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Fluorescent spectrum

An important extension to the simplest upconversion experiment at a single detection frequency M2 is the practice of measuring time-resolvedfluorescence spectra, that is, the shape of the fluorescence spectrum... [Pg.1977]

The example of a X emission X-ray fluorescence spectrum of a solid sample of tin, shown in Figure 8.30, shows four prominent transitions. The method of labelling the transitions is, unfortunately, non-systematic but those in the lower-energy group are labelled a and the... [Pg.325]

Pyridin-2-one, 1-hydroxy-fluorescence spectrum, 2, 163 (81XL1515) Pyridin-2-one, 6-methoxy-pK 2, 151 <71JCS(B)289)... [Pg.52]

Thiophene, 2-phenyl-fluorescence spectrum, 4, 735 (7UOC2236) Thiophene, 2-propionyl-... [Pg.72]

Benzo[ghi]perylene (1,12-benzoperylene) [191-24-2] M 276,3, m 273°, 277-278.5°, 278-280°, Purified as light green crystals by recrystn from CfiH6 or xylene and sublimes at 320-340° and 0.05mm [UV Helv Chim Acta 42 2315 7959 Chem Ber 65 846 1932 Fluoresc. Spectrum J Chem Soc 3875 7954]. 1,3,5-Trinitrobenzene complex m 310-313° (deep red crystals from C6Hg) picrate m 267-270° (dark red crystals from CgH6) styphnate (2,4,6-trinitroresorcinol complex) m 234° (wine red crystals from CgH6). It recrystallises from propan-l-ol [J Chem Soc 466 7959]. [Pg.123]

The optical train employed for photometric determinations of fluorescence depends on the problem involved. A spectral resolution of the emitted fluorescence is not necessary for quantitative determinations. The optical train sketched in Figure 22B can, therefore, be employed. If the fluorescence spectrum is to be determined the fluorescent light has to be analyzed into its component parts before reaching the detector (Fig. 28). A mercury or xenon lamp is used for excitation in such cases. [Pg.38]

In 1967 spraying with a solution of paraffin wax allowed the recording of the fluorescence spectrum of anthracene directly on the TLC plate without any difficulties [228]. Hellmann too was able to stabilize emissions by the addition of 2% paraffin to the solvent [229]. Low concentrations evidently serve primarily to stabilize the fluorescence — this stabilization concentration extends up to ca... [Pg.100]

Pfleiderer has suggested that the 7-hydroxy group exists as such in these compounds because this form is stabilized by mesomerism of type 191 (R — H). The tautomerism of 7-hydroxypteridine-2,4-dione in the excited electronic state has been studied on the basis of its fluorescence spectrum. [Pg.395]

In these special situations, other methods, such as electronic microscopy, IR spectrum, and fluorescence spectrum are to be used. [Pg.138]

The room temperature Raman spectrum excited in pre-resonance conditions [351 indeed shows bands at 169 cm-1 and 306 cm, which are in agreement with the modes observed in the fluorescence spectrum and that have been assigned by ab initio calculations to totally symmetric vibrations jl3). [Pg.409]

Tabic 6-5. Comparison of (he aK vibrational modes in the ground and excited states. The totally symmetric vibrations of the ground stale measured in tire Raman spectrum excited in pre-resonance conditions 3S] and in the fluorescence spectrum ]62 ate compared with the results of ab initio calculations [131- The corresponding vibrations in the excited stale arc measured in die absorption spectrum. [Pg.416]

The fluorescence spectrum of dibenz[7>,/]oxepin shows that this molecule adopts a planar structure in the excited state whereas the ground state has bent geometry as expected.19 The emission spectrum is similar to that of anthracene. [Pg.2]

According to Charbonneau et al. (1985), aequorin is a single chain peptide consisting of 189 amino acid residues, with an unblocked amino terminal. The molecule contains three cysteine residues and three EF-hand Ca2+-binding domains. The absorption spectra of aequorin and BFP are shown in Fig. 4.1.3, together with the luminescence spectrum of aequorin and the fluorescence spectrum of BFP. [Pg.101]

Fig. 7.1.5 Fluorescence spectra of purified Chaetopterus photoprotein (CPA) in 10 mM ammonium acetate, pH 6.7 (solid lines), and the bioluminescence spectrum of the luminous slime of Chaetopterus in 10 mM Tris-HCl, pH 7.2 (dashed line). Note that the luminescence spectrum of Chaetopterus photoprotein in 2 ml of 10 mM Tris-HCl, pH 7.2, containing 0.5 M NaCl, 5 pi of old dioxane and 2 pi of 10 mM FeSC>4 (Amax 453-455 nm) matched exactly with the fluorescence emission spectrum of the photoprotein. No significant change was observed in the fluorescence spectrum after the luminescence reaction. Fig. 7.1.5 Fluorescence spectra of purified Chaetopterus photoprotein (CPA) in 10 mM ammonium acetate, pH 6.7 (solid lines), and the bioluminescence spectrum of the luminous slime of Chaetopterus in 10 mM Tris-HCl, pH 7.2 (dashed line). Note that the luminescence spectrum of Chaetopterus photoprotein in 2 ml of 10 mM Tris-HCl, pH 7.2, containing 0.5 M NaCl, 5 pi of old dioxane and 2 pi of 10 mM FeSC>4 (Amax 453-455 nm) matched exactly with the fluorescence emission spectrum of the photoprotein. No significant change was observed in the fluorescence spectrum after the luminescence reaction.
Harvey (1952) demonstrated the luciferin-luciferase reaction with O. phosphorea collected at Nanaimo, British Columbia, Canada, and with O. enopla from Bermuda. McElroy (1960) partially purified the luciferin, and found that the luminescence spectrum of the luciferin-luciferase reaction of O. enopla is identical to the fluorescence spectrum of the luciferin (A.max 510 nm), and also that the luciferin is auto-oxidized by molecular oxygen without light emission. Further investigation on the bioluminescence of Odontosyllis has been made by Shimomura etal. (1963d, 1964) and Trainor (1979). Although the phenomenon is well known, the chemical structure of the luciferin and the mechanism of the luminescence reaction have not been elucidated. [Pg.226]

A number of investigations of the copper-group oxides and dioxygen complexes have been reported. The electronic spectra of CuO, AgO, and AuO were recorded in rare-gas matrices (9), and it was found that the three oxides could be formed effectively by cocondensation of the metal atoms with a dilute, oxygen matrix, followed by near-ultraviolet excitation. The effective wavelengths for CuO or AgO formation were X > 300 nm and for AuO was X > 200 nm. In addition, the laser fluorescence spectrum of CuO in solid Ar has been recorded (97). [Pg.139]

Figure 9. Chemiluminescence emission spectra from the two pulses with DPA as the acceptor inset is DPA fluorescence spectrum. (Reproduced from Ref. 24. Copyright 1986 American Chemical Society.)... Figure 9. Chemiluminescence emission spectra from the two pulses with DPA as the acceptor inset is DPA fluorescence spectrum. (Reproduced from Ref. 24. Copyright 1986 American Chemical Society.)...
Figure 1. (a) Room-temperature fluorescence spectra of benzo(a)pyrene on 80% a-Room-temperature fluorescence spectrum of 500 ng of benzo(a)pyrene on 80% a-<7clodextrin—NaCl. = 300 nm. [Pg.158]

To qualify the environment into which the colorant molecule is embedded, the actual fluorescence spectrum is compared with the one under standard conditions. If the fluorescence emission spectrum is shifted to longer wavelengths (bathochromic shift), it can be concluded that the molecular enviromnent is of a more polar nature or is polarized by the excited fluorophore. Conversely, a fluorescence shift to shorter wavelengths (hypsochromic shift) indicates a transfer of the fluorophore from a polar... [Pg.13]

Such a qualitative conclusion is supported by the observation that the room-temperature fluorescence spectrum of BMPC in alcohols (Fig. 8) is a good mirror image... [Pg.392]

Palmatine (Scheme 1) bears the same tetracychc structure as berberine but differs in the nature of the substituents on the benzo ring being methylene dioxy for berberine and dimethoxy for palmatine. In aqueous buffer, the UV-visible spectriun of palmatine shows maxima at 232, 268, 344.5 and 420 nm. Palmatine has a weak fluorescence spectrum in the range 400-650 nm with... [Pg.174]


See other pages where Fluorescent spectrum is mentioned: [Pg.256]    [Pg.1132]    [Pg.1978]    [Pg.426]    [Pg.2]    [Pg.71]    [Pg.106]    [Pg.439]    [Pg.102]    [Pg.105]    [Pg.409]    [Pg.483]    [Pg.172]    [Pg.259]    [Pg.461]    [Pg.163]    [Pg.167]    [Pg.167]    [Pg.167]    [Pg.168]    [Pg.8]    [Pg.22]    [Pg.32]    [Pg.218]    [Pg.169]   
See also in sourсe #XX -- [ Pg.841 ]




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Fluorescence spectra

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