Can we use isotopes to capture the speed of link between photosynthesis and soil respiration?
Publikation: Beiträge in Sammelwerken › Abstracts in Konferenzbänden › Forschung › begutachtet
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Can we use isotopes to capture the speed of link between photosynthesis and soil respiration? / Kayler, Zachary; Keitel, Claudia; Jansen, Kirstin et al.
Geophysical Research Abstracts. Band 13 European Geosciences Union (EGU), 2011. S. 5357 (Geophysical Research Abstracts; Nr. 13).Publikation: Beiträge in Sammelwerken › Abstracts in Konferenzbänden › Forschung › begutachtet
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TY - CHAP
T1 - Can we use isotopes to capture the speed of link between photosynthesis and soil respiration?
AU - Kayler, Zachary
AU - Keitel, Claudia
AU - Jansen, Kirstin
AU - Gessler, Arthur
N1 - Conference code: 8
PY - 2011
Y1 - 2011
N2 - Currently there are two proposed mechanisms to link assimilation to belowground respiration via the phloem:1) the transport of assimilates basipetally according to the Münch theory, and 2) pressure-concentration waves. The transport of assimilates through the phloem by mechanism 1 is often quantified through isotopic labelling studies. Thus, the time between isotopic labelling in the canopy and when the labeled carbon is respired from the rhizoshpere characterizes the degree of coupling between aboveground and belowground metabolism. The timing between the aboveground uptake and belowground respiration of the labelled carbon is termed the “speed of link”. Based on statistical approaches, recent studies have reported a speed of link on the order of one day or less in mature forests, which is too fast for phloem transport by molecular diffusion or classical sink-sourcedynamics. These studies often cite mechanism 2 to support their conclusions, there is however, absolutely no empirical evidence of pressure-concentration waves affecting soil respiration. In this presentation, we report results from experiments to test the mechanisms behind the speed of link on Douglas-fir saplings of the same provenance.We kept the plants for several days in the dark to create a large carbon source-sink gradient with the intention of inducing a strong pressure-concentration wave. Following the no light treatment, in a controlled growth chamber, we introduced labelled CO2 prior to exposing the plant to light. Upon exposing the plants to light, the labeled CO2 is carboxylated through photosynthesis and after transport, is respired belowground. During the experiment we monitored the carbon isotopic composition of CO2 and the CO2flux from the soil. We hypothesized that if the pressure concentration-wave effect on soil respiration existed then we would see an increase in CO2 flux prior to the arrival of CO2 derived from labelled assimilates.
AB - Currently there are two proposed mechanisms to link assimilation to belowground respiration via the phloem:1) the transport of assimilates basipetally according to the Münch theory, and 2) pressure-concentration waves. The transport of assimilates through the phloem by mechanism 1 is often quantified through isotopic labelling studies. Thus, the time between isotopic labelling in the canopy and when the labeled carbon is respired from the rhizoshpere characterizes the degree of coupling between aboveground and belowground metabolism. The timing between the aboveground uptake and belowground respiration of the labelled carbon is termed the “speed of link”. Based on statistical approaches, recent studies have reported a speed of link on the order of one day or less in mature forests, which is too fast for phloem transport by molecular diffusion or classical sink-sourcedynamics. These studies often cite mechanism 2 to support their conclusions, there is however, absolutely no empirical evidence of pressure-concentration waves affecting soil respiration. In this presentation, we report results from experiments to test the mechanisms behind the speed of link on Douglas-fir saplings of the same provenance.We kept the plants for several days in the dark to create a large carbon source-sink gradient with the intention of inducing a strong pressure-concentration wave. Following the no light treatment, in a controlled growth chamber, we introduced labelled CO2 prior to exposing the plant to light. Upon exposing the plants to light, the labeled CO2 is carboxylated through photosynthesis and after transport, is respired belowground. During the experiment we monitored the carbon isotopic composition of CO2 and the CO2flux from the soil. We hypothesized that if the pressure concentration-wave effect on soil respiration existed then we would see an increase in CO2 flux prior to the arrival of CO2 derived from labelled assimilates.
KW - Ecosystems Research
M3 - Published abstract in conference proceedings
VL - 13
T3 - Geophysical Research Abstracts
SP - 5357
BT - Geophysical Research Abstracts
PB - European Geosciences Union (EGU)
T2 - 8th General Assembly of the European Geosciences Union - EGU 2011
Y2 - 3 April 2011 through 8 April 2011
ER -