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ISSN: 1023-5086

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ISSN: 1023-5086

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Opticheskii Zhurnal

A full-text English translation of the journal is published by Optica Publishing Group under the title “Journal of Optical Technology”

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УДК: 535.37/535.31

Study of the angular fluorescence distribution of bioaerosol particles: modelling and experiment

Kochelaev E.A., Volchek A.O., Elizarov B.A., Sidorenko V.M.

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Publication in Journal of Optical Technology

For Russian citation (Opticheskii Zhurnal):

Кочелаев Е.А., Волчек А.О., Елизаров Б.А., Сидоренко В.М. Исследование индикатрисы флуоресценции частиц биоаэрозоля: моделирование и эксперимент // Оптический журнал. 2012. Т. 79. № 6. С. 10–19.

 

Kochelaev E.A., Sidorenko V.M., Volchek A. O., Elizarov B.A. Study of the angular fluorescence distribution of bioaerosol particles: modelling and experiment . [in Russian] // Opticheskii Zhurnal. 2012. V. 79. № 6. P. 10–19.

For citation (Journal of Optical Technology):

E. A. Kochelaev, V. M. Sidorenko, A. O. Volchek, and B. A. Elizarov, "Study of the angular fluorescence distribution of bioaerosol particles: modelling and experiment," Journal of Optical Technology. 79(6), 322-328 (2012).  https://doi.org/10.1364/JOT.79.000322

Abstract:

The results of numerical modelling of the angular fluorescence distribution of the individual particles of a bioaerosol are compared with experimental data obtained by a flowthrough-optical method when studying particles of the protein ovalbumin, as well as of Bacillus subtilis spores. It is shown that the experimental data agree on the whole with the results of the model computations.

Keywords:

bioaerosol, fluorescence indicatrix, spherical particle, flow-optical method

OCIS codes: 300.2530, 280.1415, 010.1110

References:

1. Y.-L. Pan, S. C. Hill, R. G. Pinnick, H. Huang, J. R. Bottiger, and R. K. Chang, “Fluorescence spectra of atmospheric aerosol particles measured using one or two excitation wavelengths: Comparison of classification schemes employing different emission and scattering result,” Opt. Express 18, 12436 (2010).
2. P. H. Kaye, J. E. Barton, E. Hirst, and J. M. Clark, “Simultaneous light scattering and intrinsic fluorescence measurement for the classification of airborne particles,” Appl. Opt. 39, 3738 (2000).
3. P. H. Kaye, W. R. Stanley, and E. Hirst, “Single-particle multichannel bio-aerosol fluorescence sensor,” Opt. Express 13, 3583 (2005).

4. T. H. Jeys, W. D. Herzog, J. D. Hybl, R. N. Czerwinski, and A. Sanchez, “Advanced trigger development,” Lincoln Lab. J. 17, No. 1, 29 (2007).
5. R. Domann, Y. Hardalupas, and A. R. Jones, “A study of the influence of absorption on the spatial distribution of fluorescence intensity within large droplets using Mie theory, geometrical optics and imaging experiments,” Meas. Sci. Technol. No. 13, 280 (2002).
6. S. C. Hill, V. Boutou, J. Yu, S. Ramstein, J.-P. Wolf, Y.-L. Pan, S. Holler, and R. K. Chang, “Enhanced, backward-directed multiphoton-excited fluorescence from dielectric microcavities,” Bull. Am. Phys. Soc. No. 1, 54 (2000).
7. Y.-L. Pan, S. C. Hill, J.-P. Wolf, S. Holler, R. K. Chang, and J. R. Bodiger, “Backward-enhanced fluorescence from clusters of microspheres and particles of tryptophan,” Appl. Opt. 41, 2994 (2002).
8. V. M. Sidorenko, Molecular Spectroscopy of Biological Media (Vysshaya Shkola, Moscow, 2004), pp. 105–115.
9. E. T. Arakawa, P. S. Tuminello, B. N. Khare, and M. E. Milham, “Optical properties of Erwinia herbicola bacteria at 0.19–2.5 μm,” Biopolymers 72, 391 (2003).
10. P. S. Tuminello, E. T. Arakawa, B. N. Khare, J. M. Wrobel, M. R. Querry, and M. E. Milham, “Optical properties of Bacillus subtilis spores from 0.2 to 2.5 μm,” Appl. Opt. 36, 2818 (1997).
11. E. T. Arakawa, P. S. Tuminello, B. N. Khare, and M. E. Milham, “Optical properties of ovalbumin in 0.130–2.50-μm spectral region,” Biopolymers 62, 122 (2001).
12. E. A. Kochelaev and A. O. Volchek, “Optical recording system for a flow-through optical method of analyzing bioaerosols,” Opt. Zh. 78, No. 6, 23 (2011). [J. Opt. Technol. 78, 365 (2011)].
13. E. A. Kochelaev, A. O. Volchek, and V. M. Sidorenko, “Method of calculating the angular fluorescence distribution of aerosol particles,” Izv. SPbG ´ETU L ´ETI No. 9, 110 (2011).
14. H. B. Steen, “Noise, sensitivity, and resolution of flow cytometers,” Cytometry 13, 822 (1992).
15. G. W. Faris, R. A. Copeland, K. Mortelmans, and B. V. Bronk, “Spectrally resolved absolute fluorescence cross sections for bacillus spores,” Appl. Opt. 36, 958 (1997).
16. V. Sivaprakasam, H.-B. Lin, A. L. Huston, and J. D. Eversole, “Spectral characterization of biological aerosol particles using two-wavelength excited laser-induced fluorescence and elastic scattering measurements,” Opt. Express 19, 6191 (2011).