm, which is blue-shifted from that of surface-bound 2.

113 cal withC stretching frequency significantly blue-shifted from that of the free molecule.

114 the UV (lambdamax 324-328 nm), significantly blue-shifted from the absorption spectrum of thioindigo.

115 the maximum EF occurs when the LSPR band is blue-shifted from the excitation wavelength rather than

116 oses (~1-10 kW/cm(2)) that are significantly blue-shifted from the NIR-II region (<850 nm) and may th

117 nm) than the diamines but are still slightly blue-shifted from thioindigo, with molar extinction coef

118 )](8), which exhibits an absorption spectrum blue-shifted from trans-stilbene.

119 old fluorescence intensity increase, a 90 nm blue shift (from 805 to 715 nm), and a large increase in

120 t, exhibiting either red-shifted (low pH) or blue-shifted (high pH) absorption maxima.

121 ing", can be perturbed through both red- and blue-shifted hydrogen bonding effects.

122 Met-186 is also largely responsible for the blue-shifted IFP1.4 excitation maximum relative to the p

123 At low pH, a blue shift in absorbance of 10-15 nm suggests a pH-induc

124 Donor XFs display a blue shift in absorption and emission upon protonation,

125 ing methyl group on the donor side exhibited blue shift in absorption and emission when compared to t

126 In the case of magnesium triflate, a blue shift in emission was observed; in contrast, additi

127 ase in Trp intensity and approximately 12-nm blue shift in emission wavelength maximum, involved vari

128 moieties of the casein proteins, with a 10nm blue shift in its fluorescence emission peak, and causes

129 Independently, it displays a comparable blue shift in liquid-ordered relative to liquid-disorder

130 A small blue shift in the 560-nm deoxy absorption peak marked wa

131 ectron transfer indicated approximately 3 nm blue shift in the absolute spectra of both the oxidized

132 All presented Cu(2-x)S NCs show a blue shift in the band gap absorption compared to bulk C

133 us induces an otherwise difficult to explain blue shift in the C-D absorptions.

134 antiparallel G-quadruplex DNAzymes lead to a blue shift in the CD spectra of the G-quadruplex DNAzyme

135 As the voltage is increased, a blue shift in the emission wavelength is observed until

136 on of the dimer, thereby yielding a spectral blue shift in the hybridized plasmon mode as detected by

137 enylate intermediate and is accompanied by a blue shift in the intrinsic fluorescence of the protein.

138 deletion, but not Asp17 mutation, induced a blue shift in the lambda(max) of intrinsic fluorescence

139 ripheral aryl groups results in a systematic blue shift in the low-energy electronic transitions (7,

140 Aggregation induces a significant blue shift in the oligomers' absorption spectra, and the

141 each film during gas exposures and showed a blue shift in the peak positions for the reducing gases,

142 d-halide nanocrystals unexpectedly exhibit a blue shift in the photoluminescence peak that can revert

143 P energy and the electrostatic field induced blue shift in the PL energy of the rGO-QDs.

144 nanoparticles (TGNPs) was characterized by a blue shift in the plasmon absorption spectra (SPR) follo

145 bstitution resulted in an approximately 4 nm blue shift in the Soret band and approximately 20 mV dec

146 did not bind thioflavin T and they induced a blue shift in the spectrum of Congo red.

147 n of GLTP with glycolipid liposomes caused a blue shift in the Trp emission maximum but diminished th

148 ow that all double-layer compounds exhibit a blue shift in their absorption edge (0.6-1.2 eV), due to

149 ence at residues 293-296, displayed an 11-nm blue shift in wavelength of maximum fluorescence emissio

150 orescence intensity and significant (100 nm) blue shifts in emission maxima.

151 s of water, methanol, and acetonitrile cause blue shifts in the electronic transition energy of the b

152 Blue shifts in the emission spectrum with time after exc

153 Each of the analogues caused blue shifts in the fluorescence emission and absorption

154 anced electron-withdrawing character induces blue shifts in the wavelength of photoluminescence, and

155 ransduction element produces a hypsochromic (blue) shift in photoluminescence upon the binding of alb

156 various levels of theory uniformly predict a blue-shift in absorption caused by a single water molecu

157 The RP structures show a blue-shift in bandgap for decreasing n (1.90 eV for n =

158 /Cd(2+) complex showed an enhanced (21-fold) blue-shift in emission from 483 to 446 nm.

159 videnced by a fluorescence increase and by a blue-shift in the emission maximum consistent with a cha

160 D, F, H, and S exhibited varying degrees of blue-shift in the flavin visible absorption maxima while

161 he conjugation of F8BT polymer, leading to a blue-shift in the lowest absorption transition.

162 The blue-shift in the optical spectra is attributed to the l

163 periment shows a controllable and reversible blue-shift in the SP resonance above a critical voltage.

164 radiation of cottoid fishes shows a gradual blue-shift in the wavelength of the absorption maximum o

165 for the bulk, and the LO mode is very weakly blue-shifted in 1D.

166 lrhodamine, producing significant (>/=66 nm) blue-shifts in excitation and emission maxima.

167 ed in structural changes that led to red- or blue-shifts in maximum emission, depending on temperatur

168 stacking in the solid state, unusually large blue-shifts in the absorbance and emission spectra, and

169 The blue-shifts in the photoluminescence emission and increa

170 eriences of colour in dim lights, such as a 'blue shift' in twilight.

171 This blue shift is considerably greater than observed for Trp

172 is seen in absorption (for the former) and a blue shift is observed in emission (for the latter).

173 However, the extent of such a blue shift is significantly less than that of the single

174 lculations are used to demonstrate that this blue shift is the result of delocalization of the Fermi-

175 uency in the presence of halothane, and this blue-shift is largely reversible.

176 ions and iodide ions leads to the gradually blue-shifted LSPR scattering color of AuNPLs under DFM f

177 ith thinner Ag shells (12-16.5 nm) exhibit a blue-shifted major LSPR band relative to the LSPR band a

178 3A, D, H, S, and W mutants exhibited similar blue-shifted maxima together with changes in absorption

179 s of new mechanofluorochromic materials with blue-shifted mechanochromic properties.

180 Blue-shifted metal to ligand charge transfer transitions

181 temporal acceleration can lead to relatively blue-shifted multimode solitons and blue-drifting disper

182 Blue-shifting mutations were distributed evenly along th

183 (O2(-))](2+) (3), based on its distinctively blue-shifted nu(N-O) band at 1853 cm(-1).

184 The quenching and blue shift observed for the maximum wavelength intensiti

185 region confirmed that an apparent energetic blue shift observed for transient bleach signals results

186 of the solvent, in contrast with consistent blue shifts observed for similarly sized organic molecul

187 nt, whether naturally or by mutagenesis, and blue shifts occur when it is replaced with a neutral res

188 e phosphors increased by more than 10% and a blue shift occurred.

189 n MoSe(2) deposits with exposed edges show a blue shift of 1-2 cm(-1) when exposed to H(2) flow at 15

190 -of-sight Doppler velocities with an average blue shift of 23 kilometers per second.

191 at 725 nm is attributed to an electrochromic blue shift of a FR-chlorophyll among the reaction center

192 cts increased lipid packing as measured by a blue shift of an environment-sensitive fluorescent probe

193 ement with the theoretical values and show a blue shift of approximately 0.22 eV relative to those re

194 ctric relaxation results in a time-dependent blue shift of B(A)(-) absorption, which can be monitored

195 s (Mg > Ca > Sr > Ba) was characterized by a blue shift of characteristic IR peaks, thus offering a t

196 The observed 18 nm blue shift of emission is explained by strong dispersion

197 The blue shift of mOrange is induced by an unprecedented cov

198 solid films exhibit a temperature-dependent blue shift of optical absorption peaks due to a continuo

199 ed nanoparticles (2 nm), demonstrated as the blue shift of particle absorption, diminishes SERS enhan

200 For example, a blue shift of the absorption max from 373 to 332 nm was

201 ted by nucleophilic addition, resulting in a blue shift of the absorption maxima and a dramatic decre

202 hromophore fluorescence emission and a 45 nm blue shift of the absorption maximum with an increase in

203 ed spectroscopically by the observation of a blue shift of the CO stretching mode in the IR spectrum

204 A consistent blue shift of the CR domain tryptophan fluorescence sugg

205 incubation with proteinase K, a conspicuous blue shift of the EOT is observed, which is attributed t

206 the anionic charge of membranes results in a blue shift of the fluorescence of Trp(3) of hIBPLA(2), a

207 rsion of adduct I to the azo tautomer with a blue shift of the lambda(max) to 420 nm, close to that o

208 jection of electrons into TiO2 resulted in a blue shift of the metal-to-ligand charge transfer absorp

209 s alpha-helical circular dichroism spectrum, blue shift of the native state tryptophan fluorescence,

210 arrow PL, strong excitonic absorption, and a blue shift of the optical band gap by more than 0.47 eV

211 ploiting Al nanoparticle arrays results in a blue shift of the resonance, enabling the first demonstr

212 ta-substitution produces little variation or blue shift of the SubPz Q-band, while bathochromic shift

213 HGNs exhibit an unexpected, but systematic, blue shift of the surface plasmon resonance spectral pos

214 the infrared spectra, most notably a strong blue shift of the symmetric hydrogen stretching fundamen

215 structures, we revealed significant red and blue shifts of characteristic Raman modes up to 100 cm(-

216 n on the nanoLCA sensor also showed spectral blue shifts of CYP2J2 following substrate binding.

217 d by measuring, respectively, the saturating blue shifts of fluorescence emission at high lipid:tetra

218 The slight blue shifts of the CT band follow the trend of stronger

219 Blue shifts of up to 30 nm in PL emission wavelength max

220 The MD simulations indicate that the blue-shift of -CN stretching vibration induced by haloth

221 minescence measurements exhibit a negligible blue-shift of 1.6 nm in the peak wavelength of the main

222 or with a below-bandgap laser pulse causes a blue-shift of the bandgap transition energy, known as th

223 The blue-shift of the Citrine fluorescence spectrum resultin

224 This results in a continuous blue-shift of the coupled plasmon from near infrared to

225 absorption on TiO2 films with up to a 250 nm blue-shift of the dye absorption onset on TiO2.

226 he infrared spectra from experiment showed a blue-shift of the nitrile vibrational frequency in the p

227 partial Pb(2+) for M(2+) exchange leads to a blue-shift of the optical spectra, while maintaining the

228 um of blue proteorhodopsin (BPR) is the most blue-shifted of all retinal proteins found in archaea or

229 ovides structural insight into the transient blue-shifting of isolated yellow fluorescent protein mol

230 We observed a classical optical effect: the blue-shifting of light at a white-hole horizon.

231 We observe an anomalous blue-shifting of the lasing gain profile with time up to

232 nominally MLCT transitions and accompanying blue-shifts of the visible absorptions, as the ligand pi

233 ts were especially manifested in the overall blue-shifts of the VSCF frequencies relative to the harm

234 e to bulk water, which is in contrast to the blue-shift often observed in systems such as water nanop

235 showed generally increased fluorescence with blue shift on deletion of the N-terminal domain in the d

236 rge-transfer states, as evidenced by a rapid blue shift on the electronic axis of our 2D-EV spectra.

237 lectromagnetic simulation suggested that the blue shift on the nanoLCA is because of the hybridizatio

238 ed chromophoric films exhibit a dramatically blue-shifted optical maximum (325 nm) while maintaining

239 chromophore is found to exhibit a remarkably blue-shifted optical maximum (357 nm in CH(2)Cl(2)) whil

240 membrane-intercalating COE, DSSN+, which has blue-shifted optical properties making it compatible for

241 ular dynamics simulations indicate that this blue shift originates from strong coupling between the h

242 pi-hydrogen bonds (red-shifting O-H...pi and blue-shifting ortho-C-H...pi) contribute to the stabilit

243 tion produced from the heavy oil became more blue-shifted over time, while the light oil produced a m

244 parts, the near-IR absorption of the HNPs is blue-shifted owing to the hollow interior.

245 In addition, the low blue-shift phenomenon of semi-polar (20[Formula: see tex

246 ion of a previously unknown light-sensitive, blue-shifted photocycle intermediate L (lambdamax = 495

247 the solid-liquid interface) by anti-Stokes (blue-shifted) photons following upconversion of Yb(3+) e

248 ted for the formation of emissive spectrally blue-shifted photoproducts.

249 red photoconvertable variant, PSmOrange2 has blue-shifted photoswitching action spectrum, 9-fold high

250 a series of 12 N-acetates 2 predict the most blue-shifted pi --> pi* transition for the alkoxy substi

251 -165 are key side chains responsible for the blue shift, presumably by localizing chromophore charge

252 The blue-shifted products give a dark-field sensing scheme t

253 Chl c homologs with smaller side chains, (c) blue-shifted Qy absorption maxima, and (d) a sigmoid-sha

254 ng an absorption maximum at 898 nm, an 85 nm blue shift relative to the beta-carotene radical cation

255 lecules with Ag-Fe(CO)5 bonds show a notable blue shift relative to those observed for free Fe(CO)5,

256 nocrystals (E(g) = 1.71 eV) is significantly blue-shifted relative to the bulk value (E(g) = 1.30 eV)

257 re strongly coupled, and the frequencies are blue-shifted relative to the free gas.

258 Here we report the detection of highly blue-shifted resonance lines of the singly ionized radio

259 find evidence for a functional and unusually blue-shifted rhodopsin that is expressed in small single

260 Specifically, blue-shifts seen upon treatment of H-bonding catalysts w

261 cence quenching together with a Trp emission blue shift showed that the Trp residues remain largely s

262 fted side of the spectrum faster than on the blue shifted side, facilitated by cascaded stimulated Ra

263 The adsorbed CO vibrational frequency blue-shifts slightly (approximately 4 cm(-)(1)) compared

264 solution exhibit RLS when excited within the blue-shifted Soret band (H band) and produce AFM images

265 nite or natural redox partners), including a blue-shifted Soret band and development of a strong feat

266 d the intermediate 1, which displays a weak, blue-shifted Soret band at 402 nm and an absorbance at 6

267 eins with BV covalently bound to Cys256 have blue-shifted spectra and higher quantum yield.

268 Ps with both Cys residues have the narrowest blue-shifted spectra and the highest quantum yield.

269 th respect to that in the gas phase, but the blue-shifted spectrum observed in water at pH 3 is domin

270 nd triplet energy levels (E(S) and E(T)) and blue shifts the absorption and emission bands.

271 onating group at the meso position of BODIPY blue shifts the absorption and emission with decreased f

272 and addition of a water molecule is found to blue-shift the absorption by approximately 50 nm (0.23 e

273 lower refractive index substrate in order to blue-shift the back-side surface plasmon.

274 the unmodified thiolate Fe-S bond length and blue-shift the ligand-to-metal charge-transfer band (wit

275 ogel, reduce the 2D PC particle spacing, and blue-shift the light diffracted from the PC.

276 The excitonic effects split and blue-shift the Soret absorptions, and slightly broaden t

277 The purpose was to test the hypothesis that blue-shifting the pigment by switching from A2 to A1 wil

278 A blue shift to higher frequencies of the CN vibration to

279 ECL emission of 640 nm, which is about 55 nm blue shift to its fluorescence, was observed in MeCN wit

280 BChl c in the mutant cells were narrower and blue shifted to various extents.

281 a, and Phe250Ser, whose emission maximum was blue-shifted to 549 nm, providing a set of enzymes whose

282 The relevance of the sensor blue-shifts to the LUMO-lowering abilities of the H-bond

283 he absorption onset of the CdSe quantum dots blue shifted toward higher energies at 3 eV (414 nm), wh

284 ts in the solid state displayed an analogous blue-shifted transient with a lambdamax= 510 nm that fir

285 mines the PL wavelength and thus the PL peak blue shifts upon decreasing the Si NC size.

286 increased variance of Doppler frequency, and blue-shifted UV absorbance (stimuli-responsive imaging).

287 Large blue-shifted UV-vis absorption and PL spectra have been

288 lectronic properties, including exfoliation, blue-shifted UV-vis absorption, altered luminescence, mo

289 ween 1 and 3 nm, which resulted in sharp and blue-shifted UV-vis and PL peaks due to one-dimensional

290 Even for E181D, an anomalously large blue shift was observed in the absorption spectrum of th

291 nking meso-aryl groups leads to a sharpened, blue-shifted wavelength lambdamax band, bucking the gene

292 uencies relative to the harmonic values, and blue shifts were attributed to the overall positive coup

293 At the highest level of theory, blue shifts were obtained for BF...HCl and CO...HCl, whi

294 ons are larger than the Eu(2+) dopant, but a blue shift when the M = Ca host is smaller.

295 e UV absorption of these fused thiophenes is blue-shifted when compared with their hydrocarbon counte

296 measured absorption spectrum is unexpectedly blue shifted, which is potentially due to the intense el

297 oluminescence measurements reveal an unusual blue-shift with increasing temperature, closely linked t

298 nic properties: (i) fluorescence emission is blue-shifted with respect to [8]cycloparaphenylene 1, an

299 cluster reveals that the optical band gap is blue-shifted with respect to a cluster containing only 1

300 cements in emission intensity coupled with a blue shift (Zn(2+)).