Response of a lidar-induced fluorescence signal to yellow substance absorption [commun.]

• Autorzy: Drozdowska V. , Kowalczuk P.
• Języki publikacji: EN

Abstrakty

EN

The presence of yellow substances in seawaters was measured by the standard spectrophotometric ( in vitro) and the lidar-induced fluorescence ( in vivo) methods along a transect across the Pomeranian Bay towards the River Odra mouth, a local source of yellow substances. The experiment aimed to ascertain whether the fluorescent lidar method could be applied to yellow substance detection and whether there were any relationships and similarities in the absorption and fluorescence intensity values and their changes.

Słowa kluczowe

EN

yellow substance absorption; lidar; fluorescence; Baltic Sea

• Wydawca: Polish Academy of Sciences, Institute of Oceanology ; Elsevier
• Czasopismo: Oceanologia
• Rocznik: 1999
• Tom: No. 41 (4)
• Strony: 601--608
• Opis fizyczny: Bibliogr. 19 poz., wykr.

Twórcy

autor

Drozdowska V.

autor

Kowalczuk P.

• Institute of Oceanology, Polish Academy of Sciences, Powstańców Warszawy 55, 81–712 Sopot, Poland,

Bibliografia

• 1. Babichenko S., Poryvkina L., Varlamov V., 1995, On-line fluorescent techniques for diagnostics of water environment, SPIE Proc., 2503, 157-161.
• 2. Babichenko S., Poryvkina L., Arikese V., Kaitala S., Kuosa H., 1993, Remote sensing of phytoplankton using laser-induced fluorescence, Remote Sens. Environm., 45, 43-50
• 3. Bristow M., Nielsen D., Bundy D., Furtek R., 1981, Use of water Raman emission to correct airborne laser fluorosensor data for effects of water optical attenuation, Appl. Optics, 20 (17), 2889-2906.
• 4. Burlamacchi P., Cechi G., Mazzinghi P., Pantani L., 1983, Performance evaluation of UV sources for lidar fluorosensing of oil films, Appl. Optics, 22 (1), 48-53.
• 5. Exton R. J., Houghton W. M., Esaias W., Harriss R. C., Farmer F. H., White H. H., 1983, Laboratory analysis of techniques for remote sensing of estuarine parameters using laser excitation, Appl. Optics, 22 (1), 54-64.
• 6. Ferrari G., Tassan S., 1991, On the accuracy of determining light absorption by ‘yellow substance’ through measurements of induced fluorescence, Limnol. Oceanogr., 36 (4), 777-786.
• 7. Hoge F. E., Swift R. N., 1983, Airborne detection of oceanic turbidity cell structure using depth-resolved laser-induced water Raman backscatter, Appl. Optics, 22 (23), 3778-3786.
• 8. Hoge F. E., Swift R. N., 1980, Oil film thickness measurement using airborne laser-induced water Raman backscatter, Appl. Optics, 19 (19), 3269-3281.
• 9. Hoge F. E., Swift R. N., Yungel J. K., Vodacek A., 1993a, Fluorescence of dissolved organic matter: A comparison of North Pacific and North Atlantic Oceans during April 1993, J. Geophys. Res., 98 (C12), 22779-22787.
• 10. Hoge F. E., Vodacek A., Blough N. V., 1993b, Inherent optical properties of the ocean: Retrieval of the absorption coefficient of chromophoric dissolved organic matter from fluorescence measurements, 1993, Limnol. Oceanogr., 38 (7), 1394-1402.
• 11. Kowalczuk P., Kaczmarek S., 1996, Analysis of temporal and spatial variability of ‘yellow substance’ absorption in the Southern Baltic, Oceanologia, 38 (1), 3-32.
• 12. Król T., Piskozub J., Drozdowska V., 1994, Investigation of fluorescence of Surface water in the Baltic Sea by means of the lidar method, Proc. 19th Conf. Baltic Oceanogr., Inst. Oceanol. PAS, Sopot, 1, 166-171.
• 13. Otremba Z., Czyż B., Stelmaszewski A., 1993, The total fluorescence spectra of selected oils and their possible application to identify sources of pollution, Proc. Conf. ‘Technical and ecological aspects of the presence of crude-oil derivatives’, Uniw. Szczecin, Szczecin, 76-84, (in Polish).
• 14. Piskozub J., Otremba Z., Drozdowska V., Król T., Stelmaszewski A., 1996, Oil content in the Baltic Sea water and possibilities of detection and identification by the lidar method, 20th Baltic Mar. Conf., Rønne, 73-82.
• 15. Piskozub J., Drozdowska V., Irczuk M. 1998, A water Raman extinction lidar system for detecting thin oil spills: preliminary results of field tests, Oceanologia, 40 (1), 3-10.
• 16. Poryvkina l., Babichenko S., Lapimaa J., 1992, Spectral variability of humus substances in marine ecosystems, AMBIO, XXI (7), 465-467.
• 17. Reuter R., Albers W., Brandt K., Diebel-Langohr D., Doerffer R., Dörre F., Hengstermann T., 1986a, Ground truth techniques and procedures for Gelbstoff measurements, [in] The influence of yellow substances on remote sensing of seawater constituents from space, Rep. ESA Contract No. RFQ 3-5060/84/NL/MD, GKSS Res. Centre Geesthacht.
• 18. Reuter R., Diebel-Langohr D., Dörre F., Hengstermann T., 1986b, Airborne laser fluorosensor measurements of Gelbstoff, [in] The influence of yellow substances on remote sensing of sea water constituents from Space, Rep. ESA Contract No. RFQ 3-5060/84/NL/MD, GKSS Res. Centre Geesthacht.
• 19. Vodacek A., Hoge F. E., Swift R. N., Yungel J. K., Peltzer E. T., Blough N. V., 1995, The use of in situ airborne fluorescence measurements to determine UV absorption coefficients and DOC concentrations in surface waters, Limnol. Oceanogr., 40 (2), 411-415.