Principles of Fluorescence Spectroscopy

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PRINCIPLES OF FLUORESCENCE SPECTROSCOPY 319 12. Ware WR. 1962. Oxygen quenching of fluorescence in solution: An experimental study of the diffusion process. J Phys Chem 66:455–458. 13. Othmer DF, Thakar MS. 1953. Correlating diffusion coefficients in liquids. Ind Eng Chem Res 45:589–593. 14. Lakowicz JR, Weber G. 1973. Quenching of fluorescence by oxygen: a probe for structural fluctuation in macromolecule. Biochemistry 12:4161–4170. 15. Eftink MR, Ghiron CA. 1977. Exposure of tryptophanyl residues and protein dynamics. Biochemistry 16:5546–5551. 16. Johnson DA, Yguerabide J. 1985. Solute accessibility to N'-fluorescein isothiocyanate-lysine-23: cobra "-toxin bound to the acetylcholine receptor. Biophys J 48:949–955. 17. Kubota Y, Nakamura H, Morishita M, Fujisaki Y. 1978. Interaction of 9-aminoacridine with 7-methylguanosine and 1,N 6 -ethenoadenosine monophosphate. Photochem Photobiol 27:479–481. 18. Kubota Y, Motoda Y, Shigemune Y, Fujisaki Y. 1979. Fluorescence quenching of 10-methylacridinium chloride by nucleotides. Photochem Photobiol 29:1099–1106. 19. Seidel CAM, Schulz A, Sauer MHM. 1996. Nucleobase-specific quenching of fluorescent dyes, 1: nucleobase one-electron redox potentials and their correlation with static and dynamic quenching efficiencies. J Phys Chem 100:5541–5553. 20. Eftink MR, Ghiron CA. 1976. Fluorescence quenching of indole and model micelle systems. J Phys Chem 80:486–493. 21. Casali E, Petra PH, Ross JBA. 1990. Fluorescence investigation of the sex steroid binding protein of rabbit serum: steroid binding and subunit dissociation. Biochemistry 29:9334–9343. 22. Frank IM, Vavilov SI. 1931. Über die wirkungssphäre der auslöschuns-vargänge in den flureszierenden flussig-keiten. Z Phys 69:100–110. 23. Maniara G, Vanderkooi JM, Bloomgarden DC, Koloczek H. 1988. Phosphorescence from 2-(p-toluidinyl)naphthalene-6-sulfonate and 1-anilinonaphthalene-8-sulfonate, commonly used fluorescence probes of biological structures. Photochem Photobiol 47(2): 207–208. 24. Kim H, Crouch SR, Zabik MJ. 1989. Room-temperature phosphorescence of compounds in mixed organized media: synthetic enzyme model-surfactant system. Anal Chem 61:2475–2478. 25. Encinas MV, Lissi EA, Rufs AM. 1993. Inclusion and fluorescence quenching of 2,3-dimethylnaphthalene in $-cyclodextrin cavities. Photochem Photobiol 57(4):603–608. 26. Turro NJ, Bolt JD, Kuroda Y, Tabushi I. 1982. A study of the kinetics of inclusion of halonaphthalenes with $-cyclodextrin via time correlated phosphorescence. Photochem Photobiol 35:69–72. 27. Waka Y, Hamamoto K, Mataga N. 1980. Heteroexcimer systems in aqueous micellar solutions. Photochem Photobiol 32:27–35. 28. Atherton SJ, Beaumont PC. 1986. Quenching of the fluorescence of DNA-intercalated ethidium bromide by some transition metal ions. J Phys Chem 90:2252–2259. 29. Pasternack RF, Caccam M, Keogh B, Stephenson TA, Williams AP, Gibbs EJ. 1991. Long-range fluorescence quenching of ethidium ion by cationic porphyrins in the presence of DNA. J Am Chem Soc 113: 6835–6840. 30. Poulos AT, Kuzmin V, Geacintov NE. 1982. Probing the microenvironment of benzo[a]pyrene diol epoxide-DNA adducts by triplet excited state quenching methods. J Biochem Biophys Methods 6:269–281. 31. Zinger D, Geacintov NF. 1988. Acrylamide and molecular oxygen fluorescence quenching as a probe of solvent-accessibility of aromatic fluorophores complexed with DNA in relation to their conformations: coronene-DNA and other complexes. Photochem Photobiol 47:181–188. 32. Suh D, Chaires JB. 1995. Criteria for the mode of binding of DNA binding agents. Bioorgan Med Chem 3(6):723–728. 33. Ando T, Asai H. 1980. Charge effects on the dynamic quenching of fluorescence of fluorescence of 1,N 6 -ethenoadenosine oligophosphates by iodide, thallium (I) and acrylamide. J Biochem 88: 255–264. 34. Ando T, Fujisaki H, Asai H. 1980. Electric potential at regions near the two specific thiols of heavy meromyosin determined by the fluorescence quenching technique. J Biochem 88:265–276. 35. Miyata H, Asai H. 1981. Amphoteric charge distribution at the enzymatic site of 1,N 6 -ethenoadenosine triphosphate-binding heavy meromyosin determined by dynamic fluorescence quenching. J Biochem 90:133–139. 36. Midoux P, Wahl P, Auchet J-C, Monsigny M. 1984. Fluorescence quenching of tryptophan by trifluoroacetamide. Biochim Biophys Acta 801:16–25. 37. Lehrer SS. 1971. Solute perturbation of protein fluorescence: the quenching of the tryptophan fluorescence of model compounds and of lysozyme by iodide ion. Biochemistry 10:3254–3263. 38. Kao S, Asanov AN, Oldham PB. 1998. A comparison of fluorescence inner-filter effects for different cell configurations. Instrum Sci Technol 26(4):375–387. 39. Fanget B, Devos O. 2003. Correction of inner filter effect in mirror coating cells for trace level fluorescence measurements. Anal Chem 75:2790–2795. 40. Eftink MR, Selvidge LA. 1982. Fluorescence quenching of liver alcohol dehydrogenase by acrylamide. Biochemistry 21:117–125. 41. Eftink M, Hagaman KA. 1986. Fluorescence lifetime and anisotropy studies with liver alcohol dehydrogenase and its complexes. Biochemistry 25:6631–6637. 42. Xing D, Dorr R, Cunningham RP, Scholes CP. 1995. Endonuclease III interactions with DNA substrates, 2: the DNA repair enzyme endonuclease III binds differently to intact DNA and to apyrimidinic/apurinic DNA substrates as shown by tryptophan fluorescence quenching. Biochemistry 34:2537–2544. 43. Sontag B, Reboud A-M, Divita G, Di Pietro A, Guillot D, Reboud JP. 1993. Intrinsic tryptophan fluorescence of rat liver elongation factor eEF-2 to monitor the interaction with guanylic and adenylic nucleotides and related conformational changes. Biochemistry 32: 1976–1980. 44. Wasylewski M, Malecki J, Wasylewski Z. 1995. Fluorescence study of Escherichia coli cyclic AMP receptor protein. J Protein Chem 14(5):299–308. 45. Hannemann F, Bera AK, Fischer B, Lisurek M, Teuchner K, Bernhardt R. 2002. Unfolding and conformational studies on bovine adrenodoxin probed by engineered intrinsic tryptophan fluorescence. Biochemistry 41:11008–11016. 46. Soulages JL, Arrese EL. 2000. Fluorescence spectroscopy of single tryptophan mutants of apolipophorin-III in discoidal lipoproteins of dimyristoylphosphatidylcholine. Biochemistry 39:10574–10580.
320 QUENCHING OF FLUORESCENCE 47. Raja SM, Rawat SS, Chattopadhyay A, Lala AK. 1999. Localization and environment of tryptophans in soluble and membrane-bound states of a pore-forming toxin from Staphylococcus aureus. Biophys J 76:1469–1479. 48. Weber J, Senior AE. 2000. Features of F 1-ATPase catalytic and noncatalytic sites revealed by fluorescence lifetimes and acrylamide quenching of specifically inserted tryptophan residues. Biochemistry 39:5287–5294. 49. Wells TA, Nakazawa M, Manabe K, Song P-S. 1994. A conformational change associated with the phototransformation of Pisum phytochrome A as probed by fluorescence quenching. Biochemistry 33:708–712. 50. Eftink MR, Zajicek JL, Ghiron CA. 1977. A hydrophobic quencher of protein fluorescence: 2,2,2-trichloroethanol. Biochim Biophys Acta 491:473–481. 51. Blatt E, Husain A, Sawyer WH. 1986. The association of acrylamide with proteins: the interpretation of fluorescence quenching experiments. Biochim Biophys Acta 871:6–13. 52. Eftink MR, Ghiron CA. 1987. Does the fluorescence quencher acrylamide bind to proteins? Biochim Biophys Acta 916:343–349. 53. Punyiczki M, Norman JA, Rosenberg A. 1993. Interaction of acrylamide with proteins in the concentration range used for fluorescence quenching studies. Biophys Chem 47:9–19. 54. Bastyns K, Engelborghs Y. 1992. Acrylamide quenching of the fluorescence of glyceraldehyde-3-phosphate dehydrogenase: reversible and irreversible effects. Photochem Photobiol 55:9–16. 55. Merrill AR, Palmer LR, Szabo AG. 1993. Acrylamide quenching of the intrinsic fluorescence of tryptophan residues genetically engineered into the soluble colicin E1 channel peptide: structural characterization of the insertion-competent state. Biochemistry 32:6974–6981. 56. Lakowicz JR. 1980. Fluorescence spectroscopic investigations of the dynamic properties of proteins, membranes, and nucleic acids. J Biochem Biophys Methods 2:90–119. 57. Subczynski WK, Hyde JS, Kusumi A. 1989. Oxygen permeability of phosphatidylcholine-cholesterol membranes. Proc Natl Acad Sci USA 86:4474–4478. 58. Fischkoff S, Vanderkooi JM. 1975. Oxygen diffusion in biological and artificial membranes determined by the fluorochrome pyrene. J Gen Physiol 65:663–676. 59. Dumas D, Muller S, Gouin F, Baros F, Viriot M-L, Stoltz J-F. 1997. Membrane fluidity and oxygen diffusion in cholesterol-enriched erythrocyte membrane. Arch Biochem Biophys 341(1):34–39. 60. Subczynski WK, Hyde JS, Kusumi A. 1991. Effect of alkyl chain unsaturation and cholesterol intercalation on oxygen transport in membranes: a pulse ESR spin labeling study. Biochemistry 30:8578– 8590. 61. Caputo GA, London E. 2003. Using a novel dual fluorescence quenching assay for measurement of tryptophan depth within lipid bilayers to determine hydrophobic "-helix locations within membranes. Biochemistry 42:3265–3274. 62. Lala AK, Koppaka V. 1992. Fluorenyl fatty acids as fluorescent probes for depth-dependent analysis of artificial and natural membranes. Biochemistry 31:5586–5593. 63. Sassaroli M, Ruonala M, Virtanen J, Vauhkonen M, Somerharju P. 1995. Transversal distribution of acyl-linked pyrene moieties in liq- uid-crystalline phosphatidylcholine bilayers. A fluorescence quenching study. Biochemistry 34:8843–8851. 64. Ladokhin A, Wang L, Steggles AW, Holloway PW. 1991. Fluorescence study of a mutant cytochrome b 5 with a single tryptophan in the membrane-binding domain. Biochemistry 30:10200– 10206. 65. Everett J, Zlotnick A, Tennyson J, Holloway PW. 1986. Fluorescence quenching of cytochrome b 5 in vesicles with an asymmetric transbilayer distribution of brominated phosphatidylcholine. J Biol Chem 261(15):6725–6729. 66. Gonzalez-Manas JM, Lakey JH, Pattus F. 1992. Brominated phospholipids as a tool for monitoring the membrane insertion of colicin A. Biochemistry 31:7294–7300. 67. Silvius JR. 1990. Calcium-induced lipid phase separations and interactions of phosphatidylcholine/anionic phospholipid vesicles: fluorescence studies using carbazole-labeled and brominated phospholipids. Biochemistry 29:2930–2938. 68. Silvius JR. 1992. Cholesterol modulation of lipid intermixing in phospholipid and glycosphingolipid mixtures: evaluation using fluorescent lipid probes and brominated lipid quenchers. Biochemistry 31:3398–3403. 69. Chattopadhyay A, London E. 1987. Parallax method for direct measurement of membrane penetration depth utilizing fluorescence quenching by spin-labeled phospholipids. Biochemistry 26:39–45. 70. Abrams FS, London E. 1992. Calibration of the parallax fluorescence quenching method for determination of membrane penetration depth: refinement and comparison of quenching by spin-labeled and brominated lipids. Biochemistry 31:5312–5322. 71. Abrams FS, Chattopadhyay A, London E. 1992. Determination of the location of fluorescent probes attached to fatty acids using parallax analysis of fluorescence quenching: effect of carboxyl ionization state and environment on depth. Biochemistry 31:5322–5327. 72. Abrams FS, London E. 1993. Extension of the parallax analysis of membrane penetration depth to the polar region of model membranes: use of fluorescence quenching by a spin-label attached to the phospholipid polar headgroup. Biochemistry 32:10826–10831. 73. Asuncion-Punzalan E, London E. 1995. Control of the depth of molecules within membranes by polar groups: determination of the location of anthracene-labeled probes in model membranes by parallax analysis of nitroxide-labeled phospholipid induced fluorescence quenching. Biochemistry 34:11460–11466. 74. Kachel K, Asuncion-Punzalan E, London E. 1995. Anchoring of tryptophan and tyrosine analogs at the hydrocarbon-polar boundary in model membrane vesicles: parallax analysis of fluorescence quenching induced by nitroxide-labeled phospholipids. Biochemistry 34:15475–15479. 75. Ren J, Lew S, Wang Z, London E. 1997. Transmembrane orientation of hydrophobic "-helices is regulated both by the relationship of helix length to bilayer thickness and by the cholesterol concentration. Biochemistry 36:10213–10220. 76. Ladokhin AS. 1999. Analysis of protein and peptide penetration into membranes by depth-dependent fluorescence quenching: theoretical considerations. Biophys J 76:946–955. 77. Ladokhin AS. 1999. Evaluation of lipid exposure of tryptophan residues in membrane peptides and proteins. Anal Biochem 276: 65–71.
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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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6 Solvent polarity and the local en
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238 DYNAMICS OF SOLVENT AND SPECTRA
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Page 351 and 352: 332 MECHANISMS AND DYNAMICS OF FLUO
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11 In the preceding chapter we desc
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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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15 In the previous two chapters on
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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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766 SINGLE-MOLECULE DETECTION small
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770 SINGLE-MOLECULE DETECTION Table
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786 SINGLE-MOLECULE DETECTION face
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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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914 ANSWERS TO PROBLEMS The α i va
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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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