Vol. 26, issue 10, article # 16

Fedotov Yu. V., Belov M. L., Titov A. L., Stepanov A. V. Investigation of the chlorophyll fluorescence spectra using Ti:Sapphire laser as an excitation source. // Optika Atmosfery i Okeana. 2013. V. 26. No. 10. P. 904-907 [in Russian].
Copy the reference to clipboard

Abstract:

Measurement results of the chlorophyll fluorescence spectra excited by tunable radiation of first and second harmonic of Ti:Sapphire laser are presented. The efficiency of fluorescence excitation is investigated depending on laser radiation wavelength.

Keywords:

Ti:Sapphire laser, vegetation, chlorophyll, fluorescence spectra

References:

1. Grishin A.I., Matvienko G.G., Harchenko O.V., Timofeev V.I. Issledovanie fluorescencii rastenij pri vozbuzhdenii izlucheniem vtoroj garmoniki YAG:Nd-lazera // Optika atmosf. i okeana. 1997. V. 10, N 7. P. 806–812.
2. Grishin A.I., Matvienko G.G., Harchenko O.V., Timofeev V.I., Klimkin V.M., Sokovikov V.G., Astafurova T.P., Zotikova A.P. Distancionnaja ocenka sostojanija fotosinteticheskogo apparata v rastenijah metodom inducirovannoj lazerom fluorescencii // Optika atmosf. i okeana. 1999. V. 12, N 4. P. 334–337.
3. Daughtry C.S.T., McMurtrey III J.M., Chappelle E.W., Hunter W.J., Steiner J.L. Measuring crop residue cover using remote sensing techniques // Theor. and Appl. Climatol. 1996. V. 54, N 1–2. P. 17–26.
4. Cerovic Z., Samson G., Iribas F.M. Ultraviolet-induced fluorescence for plant monitoring: present state and prospects // Agronomie. 1999. V. 19, N 7. P. 543–578.
5. Lichtenthaler H.K., Buschmann C., Rinderle U., Schmuck G. Application of chlorophyll fluorescence in ecophysiology // Radiat. and Environ. Biophys. 1986. V. 25, N 4. P. 297–308.
6. Edner H., Johansson J., Svanberg S., Wallinder E. Fluorescence lidar multicolor imaging of vegetation // Appl. Opt. 1994. V. 33, N 13. P. 2471–2479.
7. Ruth B. The initial phase of the chlorophyll fluorescence induction kinetics as an indicator for the degree of forest decline // Proc. SPIE. 1992. V. 1714. P. 61–72.
8. Schneckenburger H., Frenz M. Time-resolved fluorescence of conifers exposed to environmental pollutants // Radiat. and Environ. Biophys. 1986. V. 25, N 4. P. 289–295.
9. Zhao J., Lui H., McLean D.I., Zeng H. Toward instrument-independent quantitative measurement of fluorescence intensity in fiber-optic spectrometer systems // Appl. Opt. 2007. V. 46, N 29. P. 7132–7140.
10. Young I.T., Garini Y., Vermolen B., Liqui Lung G., Brouwer G., Hendrichs S., El Morabit M., Spoelstra J., Wilhelm E., Zaal M. Absolute Fluorescence Calibration // Proc. SPIE / Eds. D.L. Farkas, D.V. Nicolau, R.C. Leif. 2006. V. 6088. P. 60880U-1–60880U-9.
11. Eastman J. Standardization of fluorescence spectra and the calibration of spectrofluorimeters // Appl. Opt. 1966. V. 5, N 7. P. 1125–1132.
12. Melhuish W. A standard fluorescence spectrum for calibrating spectro-fluorophotometers // J. Phys. Chem. 1960. V. 3, N 1. P. 7–9.
13. Melhuish W. Calibration of spectrofluorimeters for measuring corrected emission spectra // J. Opt. Soc. Amer. 1962. V. 52, N 11. P. 1256–1258.