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Oceanography
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A study on biological Co2 fixation in the sea on the earth
In this study, firstly, Epply's correlation between density and net primary productivity is corrected by the observational data of primary productivity by Ryther (1963) and Koblentz-Minishke et al (1970). Table 1 shows the corrected correlation in each sea region where the in situ observation data exist. Secondly, using the new correlation, the primary productivity in each mesh is yield, and after summing up the capacity of Co 2 fixation in the sea is yield.
Table 1 Correlation primary productivity (p: mgCm-2s-1) vs. chlorophyll density (Ck: mgm-3) in each sea area.
Result
Table 2 shows the capacity of COs fixation in each sea region where Epply's correlation inc corrected. From this table the total capacity of Co 2 fixation fro original correlated is three times the value of corrected correlation. The capacity of Co 2 fixation in the sea is 31.1 GtC/year.
Table 2 shows the result of comparison with the result from observational data.
Through the process above the primary productivity in the sea is calculated. Fig. 5 shows the distribution of the primary productivity in this study and Fig. 6 shows the result by Koblentz-Minshke et al. (1970)for comparison. These two result is similar except for the value in the North Atlantic Ocean. In this region the primary productivity is very high in this study. And the other problem in this study is the discontinuity of the primary productivity in each sea region.
Table 2 : PP : Primary Productivity (Gtc/year) from new correlation vs. Epply's original correlation.
Table 3 Comparison the capacity of Co2 fixation (Gtc/year) in this study with the observational data in the sea.
Conclusion
The following conclusions were obtained.
Using the chlorophyll density map by Nimbus7/CZCS, capacity of biological Co 2 fixation was estimated and it agreed with the studies before. Ti shows the potential availability of using satellite data for estimation of Co 2 fixation of changing global environment.
The father research will pay attention to checking the distribution locally and to removing the discontinuity of primary productivity.
References
- Box, E, 1975. Quantitative Evaluation of Global Primary Productivity Models Generated by Computers, Primary Productivity of the Biosphere (ed. Lieth, H and Whittaker, H.), Springer - Verlag New York Inc., pp265-283.0
- Epply, R.W. Stewart, E. Abbot.M.R. and Heyman, U., 1985. Estimating ocean primary production from satellite chlorophyll, introduction to regional differences and statistics for the Southern California
- Bight, Journal of Plankton Research, Vol. 7, no. 1 pp57-70.
- McClain, J. Erold, N. Mayanrad, D. Endres, R. Evans, J. Brown, S. Walsh, M. Carle and G. Podestra, 1989. Ocean color : Availability of the global data set.
- Gordon.H.R. and A.Y. Morel, 1983. Remote Assessment of Ocean color for Interpretation of satellite visible imagery, Springer - Verlag, New York.
- Koblentz-Minshike, O.J., V.V. Volkovinsky, and J.C. Kabanova, 1970. Plankton primary production of the world ocean in scientific exploration of the southern pacific, edited by W.S. Wooster, National Academy of Science, Washington D.C, pp 183-193.
- Rotty R.M. and Marland G., 1986. fossil fuel combustion : recent amounts, patterns and trends of Co2. In; the changing carbon cycle: A global analysis (eds Trabalka J & Reichele D). Springer Berlin Heidelberg, New York, pp 484-500.
- Ryther, J.H., 1963. The seas.11.(ed. Hill M.N), Interscience Publ., pp 347-380.
- Shintaro Goto, Shunji Murai, Yoshiati Honda and Kengo Asakura, 1992.A study on the relationships between human activities and biosphere using satellite data, proc. of XVII ISPRS Congress, Washington D.C (in printing)
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