Oxygen flux simulations as a constraint for carbon fluxes and nitrogen sources in a temperate forest ecosystem
Doctoral thesis
Date of Examination:2024-04-12
Date of issue:2024-06-20
Advisor:Prof. Dr. Alexander Knohl
Referee:Dr. Matthias Cuntz
Referee:Prof. Dr. Kerstin Wiegand
Referee:Prof. Dr. Dominik Seidel
Files in this item
Name:Thesis-without-CV.pdf
Size:5.30Mb
Format:PDF
This file will be freely accessible after 2025-04-11.
Abstract
English
The O2:CO2 exchange ratio (ER) between terrestrial ecosystems and the atmosphere is a key parameter for partitioning global ocean and land carbon fluxes. The long-term terrestrial ER is considered to be close to 1.10 mol of O2 consumed per mole of CO2 produced. Due to the technical challenges in measuring directly the ER of entire terrestrial ecosystems (EReco), little is known about variations in ER at hourly and seasonal scales, as well as how different ecosystem and flux components (e.g., vegetation and soil, assimilation and respiration) contribute to EReco. In this modeling study, we explored the variability in and drivers of EReco and evaluated the hypothetical uncertainty in determining ecosystem O2 fluxes based on current instrument precision used in micrometeorological methods such as the flux-gradient approach. We updated the one-dimensional, multilayer atmosphere–biosphere gas exchange model “CANVEG” by 1) implementing ER for various ecosystem components in the model; 2) implementing the control of triose phosphate utilization (TPU) and Medlyn’s stomatal conductance equation to CO2 assimilation; and 3) linking photosynthetic O2 emission to nitrogen (N) assimilation sources. The model study was conducted at the Leinefelde FLUXNET site, a temperate beech forest in Germany, where eddy-covariance, profile, and gas exchange chamber measurements were available. We found that when assuming fixed ER for CO2 assimilation and respiration, the hourly EReco showed strong variations over diel and seasonal cycles and within the vertical canopy profile, indicating the potential to partition eddy-covariance derived CO2 fluxes with corresponding O2 flux measurements. The O2 and CO2 mole fraction ratio of canopy air (ERconc) showed different values and mechanisms from EReco. The model showed more robust performances in future CO2, temperature and air humidity conditions when taking into account TPU limitation and Medlyn’s stomatal conductance algorithm in CO2 assimilation processes. The predicted net carbon sink under elevated atmospheric CO2 mole fraction increased less with TPU limitation than without. The most significant impacts on photosynthetic O2 emission and hence the ER of CO2 assimilation resulted from variation in nitrogen assimilation sources. The ER of net photosynthetic O2 and CO2 exchange measured with branch-level gas exchange chambers 2 showed little variation from 1.0 mol mol-1, indicating ammonia as the main N assimilation source. But O2 emission would increase by up to 11% if the fraction of nitrate increases in the N assimilation source. Our study successfully coupled oxygen with carbon fluxes within a multilayer atmosphere–biosphere gas exchange model. The modeling study yielded that the application of the flux-gradient measurement approach is feasible to derive ecosystem O2 fluxes. To achieve better model behavior, it is necessary to incorporate TPU limitation in the assimilation model and to properly consider N assimilation during photosynthesis.
Keywords: multilayer atmosphere–biosphere gas exchange model; O2:CO2 exchange; CO2 flux source partitioning; flux-gradient method; triose phosphate utilization; photosynthetic nitrogen assimilation