Principles of Fluorescence Spectroscopy

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PRINCIPLES OF FLUORESCENCE SPECTROSCOPY 349 19. Parmenter CS, Rau JD. 1969. Fluorescence quenching in aromatic hydrocarbons by oxygen. J Chem Phys 51(5):2242–2246. 20. Camyshan SV, Gritsan NP, Korolev VV, Bazhin NM. 1990. Quenching of the luminescence of organic compounds by oxygen in glassy matrices. Chem Phys 142:59–68. 21. Alford PC, Cureton CG, Lampert RA, Phillips D. 1983. Fluorescence quenching of tertiary amines by halocarbons. Chem Phys 76:103–109. 22. Najbar J, Mac M. 1991. Mechanisms of fluorescence quenching of aromatic molecules by potassium iodide and potassium bromide in methanol-ethanol solutions. J Chem Soc Faraday Trans 87(10): 1523–1529. 23. Goswami D, Sarpal RS, Dogra SK. 1991. Fluorescence quenching of few aromatic amines by chlorinated methanes. Chem Soc Jpn 64:3137–3141. 24. Bortolus P, Bartocci G, Mazzucato U. 1975. Excited state reactivity of aza aromatics, III: quenching of fluorescence and photoisomerization of azastilbenes by inorganic anions. J Phys Chem 79:21–25. 25. Watkins AR. 1974. Kinetics of fluorescence quenching by inorganic anions. J Phys Chem 78(25):2555–2558. 26. Carrigan S, Doucette S, Jones C, Marzzacco CJ, Halpern AM. 1996. The fluorescence quenching of 5,6-benzoquinoline and its conjugate acid by Cl – ,Br – , SCN – and I – ions. J Photochem Photobiol A: Chem 99:29–35. 27. Ahmad A, Durocher G. 1981. Fluorescence quenching of carbazole by holocarbons in 3-methylpentane solutions at room temperature. Can J Spectrosc 26(1):19–24. 28. Ahmad A, Durocher G. 1981. How hydrogen bonding of carbazole to ethanol affects its fluorescence quenching rate by electron acceptor quencher molecules. Photochem Photobiol 34:573–578. 29. Namiki A, Nakashima N, Yoshinara K. 1979. Fluorescence quenching due to the electron transfer: indole-chloromethanes in rigid ethanol glass. J Chem Phys 71(2):925–932. 30. Tucker SA, Cretella LE, Waris R, Street KW, Acree WE, Fetzer JC. 1990. Polycyclic aromatic hydrocarbon solute probes, VI: effect of dissolved oxygen and halogenated solvents on the emission spectra of select probe molecules. Appl Spectrosc 44:269–273. 31. Takahashi T, Kikuchi K, Kokubun H. 1980. Quenching of excited 2,5-diphenyloxazole by CCl 4 . J Photochem 14:67–76. 32. Ellison EH, Thoms JK. 2001. Photoinduced reaction of arene singlets with carbon tetrachloride in zeolite Y. Microporous Mesoporous Mater 49(1–3):15-24. 33. Encinas MV, Rubio MA, Lissi EA. 1982. Quenching and photobleaching of excited polycyclic aromatic hydrocarbons by carbon tetrachloride. J Photochem 18:137–150. 34. Dexter DL. 1953. A theory of sensitized luminescence in solids. J Chem Phys 21(5):836–850. 35. Inokuti M, Hirayama F. 1965. Influence of energy transfer by the exchange mechanism on donor luminescence. J Chem Phys 43(6): 1978–1989. 36. Kobayashi H, Morita T. 1973. Influence of triplet–triplet excitation transfer on the decay function of donor luminescence. 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Enhancement of quenching of polymer-bound ruthenium (II) complexes with MV 2+ using L-tyrosine esters. Eur Polym J 35:221–226. 53. Namiki A, Nakashima N, Yoshihara K. 1979. Fluorescence quenching due to the electron transfer: indole-chloromethanes in rigid ethanol glass. J Chem Phys 71(2):925–930.
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Drei vortage über diffusion, brownsche molekularbewegung und koagulation von kolloidteilchen [Three lectures on diffusion, Brownian molecular motion and coagulation of colloids]. Z Physik 17:557–571, 585–599. (An English translation is available in Chandrasekhar S, Kac M, Smoluchowski R. 1986. Marian Smoluchowski, his life and scientific work. Polish Scientific Publishers, Warsaw.) 71. Collins FC, Kimball GE. 1949. Diffusion-controlled reaction rates. J Colloid Sci 4:425–437. (See also Collins FC. 1950. J Colloid Sci 5:499–505 for correction.) 72. Yguerabide J, Dillon MA, Burton M. 1964. Kinetics of diffusioncontrolled processes in liquids: theoretical consideration of luminescent systems—quenching and excitation transfer in collision. J Chem Phys 40(10):3040–3052. 73. Ware WR, Novros JS. 1966. Kinetics of diffusion-controlled reactions: an experimental test of theory as applied to fluorescence quenching. J Phys Chem 70:3246–3253. 74. Ware WR, Andre JC. 1980. The influence of diffusion on fluorescence quenching. In Time-resolved fluorescence spectroscopy in biochemistry and biology, pp. 363–392. Ed RB Cundall, RE Dale. Plenum Press, New York. 75. Lakowicz JR, Johnson ML, Gryczynski I, Joshi N, Laczko G. 1987. Transient effects in fluorescence quenching measured by 2-GHz frequency-domain fluorometry. J Phys Chem 91:3277–3285. 76. Periasamy N, Doraiswamy S, Venkataraman B, Fleming GR. 1988. Diffusion controlled reactions: experimental verification of the timedependent rate equation. J Chem Phys 89(8):4799–4806. 77. Lakowicz JR, Kusba, J., Szmacinski H, Johnson ML, Gryczynski I. 1993. Distance-dependent fluorescence quenching observed by frequency-domain fluorometry. Chem Phys Lett 206(5,6):455–463. 78. Lakowicz JR, Zelent B, Gryczynski I, Kusba J, Johnson ML. 1994. Distance-dependent fluorescence quenching of tryptophan by acrylamide. Photochem Photobiol 60(3):205–214. 79. Naumann W. 2000. Reversible fluorescence quenching: generalized Stern-Volmer equations on the basis of self-consistent quenching constant relations. J Chem Phys 112(16):7152–7157. 80. Zelent B, Kusba J, Gryczynski I, Johnson ML, Lakowicz JR. 1996. Distance-dependent fluorescence quenching of p-bis[2-(5-phenyloxazolyl)]benzene by various quenchers. J Phys Chem 100:18592– 18602. 81. Lakowicz JR, Zelent B, Kusba J, Gryczynski I. 1996. Distancedependent quenching of nile blue fluorescence by N,N-diethylaniline observed by frequency-domain fluorometry. J Fluoresc 6(4): 187–194. 82. Naqvi KR, Martins J, Melo E. 2000. Recipes for analyzing diffusioncontrolled reactions in two dimensions: time-resolved and steadystate measurements. J Phys Chem B 104:12035–12038. 83. Kusba J, Lakowicz JR. 1994. Diffusion-modulated energy transfer and quenching: analysis by numerical integration of diffusion equation in Laplace space. Methods Enzymol 240:216–262. 84. Novikov E, Molski A, Boens N. 2000. Identifiability of a model for diffusion-mediated intramolecular excited-state quenching. J Chem Phys 112(12):5348–5352. 85. Gladkikh VS, Burshtein AI, Tavernier HL, Fayer MD. 2002. Influence of diffusion on the kinetics of donor–acceptor electron transfer monitored by the quenching of donor fluorescence. J Phys Chem A 106:6982–6990. 86. Owen CS, Vanderkooi JM. 1991. Diffusion-dependent and -independent collisional quenching of fluorescence and phosphorescence. Comments Mol Cell Biophys 7(4):235–257.
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Principles of Fluorescence Spectros
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Joseph R. Lakowicz Center for Fluor
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Preface The first edition of Princi
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x GLOSSARY OF ACRONYMS DNS dansyl o
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xii GLOSSARY OF ACRONYMS TRES time-
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xiv GLOSSARY OF MATHEMATICAL TERMS
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xvi CONTENTS 2.9.4. Conversion betw
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xviii CONTENTS 6. Solvent and Envir
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xx CONTENTS 10.4.4. Alignment of Po
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xxii CONTENTS 14.7.1. Simulations o
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xxiv CONTENTS 19.12. New Approaches
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xxvi CONTENTS 25.3. Optical Propert
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2 INTRODUCTION TO FLUORESCENCE Figu
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6 INTRODUCTION TO FLUORESCENCE inst
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10 INTRODUCTION TO FLUORESCENCE Fig
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12 INTRODUCTION TO FLUORESCENCE ns,
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14 INTRODUCTION TO FLUORESCENCE 1.7
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24 INTRODUCTION TO FLUORESCENCE due
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28 INSTRUMENTATION FOR FLUORESCENCE
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3 Fluorescence probes represent the
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PRINCIPLES OF FLUORESCENCE SPECTROS
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98 TIME-DOMAIN LIFETIME MEASUREMENT
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100 TIME-DOMAIN LIFETIME MEASUREMEN
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238 DYNAMICS OF SOLVENT AND SPECTRA
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278 QUENCHING OF FLUORESCENCE 8.1.
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282 QUENCHING OF FLUORESCENCE ly ev
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290 QUENCHING OF FLUORESCENCE relat
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12 In the preceding two chapters we
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444 ENERGY TRANSFER Figure 13.1. Fl
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446 ENERGY TRANSFER wavelength is e
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448 ENERGY TRANSFER Table 13.1. Cal
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450 ENERGY TRANSFER Figure 13.6. Ab
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452 ENERGY TRANSFER safe for many p
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454 ENERGY TRANSFER Figure 13.12. P
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456 ENERGY TRANSFER Figure 13.16. E
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458 ENERGY TRANSFER Figure 13.21. R
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460 ENERGY TRANSFER Figure 13.24. R
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462 ENERGY TRANSFER tiple acceptors
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464 ENERGY TRANSFER Figure 13.29. A
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466 ENERGY TRANSFER Figure 13.33. F
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468 ENERGY TRANSFER Table 13.3. Rep
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470 ENERGY TRANSFER 55. Clegg RM. 1
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472 ENERGY TRANSFER Tong AK, Jockus
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474 ENERGY TRANSFER Figure 13.39. O
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14 In the previous chapter we descr
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16 The biochemical applications of
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578 TIME-RESOLVED PROTEIN FLUORESCE
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608 MULTIPHOTON EXCITATION AND MICR
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19 Fluorescence sensing of chemical
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676 NOVEL FLUOROPHORES Figure 20.1.
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678 NOVEL FLUOROPHORES Figure 20.7.
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680 NOVEL FLUOROPHORES Figure 20.12
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698 NOVEL FLUOROPHORES 33. Acherman
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700 NOVEL FLUOROPHORES 103. Demas J
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702 NOVEL FLUOROPHORES 176. Montalt
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21 During the past 20 years there h
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22 Fluorescence microscopy is one o
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758 SINGLE-MOLECULE DETECTION Figur
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770 SINGLE-MOLECULE DETECTION Table
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788 SINGLE-MOLECULE DETECTION TCSPC
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790 SINGLE-MOLECULE DETECTION 53. H
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792 SINGLE-MOLECULE DETECTION Ke PC
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794 SINGLE-MOLECULE DETECTION Polar
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862 RADIATIVE-DECAY ENGINEERING: SU
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Appendix I Corrected Emission Spect
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Appendix II Fluorescence Lifetime S
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890 APPENDIX III P ADDITIONAL READI
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892 APPENDIX III P ADDITIONAL READI
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894 ANSWERS TO PROBLEMS A1.4. A. Th
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896 ANSWERS TO PROBLEMS Energy tran
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898 ANSWERS TO PROBLEMS Figure 4.65
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900 ANSWERS TO PROBLEMS expected to
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904 ANSWERS TO PROBLEMS where f is
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906 ANSWERS TO PROBLEMS [BSA] Obser
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908 ANSWERS TO PROBLEMS emission. T
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910 ANSWERS TO PROBLEMS dx rA A (
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912 ANSWERS TO PROBLEMS B. A covale
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920 ANSWERS TO PROBLEMS CHAPTER 24
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Index A Absorption spectroscopy, 12
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Principles of Fluorescence Spectroscopy

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