Principles of Fluorescence Spectroscopy

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524 ENERGY TRANSFER TO MULTIPLE ACCEPTORS IN ONE,TWO, OR THREE DIMENSIONS experience the same diffusion-limited rate of transfer. Photobleaching of the retinal decreases its effective concentration, and the Tb 3+ lifetime increases. The decay times found for Tb 3+ within the vesicles can be used to determine the transfer efficiency. Since the intensity decays are single exponentials, the efficiency can be calculated from (15.24) where τ DA and τ D are the Tb 3+ decay times in the presence and in the absence of energy transfer. The transfer efficiency is then compared with that predicted using eq. 15.23 to determine the retinal distance below the inner membrane surface. The distance of retinal from the inner membrane surface was estimated to be 22 Å. 15.7. CONCLUSIONS The phenomenon of Förster transfer is simultaneously simple and complex. While the theory describing the mechanism of dipolar transfer is complex, the result is dependable and robust. Förster distances can be predicted with good accuracy from the spectral properties of the donor and acceptor. There are no known exceptions to Förster transfer, so that RET can be reliably assumed to occur whenever the donors and acceptors are in close proximity. Hence, RET is a reliable method to study the proximity and geometric distributions of donor–acceptor pairs. The complexity of energy transfer arises from the occurrence of distance distributions, non-random distributions, and donor-to-acceptor diffusion. These phenomena result in complex theory, not because of Förster transfer, but because of the need to average the distance dependence over various geometrics and timescales. REFERENCES E 1 τ DA τ D 1. Förster Th. 1949. Experimentelle und theoretische Untersuchung des zwischenmolekularen Ubergangs von Elektronenanregungsenergie. Z Naturforsch A 4:321–327. 2. Förster Th. 1959. 10th Spiers memorial lecture, transfer mechanisms of electronic excitation. Discuss Faraday Soc 27:7–17. 3. Bojarski C, Sienicki K. 1990. Energy transfer and migration in fluorescent solutions. In Photochemistry and photophysics, Vol. I, pp. 1–57. Ed JF Rabek. CRC Press, Boca Raton, GL. 4. Galanin MD. 1955. The influence of concentration on luminescence in solutions. Sov Phys JETP 1:317–325. 5. Maksimov MA, Rozman IM. 1962. On the energy transfer in rigid solutions. Opt Spectrosc 12:337–338. 6. Elkana Y, Feitelson J, Katchalski E. 1968. Effect of diffusion on transfer of electronic excitation energy. J Chem Phys 48:2399–2404. 7. Steinberg IZ, Katchalski E. 1968. Theoretical analysis of the role of diffusion in chemical reactions, fluorescence quenching, and nonradiative energy transfer. J Chem Phys 48(6):2404–2410. 8. Kusba J. 1987. Long-range energy transfer in the case of material diffusion. J Luminesc 37:287–291. 9. Yokota M, Tanimato O. 1967. Effects of diffusion on energy transfer by resonance. J Phys Soc Jpn 22(3):779–784. 10. Gösele U, Hauser M, Klein UKA, Frey R. 1975. Diffusion and longrange energy transfer. Chem Phys Lett 34(3):519–522. 11. Faulkner LR. 1976. Effects of diffusion on resonance energy transfer: comparisons of theory and experiment. Chem Phys Lett 43(6): 552–556. 12. Millar DP, Robbins RJ, Zewail AH. 1981. Picosecond dynamics of electronic energy transfer in condensed phases. J Chem Phys 75(8): 3649–3659. 13. Lakowicz JR, Szmacinski H, Gryczynski I, Wiczk W, Johnson ML. 1990. Influence of diffusion on excitation energy transfer in solutions by gigahertz harmonic content frequency-domain fluorometry. J Phys Chem 94:8413–8416. 14. Birks JB, Georghiou S. 1968. Energy transfer in organic systems, VII: effect of diffusion on fluorescence decay. J Phys B 1:958–965. 15. Tweet AO, Bellamy WD, Gains GL. 1964. Fluorescence quenching and energy transfer in monomolecular films containing chlorophyll. J Chem Phys 41:2068–2077. 16. Koppel DE, Fleming PJ, Strittmatter P. 1979. Intramembrane positions of membrane-bound chromophores determined by excitation energy transfer. Biochemistry 24:5450–5457. 17. Szmacinski H. 1998. Personal communication. 18. Maliwal BP, Kusba J, Lakowicz JR. 1994. Fluorescence energy transfer in one dimension: frequency-domain fluorescence study of DNA–fluorophore complexes. Biopolymers 35:245–255. 19. Drake JM, Klafter J, Levitz P. 1991. Chemical and biological microstructures as probed by dynamic processes. Science 251:1574–1579. 20. Dewey TG. 1991. Excitation energy transport in fractal aggregates. Chem Phys 150:445–451. 21. Lianos P, Duportail G. 1993. Time-resolved fluorescence fractal analysis in lipid aggregates. Biophys Chem 48:293–299. 22. Loura LMM, Fedorov A, Prieto M. 1996. Resonance energy transfer in a model system of membranes: applications to gel and liquid crystalline phases. Biophys J 71:1823–1836. 23. Tamai N, Yamazaki T, Yamazaki I, Mizuma A, Mataga N. 1987. Excitation energy transfer between dye molecules adsorbed on a vesicle surface. J Phys Chem 91:3503–3508. 24. Levitz P, Drake JM, Klafter J. 1988. Critical evaluation of the application of direct energy transfer in probing the morphology of porous solids. J Chem Phys 89(8):5224–5236. 25. Drake JM, Levitz P, Sinha SK, Klafter J. 1988. Relaxation of excitations in porous silica gels. Chem Phys 128:199–207. 26. Dewey TG, Datta MM. 1989. Determination of the fractal dimension of membrane protein aggregates using fluorescence energy transfer. Biophys J 56:415–420.
PRINCIPLES OF FLUORESCENCE SPECTROSCOPY 525 27. Drake JM, Kafter J. 1990. Dynamics of confined molecular systems. Phys Today, May, pp. 46–55. 28. Pines D, Huppert D. 1987. Time-resolved fluorescence depolarization measurements in mesoporous silicas: the fractal approach. J Phys Chem 91(27):6569–6572. 29. Pines D, Huppert D, Avnir D. 1988. The fractal nature of the surfaces of porous silicas as revealed in electronic energy transfer between adsorbates: comparison of three donor/acceptor pairs. J Chem Phys 89:1177–1180. 30. Nakashima K, Duhamel J, Winnik MA. 1993. Photophysical processes on a latex surface: electronic energy transfer from rhodamine dyes to malachite green. J Phys Chem 97:10702–10707. 31. Schurr JM, Fujimoto BS, Wu P, Song L. 1992. Fluorescence studies of nucleic acids: dynamics, rigidities and structures. In Topics in fluorescence spectroscopy, Vol. 3: Biochemical applications, pp. 137– 229. Ed JR Lakowicz. Plenum Press, New York. 32. Mergny J-L, Slama-Schwok A, Montenay-Garestier T, Rougee M, Helene C. 1991. Fluorescence energy transfer between dimethyldiazaperopyrenium dication and ethidium intercalated in poly d(A- T). Photochem Photobiol 53(4):555–558. 33. Lee BW, Moon SJ, Youn MR, Kim JH, Jang HG, Kim SK. 2003. DNA mediated resonance energy transfer from 4',6-diamidino-2phenylindole to [Ru(1,10-phenanthroline) 2 L] 2+ . Biophys J 85:3865– 3871. 34. Murata S, Kusba J, Piszczek G, Gryczynski I, Lakowicz JR. 2000. Donor fluorescence decay analysis for energy transfer in double-helical DNA with various acceptor concentrations. Biopolymers 57: 306–315. 35. Kang JS, Lakowicz JR, Piszczek G. 2002. DNA dynamics: a fluorescence resonance energy transfer study using a long-lifetime metal–ligand complex. Arch Pharm Res 25(2):143–150. 36. Kim J, Lee M. 2004. Observation of multi-step conformation switching in $-amyloid peptide aggregation by fluorescence resonance energy transfer. Biochem Biophys Res Commun. 316:393–397. 37. Baneyx G, Baugh L, Vogel V. 2001. Coexisting conformations of fibronectin in cell culture imaged using fluorescence resonance energy transfer. Proc Natl Acad Sci USA 98(25):14454–14468. 38. Wolber PK, Hudson BS. 1979. An analytic solution to the Förster energy transfer problem in two dimensions. Biophys J 28:197–210. 39. Dewey TG, Hammes GG. 1986. Calculation of fluorescence resonance energy transfer on surfaces. Biophys J 32:1023–1036. 40. Hauser M, Klein UKA, Gosele U. 1976. Extension of Förster's theory for long-range energy transfer to donor–acceptor pairs in systems of molecular dimensions. Z Phys Chem 101:255–266. 41. Estep TN, Thompson TE. 1979. Energy transfer in lipid bilayers. Biophys J 26:195–208. 42. Dobretsov GE, Kurek NK, Machov VN, Syrejshchikova TI, Yakimenko MN. 1989. Determination of fluorescent probes localization in membranes by nonradiative energy transfer. J Biochem Biophys Methods 19:259–274. 43. Blumen A, Klafter J, Zumofen G. 1986. Influence of restricted geometries on the direct energy transfer. J Chem Phys 84(3):1307–1401. 44. Kellerer H, Blumen A. 1984. Anisotropic excitation transfer to acceptors randomly distributed on surfaces. Biophys J 46:1–8. 45. Yguerabide Y. 1994. Theory of establishing proximity relationships in biological membranes by excitation energy transfer measurements. Biophys J 66:683–693. 46. Bastiaens P, de Beun A, Lackea M, Somerharja P, Vauhkomer M, Eisinger J. 1990. Resonance energy transfer from a cylindrical distribution of donors to a plan of acceptors: location of apo-B100 protein on the human low-density lipoprotein particle. Biophys J 58:665– 675. 47. Baumann J, Fayer MD. 1986. Excitation transfer in disordered twodimensional and anisotropic three-dimensional systems: effects of spatial geometry on time-resolved observables. J Chem Phys 85: 4087–4107. 48. Zimet DB, Thevenin BJ-M, Verkman AS, Shohet SB, Abney JR. 1995. Calculation of resonance energy transfer in crowded biological membranes. Biophys J 68:1592–1603. 49. Snyder B, Frieri E. 1982. Fluorescence energy transfer in two dimensions. Biophys J 40:137–148. 50. Fung B, Stryer L. 1978. Surface density measurements in membranes by fluorescence resonance energy transfer. Biochemistry 17: 5241–5248. 51. Pedersen S, Jorgensen K, Baekmark TR, Mouritsen OG. 1996. Indirect evidence for lipid-domain formation in the transition region of phospholipid bilayers by two-probe fluorescence energy transfer. Biophys J 71:554–560. 52. Wolf DE, Winiski AP, Ting AE, Bocian KM, Pagano RE. 1992. Determination of the transbilayer distribution of fluorescent lipid analogues by nonradiative fluorescence resonance energy transfer. Biochemistry 31:2865–2873. 53. Shaklai N, Yguerabide J, Ranney HM. 1977. Interaction of hemoglobin with red blood cell membranes as shown by a fluorescent chromophore. Biochemistry 16(25):5585–5592. 54. Chigaev Z, Buranda T, Dwyer DC, Prossnitz ER, Sklar LA. 2003. FRET detection of cellular " 4 -integrin conformational activation. Biophys J 85:3951–3962. 55. Kusba J, Piszczek G, Gryczynski I, Johnson ML, Lakowicz JR. 2000. Effects of diffusion on energy transfer in solution using a microsecond decay time rhenium metal–ligand complex as the donor. Chem Phys Letts 319:661–668. 56. Kusba J, Li L, Gryczynski I, Piszczek G, Johnson ML, Lakowicz JR. 2002. Lateral diffusion coefficients in membranes measured by resonance energy transfer and a new algorithm for diffusion in two dimensions. Biophys J 82:1358–1372. 57. 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. 58. Thomas DD, Carlsen WF, Stryer L. 1978. Fluorescence energy transfer in the rapid diffusion limit. Proc Natl Acad Sci USA 75:5746–5750. 59. Stryer L, Thomas DD, Meares CF. 1982. Diffusion-enhanced fluorescence energy transfer. Annu Rev Biophys Bioeng 11:203–222. 60. Thomas DD, Stryer L. 1982. Transverse location of the retinal chromophore of rhodopsin in rod outer segment disc membranes. J Mol Biol 154:145–157. 61. Yeh SM, Meares CF. 1980. Characterization of transferrin metalbinding sites by diffusion-enhanced energy transfer. Biochemistry 19:5057–5062.
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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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280 QUENCHING OF FLUORESCENCE Figur
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282 QUENCHING OF FLUORESCENCE ly ev
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290 QUENCHING OF FLUORESCENCE relat
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298 QUENCHING OF FLUORESCENCE σ ar
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320 QUENCHING OF FLUORESCENCE 47. R
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322 QUENCHING OF FLUORESCENCE 113.
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328 QUENCHING OF FLUORESCENCE P8.3.
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330 QUENCHING OF FLUORESCENCE P8.11
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332 MECHANISMS AND DYNAMICS OF FLUO
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10 Measurements of fluorescence ani
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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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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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24 In the previous chapter we descr
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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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