Leaf economics spectrum prevails over nutrient resorption in regulating the temperature sensitivity of litter decomposition in a subtropical forest ecosystem

Leaf economics spectrum prevails over nutrient resorption in regulating the temperature sensitivity of litter decomposition in a subtropical forest ecosystem

The LES and nutrient resorption are thought to jointly modulate leaf litter traits, including the litter decomposition, but it is unknown how the two factors affect the temperature sensitivity of litter decomposition (Q 10 ). The Q 10 of litter decomposition was evaluated for 15 co-occurring subtrop...

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Bibliographic Details
Published in:Biology and fertility of soils Vol. 59; no. 8; pp. 901 - 910
Main Authors: Li, Renshan, Wang, Yu, Yuan, Congying, Zhang, Weidong, Wang, Qingkui, Guan, Xin, Chen, Longchi, Wang, Silong, Han, Jianming, Yang, Qingpeng
Format: Journal Article
Language:English
Published: Berlin/Heidelberg Springer Berlin Heidelberg 01-11-2023
Springer Nature B.V
Subjects:
Agriculture
Biomedical and Life Sciences
Correlation
Decomposition
Forest ecosystems
Leaf area
Leaf litter
Leaves
Life Sciences
Lignin
Nutrient resorption
Nutrients
Original Paper
Senescence
Soil Science & Conservation
Species
Terrestrial ecosystems
Tropical forests
Litter respiration
Global warming
Vegetation strategy
CO
efflux
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Summary:The LES and nutrient resorption are thought to jointly modulate leaf litter traits, including the litter decomposition, but it is unknown how the two factors affect the temperature sensitivity of litter decomposition (Q 10 ). The Q 10 of litter decomposition was evaluated for 15 co-occurring subtropical woody species under laboratory conditions. The LES of these species, as well as species-specific N (NRE) and P resorption efficiency (PRE) during leaf senescence, were also determined. Results showed that the Q 10 values were significantly correlated to LES, with litters from resource-conservative species having higher Q 10 values than those from resource-acquisitive species. Among the parameters characterizing LES, leaf N concentration, C:N ratio, and lignin:N ratio were correlated to Q 10 , whereas leaf P and lignin concentrations, specific leaf area, and C:P ratio showed no relationships. The LES was correlated to litter C:N and lignin:N ratios, and, in turn, litter C:N and lignin:N ratios were correlated to Q 10 . This result suggested that LES affects litter quality and thus the Q 10 of litter decomposition. However, NRE and PRE were not correlated to Q 10 . In addition, the LES effects on litter quality and the Q 10 of decomposition did not depend on nutrient resorption, as indicated by the lack of correlation between LES and NRE or PRE. Our results reveal an association between plant functional features and forest C dynamics in a warmer future.
ISSN:0178-2762
1432-0789
DOI:10.1007/s00374-023-01758-w