Comparisons of δ13C of photosynthetic products and ecosystem respiratory CO2 and their responses to seasonal climate variability

This study investigated the relationship between δ¹³C of ecosystem components, soluble plant carbohydrates and the isotopic signature of ecosystem respired CO₂ (δ¹³CR) during seasonal changes in soil and atmospheric moisture in a beech (Fagus sylvatica L.) forest in the central Apennine mountains, I...

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Bibliographic Details
Published in:Oecologia 2004-07, Vol.140 (2), p.340-351
Main Authors: Scartazza, Andrea, Mata, Catarina, Matteucci, Giorgio, Yakir, Dan, Moscatello, Stefano, Brugnoli, Enrico
Format: Article
Language:English
Subjects:
air
Animal and plant ecology
Animal, plant and microbial ecology
bark
Biological and medical sciences
biosphere
carbohydrate composition
carbon
carbon cycle
carbon dioxide
carbon sinks
climate
ecosystem respiration
ecosystems
Fagus sylvatica
forests
Fundamental and applied biological sciences. Psychology
leaves
lipids
mountains
phloem
sap
seasonal variation
soil water
stable isotopes
sugars
summer
Synecology
Terrestrial ecosystems
vapor pressure
wood
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Summary:This study investigated the relationship between δ¹³C of ecosystem components, soluble plant carbohydrates and the isotopic signature of ecosystem respired CO₂ (δ¹³CR) during seasonal changes in soil and atmospheric moisture in a beech (Fagus sylvatica L.) forest in the central Apennine mountains, Italy. Decrease in soil moisture and increase in air vapour pressure deficit during summer correlated with substantial increase in δ¹³C of leaf and phloem sap soluble sugars. Increases in δ¹³C of ecosystem respired CO₂ were linearly related to increases in phloem sugar δ¹³C (r ²=0.99, P≤0.001) and leaf sugar δ¹³C (r ²=0.981, P≤0.01), indicating that a major proportion of ecosystem respired CO₂ was derived from recent assimilates. The slopes of the best-fit lines differed significantly (P≤0.05), however, and were about 0.86 (SE=0.04) for phloem sugars and about 1.63 (SE=0.16) for leaf sugars. Hence, changes in isotopic signature in phloem sugars were transferred to ecosystem respiration in the beech forest, while leaf sugars, with relatively small seasonal changes in δ¹³C, must have a slower turnover rate or a significant storage component. No significant variation in δ¹³C was observed in bulk dry matter of various plant and ecosystem components (including leaves, bark, wood, litter and soil organics). The apparent coupling between the δ¹³C of soluble sugars and ecosystem respiration was associated with large apparent isotopic disequilibria. Values of δ¹³CR were consistently more depleted by about 4‰ relative to phloem sugars, and by about 2‰ compared to leaf sugars. Since no combination of the measured pools could produce the observed δ¹³CR signal over the entire season, a significant isotopic discrimination against ¹³C might be associated with short-term ecosystem respiration. However, these differences might also be explained by substantial contributions of other not measured carbon pools (e.g., lipids) to ecosystem respiration or contributions linked to differences in footprint area between Keeling plots and carbohydrate sampling. Linking the seasonal and inter-annual variations in carbon isotope composition of carbohydrates and respiratory CO₂ should be applicable in carbon cycle models and help the understanding of inter-annual variation in biospheric sink strength.
ISSN:0029-8549
1432-1939
DOI:10.1007/s00442-004-1588-1