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Jean Ometto, Luiz Martinelli, F Yoko Ishida & Edmar Mazzi Cena – University of São Paulo, Brasil

Seasonal dynamics of soil, litter, and ecosystem respiratory carbon dioxide fluxes as indicated by stable isotope analyses. Jean Ometto, Luiz Martinelli, F Yoko Ishida & Edmar Mazzi Cena – University of São Paulo, Brasil Jim Ehleringer, Tomas Domingues Univeristy of Utah, USA

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Jean Ometto, Luiz Martinelli, F Yoko Ishida & Edmar Mazzi Cena – University of São Paulo, Brasil

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  1. Seasonal dynamics of soil, litter, and ecosystem respiratory carbon dioxide fluxes as indicated by stable isotope analyses Jean Ometto, Luiz Martinelli, F Yoko Ishida & Edmar Mazzi Cena – University of São Paulo, Brasil Jim Ehleringer, Tomas Domingues Univeristy of Utah, USA H Jackson Silva, Sebastião Lopes UFPA – Santarém, Brasil Joe Berry Carnegie Institution, USA

  2. (Ometto et al, submitted)

  3. Focus of heat in 1998 in the BR Amazon source: IBAMA-PROARCO

  4. ca ci

  5. Measurements • δ13C and δ18O of CO2 – Keeling plots • Ecosystem • Soil – surface / profile • Decaying wood; leaves • Troposphere • River DIC • δ18O • leaf water, • soil/stem water, • water vapor • δ13C and δ15N • Leaves – spp (legumes / non-legumes) • Wood / bark • Litter • SOM

  6. Leaves sampling for δ13CCHO

  7. Air Sampling δ13CCO2

  8. Results • Carbon isotopic variation within the canopy • Seasonal isotopic variation of fixed organic carbon • Isotopic variation on the ecosystem respired 13CO2 associated to logging activities • Isotopic variation of soil respired CO2 – Importance of the litter for the 13C signal

  9. d13C = - 26.9 42.0m ci/ca= 0.53 d13C = - 31.1 ci/ca= 0.69 22.0m ci/ca= 0.77 d13C = - 33.5 5.0m ci/ca= 0.71 d13C = - 34.7 0.5m

  10. Flona - Santarém • = δ13CO2 canopy – δ13Cleaf

  11. Results • Carbon isotopic variation within the canopy • Seasonal isotopic variation of fixed organic carbon • Isotopic variation on the ecosystem respired 13CO2 associated to logging activities • Isotopic variation of soil respired CO2 – Importance of the litter for the 13C signal

  12. Seca Floresta Dry Plot Control Plot Dry season Wet season Dry season Wet season

  13. Seasonal variation of the upper canopy leaves d13C at k83 logged forest

  14. Results • Carbon isotopic variation within the canopy • Seasonal isotopic variation of fixed organic carbon • Isotopic variation on the ecosystem respired 13CO2 associated to logging activities • Isotopic variation of soil respired CO2 – Importance of the litter for the 13C signal

  15. Liana cutting Logging

  16. Liana cutting Logging

  17. M.Goulden, S.Miller Logging Wet season begins Years converge δ13CR-CO2 -25.9 after logging -24.7 -30.5 Before logging • Before logging the two years were generally similar. • From Sept to April the logged forest lost about 2 TC more than during the previous year, presumably because of decomposition of slash and reduced leaf area • After May the years were similar, presumably because fast growing plants are now filling the gaps.

  18. δ13CR-CO2 Cumulative NEE BLUE: PRE-LOGGING GREEN: POST-LOGGING -30.5 2001/2002 -24.7 2000/2001

  19. What the isotopes are showing us: • 1-The heavier signal prior to the logging • Can be related to a practice that consist on cutting lianas 6 to 8 months before the logging starts. • Lianas are important on the system water cycle • Lianas are isotopically heavy and the slash decomposing could contribute to a heavier respired CO2.

  20. 2 - Strong heavy signal in the dry season after logging The daily cycles of Net Ecosystem Exchange (NEE) during the 2001 dry season after the harvest showed less afternoon uptake and less nighttime efflux (respiration) than during the 2000 pre-harvest dry season. The reduction is of order 15%, consistent with the fraction of gaps left by the logging Heavy 13C signal • Reducing in photosynthetic rates – lower ci/ca • Strong increment of slash to the system – decomposition

  21. d13C of the respired CO2 and the ci:ca ratio of the upper canopy trees

  22. Isotopic composition of the respired CO2 and the ci:ca ratio calculated from the d13C of the organic matter on the top of the canopy

  23. Results • Carbon isotopic variation within the canopy • Seasonal isotopic variation of fixed organic carbon • Isotopic variation on the ecosystem respired 13CO2 associated to logging activities • Isotopic variation of soil respired CO2 – Importance of the litter for the 13C signal

  24. d13C of the respired CO2 – keeling plot intercept 2003

  25. d13C Litter fall isotopic composition variation at km 67 in 2003

  26. d13C

  27. Final remarks • Different compartments of the ecosystem present consistent isotopic data allowing predictions with certain degree of confidence; • The isotopic signature of the ecosystem respired CO2 reflects the seasonality of the precipitation and is consistent with the ci/ca ratio calculated from the d13C of the upper canopy leaves; • The litter fall reflects mainly the isotopic signature of the upper third canopy leaves and therefore a seasonality associated to ppt; • As widely known litter is an important component for soil CO2 efflux and the isotopic difference to the bulk soil respiration allow us to partitioning the importance of each of this compartments;

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