Tracing Low‐CO2 Fluxes in Soil Incubation and 13C Labeling Experiments: A Simplified Gas Sampling System for Respiration and Photosynthesis Measurements

Quantifying carbon dioxide (CO2) fluxes between soil and atmosphere is key in understanding net ecosystem C exchange and biogeochemical C cycling in plant‐soil systems. In ecosystems with low primary production and sparse vegetation, for example, dry lands or subpolar regions where C fluxes are smal...

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Published in:Journal of geophysical research. Biogeosciences 2023-09, Vol.128 (9), p.n/a
Main Authors: Witzgall, K., Hesse, B. D., Seguel, O., Oses, R., Grams, T. E. E., Mueller, C. W.
Format: Article
Language:English
Subjects:
Accessibility
Arid lands
Arid zones
Atmosphere
Balloons
biocrust
Biological activity
Carbon cycle
Carbon dioxide
Carbon dioxide concentration
CO2 flux
Compartments
Constraining
Contamination
dryland soil
Fluxes
Gas sampling
heterotrophic soil respiration
Isotope labelling
Isotopic labeling
Labeling
Meteorological balloons
Microorganisms
Mitigation
Photosynthesis
Plant cover
Plants (botany)
Pressure effects
Primary production
Radioactive labeling
Respiration
Sampling
Sensitivity
Soil
Soil contamination
Soils
Turnover rate
Uptake
Vegetation
Vegetation cover
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container_title Journal of geophysical research. Biogeosciences
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creator Witzgall, K.
Hesse, B. D.
Seguel, O.
Oses, R.
Grams, T. E. E.
Mueller, C. W.
description Quantifying carbon dioxide (CO2) fluxes between soil and atmosphere is key in understanding net ecosystem C exchange and biogeochemical C cycling in plant‐soil systems. In ecosystems with low primary production and sparse vegetation, for example, dry lands or subpolar regions where C fluxes are small, measurement sensitivity is key—even so when measurements are combined with isotopic labeling. Here, we present a simplified gas sampling system developed to facilitate sampling and measurement of low soil CO2 fluxes as well as in situ 13CO2 labeling in the same setup. The capacity of the system was tested in a set of feature tests along with gas measurements of dryland soil‐biocrust systems. The system's sensitivity to capture minor changes in CO2 concentration was confirmed in respiration and photosynthesis measurements of soil‐biocrust systems, where fluxes down to 0.1 μmol CO2 m−2 s−1 were quantified. A balloon, implemented to counterbalance underpressure build‐up during gas withdrawal, mitigated 72% of pressure differences at sampling. The overall system volume was reduced to a minimum to limit contamination caused by residual air, and the design enabled one‐step flushing and evacuation of system compartments and gas sample bags, successfully ruling out cross‐contamination between samples. Ultimately, this system offers a flexible and accessible solution for CO2 measurements that can be applied not only on arid soils with low biological activity and turnover rates, but also on plant‐soil systems. The modifications enabled larger, and thereby more representative, sample volumes to be collected while limiting incubation, contamination, and pressure effects on the intact soil system. Plain Language Summary Measurements of carbon dioxide (CO2) fluxes between soil and atmosphere are crucial to understand the terrestrial carbon cycle. In dry regions, these fluxes are rather small as both the release of CO2 via microbial respiration and uptake of CO2 via photosynthesis is limited by lack of water and sparse vegetation cover. We have developed a simplified CO2 gas sampling setup suitable for incubation experiments of soils with low biological activity and turnover rates, for example, soils from dry lands or subpolar regions, using only cost‐effective, easily available and replaceable system compartments. We tested system parameters in a set of feature tests and could rule out leakage and cross‐contamination. We further confirmed the suitability of the system for
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D. ; Seguel, O. ; Oses, R. ; Grams, T. E. E. ; Mueller, C. W.</creator><creatorcontrib>Witzgall, K. ; Hesse, B. D. ; Seguel, O. ; Oses, R. ; Grams, T. E. E. ; Mueller, C. W.</creatorcontrib><description>Quantifying carbon dioxide (CO2) fluxes between soil and atmosphere is key in understanding net ecosystem C exchange and biogeochemical C cycling in plant‐soil systems. In ecosystems with low primary production and sparse vegetation, for example, dry lands or subpolar regions where C fluxes are small, measurement sensitivity is key—even so when measurements are combined with isotopic labeling. Here, we present a simplified gas sampling system developed to facilitate sampling and measurement of low soil CO2 fluxes as well as in situ 13CO2 labeling in the same setup. The capacity of the system was tested in a set of feature tests along with gas measurements of dryland soil‐biocrust systems. The system's sensitivity to capture minor changes in CO2 concentration was confirmed in respiration and photosynthesis measurements of soil‐biocrust systems, where fluxes down to 0.1 μmol CO2 m−2 s−1 were quantified. A balloon, implemented to counterbalance underpressure build‐up during gas withdrawal, mitigated 72% of pressure differences at sampling. The overall system volume was reduced to a minimum to limit contamination caused by residual air, and the design enabled one‐step flushing and evacuation of system compartments and gas sample bags, successfully ruling out cross‐contamination between samples. Ultimately, this system offers a flexible and accessible solution for CO2 measurements that can be applied not only on arid soils with low biological activity and turnover rates, but also on plant‐soil systems. The modifications enabled larger, and thereby more representative, sample volumes to be collected while limiting incubation, contamination, and pressure effects on the intact soil system. Plain Language Summary Measurements of carbon dioxide (CO2) fluxes between soil and atmosphere are crucial to understand the terrestrial carbon cycle. In dry regions, these fluxes are rather small as both the release of CO2 via microbial respiration and uptake of CO2 via photosynthesis is limited by lack of water and sparse vegetation cover. We have developed a simplified CO2 gas sampling setup suitable for incubation experiments of soils with low biological activity and turnover rates, for example, soils from dry lands or subpolar regions, using only cost‐effective, easily available and replaceable system compartments. We tested system parameters in a set of feature tests and could rule out leakage and cross‐contamination. We further confirmed the suitability of the system for capturing small CO2 fluxes in photosynthesis and respiration measurements of soils with biocrusts. A balloon was installed to counterbalance pressure build‐up during sampling, allowing for larger gas volumes to be collected, which resulted in a mitigation of 72% of the underpressure build‐up. This system offers a straightforward and accessible solution for CO2 measurements, with features limiting contamination and pressure effects on the research sample. Key Points We present a simplified and low‐cost gas sampling system, developed for quantifying CO2 fluxes in soil incubation experiments Respiration rates down to 0.1 μmol CO2 m−2 s−1 were quantified, confirming the suitability of the system for low‐CO2 flux measurements A balloon was installed, mitigating 72% of pressure changes in the headspace during sampling</description><identifier>ISSN: 2169-8953</identifier><identifier>EISSN: 2169-8961</identifier><identifier>DOI: 10.1029/2023JG007410</identifier><language>eng</language><publisher>Washington: Blackwell Publishing Ltd</publisher><subject>Accessibility ; Arid lands ; Arid zones ; Atmosphere ; Balloons ; biocrust ; Biological activity ; Carbon cycle ; Carbon dioxide ; Carbon dioxide concentration ; CO2 flux ; Compartments ; Constraining ; Contamination ; dryland soil ; Fluxes ; Gas sampling ; heterotrophic soil respiration ; Isotope labelling ; Isotopic labeling ; Labeling ; Meteorological balloons ; Microorganisms ; Mitigation ; Photosynthesis ; Plant cover ; Plants (botany) ; Pressure effects ; Primary production ; Radioactive labeling ; Respiration ; Sampling ; Sensitivity ; Soil ; Soil contamination ; Soils ; Turnover rate ; Uptake ; Vegetation ; Vegetation cover</subject><ispartof>Journal of geophysical research. 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Here, we present a simplified gas sampling system developed to facilitate sampling and measurement of low soil CO2 fluxes as well as in situ 13CO2 labeling in the same setup. The capacity of the system was tested in a set of feature tests along with gas measurements of dryland soil‐biocrust systems. The system's sensitivity to capture minor changes in CO2 concentration was confirmed in respiration and photosynthesis measurements of soil‐biocrust systems, where fluxes down to 0.1 μmol CO2 m−2 s−1 were quantified. A balloon, implemented to counterbalance underpressure build‐up during gas withdrawal, mitigated 72% of pressure differences at sampling. The overall system volume was reduced to a minimum to limit contamination caused by residual air, and the design enabled one‐step flushing and evacuation of system compartments and gas sample bags, successfully ruling out cross‐contamination between samples. 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We have developed a simplified CO2 gas sampling setup suitable for incubation experiments of soils with low biological activity and turnover rates, for example, soils from dry lands or subpolar regions, using only cost‐effective, easily available and replaceable system compartments. We tested system parameters in a set of feature tests and could rule out leakage and cross‐contamination. We further confirmed the suitability of the system for capturing small CO2 fluxes in photosynthesis and respiration measurements of soils with biocrusts. A balloon was installed to counterbalance pressure build‐up during sampling, allowing for larger gas volumes to be collected, which resulted in a mitigation of 72% of the underpressure build‐up. This system offers a straightforward and accessible solution for CO2 measurements, with features limiting contamination and pressure effects on the research sample. Key Points We present a simplified and low‐cost gas sampling system, developed for quantifying CO2 fluxes in soil incubation experiments Respiration rates down to 0.1 μmol CO2 m−2 s−1 were quantified, confirming the suitability of the system for low‐CO2 flux measurements A balloon was installed, mitigating 72% of pressure changes in the headspace during sampling</abstract><cop>Washington</cop><pub>Blackwell Publishing Ltd</pub><doi>10.1029/2023JG007410</doi><tpages>11</tpages><orcidid>https://orcid.org/0000-0003-4119-0544</orcidid><orcidid>https://orcid.org/0000-0003-1366-9056</orcidid><orcidid>https://orcid.org/0000-0003-1113-9801</orcidid><orcidid>https://orcid.org/0000-0003-2310-3339</orcidid><orcidid>https://orcid.org/0000-0002-4355-8827</orcidid><orcidid>https://orcid.org/0000-0001-7040-3604</orcidid><oa>free_for_read</oa></addata></record>
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subjects Accessibility
Arid lands
Arid zones
Atmosphere
Balloons
biocrust
Biological activity
Carbon cycle
Carbon dioxide
Carbon dioxide concentration
CO2 flux
Compartments
Constraining
Contamination
dryland soil
Fluxes
Gas sampling
heterotrophic soil respiration
Isotope labelling
Isotopic labeling
Labeling
Meteorological balloons
Microorganisms
Mitigation
Photosynthesis
Plant cover
Plants (botany)
Pressure effects
Primary production
Radioactive labeling
Respiration
Sampling
Sensitivity
Soil
Soil contamination
Soils
Turnover rate
Uptake
Vegetation
Vegetation cover
title Tracing Low‐CO2 Fluxes in Soil Incubation and 13C Labeling Experiments: A Simplified Gas Sampling System for Respiration and Photosynthesis Measurements
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