Principles of Fluorescence Spectroscopy

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738 DNA TECHNOLOGY 95. Okamoto A, Kanatani K, Saito I. 2004. Pyrene-labeled base-discriminating fluorescent DNA probes for homogeneous SNP typing. J Am Chem Soc 126:4820–4827. 96. Ebata K, Masuko M, Ohtani H, Kashiwasake-Jibu M. 1995. Nucleic acid hybridization accompanied with excimer formation from two pyrene-labeled probes. Photochem Photobiol 62(5):836–839. 97. Yan Y, Myrick ML. 2001. Quantitative measurement and discrimination of isochromatic fluorophores based on micelle-enhanced steadystate fluorescence polarization in fluid solution. Anal Chim Acta 441: 87–93. 98. Yan Y, Myrick ML. 2001. Identification of nucleotides with identical fluorescent labels based on fluorescence polarization in surfactant solutions. Anal Chem 73:4508–4513. 99. Devlin R, Studholme RM, Dandliker WB, Fahy E, Blumeyer K, Ghosh SS. 1993. Homogeneous detection of nucleic acids by transient state polarized fluorescence. Clin Chem 39(9):1939–1943. 100. Murakami A, Nakaura M, Nakatsuji Y, Nagahara S, Tran-Cong Q, Makino K. 1991. Fluorescent-labeled oligonucleotide probes: detection of hybrid formation in solution by fluorescence polarization spectroscopy. Nucleic Acids Res 19(15):4097–4102. 101. Kumke MU, Shu L, McGown LB, Walker GT, Pitner JB, Linn CP. 1997. Temperature and quenching studies of fluorescence polarization detection of DNA hybridization. Anal Chem 69:500–506. 102. Walker NJ. 2002. A technique whose time has come. Science 296: 557–559. 103. Livak KJ, Flood SJA, Marmaro J, Giusti W, Deetz K. 1995. Oligonucleotides with fluorescent dyes at opposite ends provide a quenched probe system useful for detecting PCR product and nucleic acid hybridization. PCR Methods Appl 4:357–362. 104. Gibson UEM, Heid CA, Williams PM. 1996. A novel method for real time quantitative RT-PCR. Genome Res 6:995–1001. 105. Wittwer CT, Herrmann MG, Moss AA, Rasmussen RP. 1997. Continuous fluorescence monitoring of rapid cycle DNA amplification. BioTechniques 22(1):130–138. 106. Tyagi S, Kramer FR. 1996. Molecular beacons: probes that fluoresce upon hybridization. Nature Biotechnol 14:303–308. 107. Tyagi S, Bratu DP, Kramer FR. 1998. Multicolor molecular beacons for allele discrimination. Nature Biotechnol 16:49–53. 108. Marras SAE, Kramer FR, Tyagi S. 2002. Efficiencies of fluorescence resonance energy transfer and contact-mediated quenching in oligonucleotide probes. Nucleic Acids Res 30(21):e122. 1–8. 109. Yamane A. 2002. MagiProbe: a novel fluorescence quenching-based oligonucleotide probe carrying a fluorophore and an intercalator. Nucleic Acids Res 30(19):e97. 1–8. 110. Hwang GT, Seo YJ, Kim BH. 2004. A highly discriminating quencher-free molecular beacon for probing DNA. J Am Chem Soc 126:6528–6529. 111. Tyagi S, Marras SAE, Kramer FR. 2000. Wavelength-shifting molecular beacons. Nature Biotechnol 18:1191–1196. 112. Zhang P, Beck T, Tan W. 2001. Design of a molecular beacon DNA probe with two fluorophores. Angew Chem, Int Ed 40(2):402–405. 113. Ueberfeld J, Walt DR. 2004. Reversible ratiometric probe for quantitative DNA measurements. Anal Chem 76:947–952. 114. Root DD, Vaccaro C, Zhang Z, Castro M. 2004. Detection of single nucleotide variations by a hybridization proximity assay based on molecular beacons and luminescence resonance energy transfer. Biopolymers 75:60–70. 115. Ohya Y, Yabuki K, Hashimoto M, Nakajima A, Ouchi T. 2003. Multistep fluorescence resonance energy transfer in sequential chromophore array constructed on oligo-DNA assemblies. Bioconjugate Chem 14(6):1057–1066. 116. Tsourkas A, Behlke MA, Xu Y, Bao G. 2003. Spectroscopic features of dual fluorescence/luminescence resonance energy-transfer molecular beacons. Anal Chem 75:3697–3703. 117. Aslan K, Perez-Luna VH. 2004. Quenched emission of fluorescence by ligand functionalized gold nanoparticles. J Fluoresc 14(4):401– 405. 118. Rant U, Arinaga K, Fujita S, Yokoyama N, Abstreiter G, Tornow M. 2004. Structural properties of olignucleotide monolayers on gold surfaces probed by fluorescence investigations. Langmuir 20(23): 10086–10092. 119. Li H, Rothberg LJ. 2004. DNA sequence detection using selective fluorescence quenching of tagged oligonucleotide probes by gold nanoparticles. Anal Chem 76(18):5414–5417. 120. Dubertret B, Calame M, Libchaber AJ. 2001. Single-mismatch detection using gold-quenched fluorescent oligonucleotides. Nature Biotechnol 19:365–370. 121. Du H, Disney MD, Miller BL, Krauss TD. 2003. Hybridizationbased unquenching of DNA hairpins on Au surfaces: prototypical "molecular beacon" biosensors. J Am Chem Soc 125:4012–4013. 122. Sokol DL, Zhang X, Lu P, Gewirtz AM. 1998. Real time detection of DNA-RNA hybridization in living cells. Proc Natl Acad Sci USA 95:11538–11543. 123. Fang X, Mi Y, Li JJ, Beck T, Schuster S, Tan W. 2002. Molecular beacons: fluorogenic probes for living cell study. Cell Biochem Biophys 37:71–81. 124. Perlette J, Tan W. 2001. Real-time monitoring of intracellular mRNA hybridization inside single living cells. Anal Chem 73:5544–5550. 125. Stojanovic MN, de Prada P, Landry DW. 2000. Fluorescent sensors based on aptamer self-assembly. J Am Chem Soc 122:11547–11548. 126. Stojanovic MN, de Prada P, Landry DW. 2001. Aptamer-based folding fluorescent sensor for cocaine. J Am Chem Soc 123:4928–4931. 127. Hermann T, Patel DJ. 2000. Adaptive recognition by nucleic acid aptamers. Science 287:820–825. 128. Hoppe-Seyler F, Butz K. 2000. Peptide aptamers: powerful new tools for molecular medicine. J Molec Med 78:466–470. 129. Jayasena SD. 1999. Aptamers: an emerging class of molecules that rival antibodies as diagnostics. Clin Chem 45(9):1628–1650. 130. Fang X, Sen A, Vicens M, Tan W. 2003. Synthetic DNA aptamers to detect protein molecular variants in a high-throughput fluorescence quenching assay. ChemBioChem 4:829–834. 131. Brody EN, Gold L. 2000. Aptamers as therapeutic and diagnostic agents. Rev Mol Biotechnol 74:5–13. 132. Koizumi M, Breaker RR. 2000. Molecular recognition of cAMP by an DNA aptamer. Biochemistry 39:8983–8992. 133. Jhaveri SD, Kirby R, Conrad R, Maglott EJ, Bowser M, Kennedy RT, Glick G, Ellington AD. 2000. Designed signaling aptamers that transducer molecular recognition to changes in fluorescence intensity. J Am Chem Soc 122:2469–2473.
PRINCIPLES OF FLUORESCENCE SPECTROSCOPY 739 134. Stojanovic MN, Green EG, Semova S, Nikic DB, Landry DW. 2003. Cross-reactive arrays based on three-way functions. J Am Chem Soc 125:6085–6089. 135. Yang Q, Goldstein IJ, Mei H-Y, Engelke DR. 1998. DNA ligands that bind tightly and selectively to cellobiose. Proc Natl Acad Sci USA 95:5462–5467. 136. Pavski V, Le XC. 2001. Detection of human immunodeficiency virus type 1 reverse transcriptase using aptamers as probes in affinity capillary electrophoresis. Anal Chem 73:6070–6076. 137. Yamamoto R, Kumar PKR. 2000. Molecular beacon aptamer fluoresces in the presence of Tat protein of HIV-1. Genes Cells 5: 389–396. 138. Fang X, Cao Z, Beck T, Tan W. 2001. Molecular aptamer for realtime oncoprotein platelet-derived growth factor monitoring by fluorescence anisotropy. Anal Chem 73:5752–5757. 139. Sen D, Geyer CR. 1998. DNA enzymes. Curr Opin Chem Biol 2:680–687. 140. Breaker RR. 1997. DNA enzymes. Nature Biotechnol 15:427–431. 141. Liu J, Lu Y. 2003. Improving fluorescent DNAzyme biosensors by combining inter- and intramolecular quenchers. Anal Chem 75:6666–6672. 142. Lu Y, Liu J, Li J, Bruesehoff PJ, Pavot CM-B, Brown AK. 2003. New highly sensitive and selective catalytic DNA biosensors for metal ions. Biosens Bioelectron 18:529–540. 143. Nolan JP, Sklar LA. 2002. Suspension array technology: evolution of the flat-array paradigm. Trends Biotechnol 20(1):9–12. 144. Braeckmans K, De Smedt SC, Leblans M, Pauwels R, Demeester J. 2002. Encoding microcarriers: present and future technologies. Nature Rev 1:447–456. 145. Ferguson JA, Steemers FJ, Walt DR. 2000. High-density fiber-optic DNA random microsphere array. Anal Chem 72:5618–5624. 146. Battersby BJ, Bryant D, Meutermans W, Matthews D, Smythe ML, Trau M. 2000. Toward larger chemical libraries: encoding with fluorescent colloids in combinatorial chemistry. J Am Chem Soc 122:2138–2139. 147. Steemers FJ, Furguson JA, Walt DR. 2000. Screening unlabeled DNA targets with randomly ordered fiber-optic gene arrays. Nature Biotechnol 18:91–94. 148. Han M, Gao X, Su JZ, Nie S. 2001. Quantum-dot-tagged microbeads for multiplexed optical coding of biomolecules. Nature Biotechnol 19:631–635. 149. Levsky JM, Singer RH. 2003. Fluorescence in situ hybridization: past, present, and future. J Cell Sci 116:2833–2838. 150. Difilippantonio MJ, Reid T. 2003. Technicolor genome analysis. In Topics in fluorescence spectroscopy, Vol. 7: DNA technology, pp. 291–316. Ed JR Lakowicz. Kluwer Academic/Plenum Publishers, New York. 151. Lichter P, Boyle AL, Cremer T, Ward DC. 1991. Analysis of genes and chromosomes by nonisotropic in situ hybridization. Genet Anal Technol Appl 8(1):24–35. 152. Polak JM, McGee JOD. 1990. In situ hybridization, principles and practice. Oxford University Press, New York. 153. Denijn M, Schuurman H-J, Jacobse KC, De Weger RA. 1992. In situ hybridization: a valuable tool in diagnostic pathology. APMIS 100:669–681. 154. Fuller CE, Perry A. 2002. Fluorescence in situ hybridization (FISH) in diagnostic and investigative neuropathology. Brain Pathol 12:67– 86. 155. Levsky JM, Shenoy SM, Pezo RC, Singer RH. 2002. Single-cell gene expression profiling. Science 297(5582):836–840. 156. Voskova-Goldman A, Peier A, Caskey CT, Richards CS, Shaffner LG. 1997. DMD-specific FISH probes are diagnostically useful in the detection of female carriers of DMD gene deletions. Neurology 48:1633–1638. 157. Siadat-Pajouh M, Periasamy A, Ayscue AH, Moscicki AB, Palefsky JM, Walton L, DeMars LR, Power JD, Herman B, Lockett SJ. 1994. Detection of human papillomavirus type 16/18 DNA in cervicovaginal cells by fluorescence based in situ hybridization and automated image cytometry. Cytometry 15:245–257. 158. Pandya PP, Cardy DLN, Jauniaux E, Campbell S, Nicolaides KH. 1994. Rapid determination of fetal sex in coelomic and amniotic fluid by fluorescence in situ hybridization. Fetal Diagn Ther 10:66–70. 159. Saracoglu K, Brown J, Kearney L, Uhrig S, Azofeifa J, Fauth C, Speicher MR, Eils R. 2001. New concepts to improve resolution and sensitivity of molecular cytogenetic diagnostics by multicolor fluorescence in situ hybridization. Cytometry 44:7–15. 160. Wiegant J, Bezrookove V, Rosenberg C, Tanke HJ, Raap AK, Zhang H, Bittner M, Trent JM, Meltzer P. 2000. Differentially painting human chromosome arms with combined binary ratio-labeling fluorescence in situ hybridization. Genome Res 10:861–865. 161. Jentsch I, Geigl J, Klein CA, Speicher MR. 2003. Seven-fluorochrome mouse M-FISH for high-resolution analysis of interchromosomal rearrangements. Cytogenetic Genome Res 103:84–88. 162. Bayani J, Squire JA. 2001. Advances in the detection of chromosomal aberrations using spectral karyotyping. Clin Genet 59:65–73. 163. Macville M, Veldman T, Padilla-Nash H, Wangsa D, O'Brien P, Schrock E, Ried T. 1997. Spectral karyotyping, a 24-colour FISH technique for the identification of chromosomal rearrangements. Histochem Cell Biol 108:299–305. 164. Buwe A, Steinlein C, Koehler MR, Bar-Am. I, Katzin N, Schmid M. 2003. Multicolor spectral karyotyping of rat chromosomes. Cytogenetic Genome Res 103:163–168. 165. Schrock E, du Manoir S, Veldman T, Schoell B, Wienberg J, Ferguson-Smith MA, Ning Y, Ledbetter DH, Bar-Am I, Soenksen D, Garini Y, Ried T. 1996. Multicolor spectral karyotyping of human chromosomes. Science 273(5274):494–497. 166. Le Beau MM. 1996. One FISH, two FISH, red FISH, blue FISH. Nature Genet 12:341–344. 167. Speicher MR, Ward DC. 1996. The coloring of cytogenetics. Nature Med 2(9):1046–1048. 168. Bentz M, Döhner H, Cabot G, Lichter P. 1994. Fluorescence in situ hybridization in leukemias: the FISH are spawning. Leukemia 8(9):1447–1452. 169. Fox JL, Hsu P-H, Legator MS, Morrison LE, Seelig SA. 1995. Fluorescence in situ hybridization: Powerful molecular tool for cancer prognosis. Clin Chem 41(11):1554–1559. 170. Popescu NC, Zimonjic DB. 1997. Molecular cytogenetic characterization of cancer cell alterations. Cancer Genet Cytogenet 93:10–21. 171. Swiger RR, Tucker JD. 1996. Fluorescence in situ hybridization. Environ Mol Mutagen 27:245–254.
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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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5 In the preceding chapter we descr
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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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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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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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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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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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