Advances in reference materials and measurement techniques for greenhouse gas atmospheric observations

Brewer, Paul J.; Kim, Jin Seog; Lee, Sangil; Tarasova, Oksana; Viallon, Joële; Flores, Edgar; Wielgosz, Robert; Shimosaka, Takuya; Assonov, S. S.; Allison, C. E.; Veen, Adriaan M. H. van der; Hall, B. D.; Crotwell, Andrew M.; Rhoderick, George C.; Hodges, Joseph T.; Mohn, Joachim; Zellweger, Christoph; Moossen, Heiko; Ebert, Volker; Griffith, David

doi:10.1088/1681-7575/ab1506

Cited by 29 publications

(35 citation statements)

References 231 publications

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“…Preliminary isotopic composition measurements of USGS51 and USGS52 revealed relatively large differences between the two standard materials with regard to δ 15 N SP , but not so much for δ 15 N bulk and δ 18 O. To implement a two‐point isotope calibration also for the bulk parameters, however, additional gases with differences in δ 15 N bulk and δ 18 O values are required, and these will probably become available within the framework of the ongoing European metrology project SIRS 59 . These primary N 2 O reference materials can then be applied to establish secondary N 2 O isotope laboratory standards with similar N 2 O and trace gas mole fractions and matrix gases to the sample gas, considering the “identical treatment principle” 22,49 .…”

Section: Analyticsmentioning

confidence: 99%

What can we learn from N₂O isotope data? – Analytics, processes and modelling

Harris

Lewicka‐Szczebak

et al. 2020

Rapid Comm Mass Spectrometry

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115

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The isotopic composition of nitrous oxide (N2O) provides useful information for evaluating N2O sources and budgets. Due to the co‐occurrence of multiple N2O transformation pathways, it is, however, challenging to use isotopic information to quantify the contribution of distinct processes across variable spatiotemporal scales. Here, we present an overview of recent progress in N2O isotopic studies and provide suggestions for future research, mainly focusing on: analytical techniques; production and consumption processes; and interpretation and modelling approaches. Comparing isotope‐ratio mass spectrometry (IRMS) with laser absorption spectroscopy (LAS), we conclude that IRMS is a precise technique for laboratory analysis of N2O isotopes, while LAS is more suitable for in situ/inline studies and offers advantages for site‐specific analyses. When reviewing the link between the N2O isotopic composition and underlying mechanisms/processes, we find that, at the molecular scale, the specific enzymes and mechanisms involved determine isotopic fractionation effects. In contrast, at plot‐to‐global scales, mixing of N2O derived from different processes and their isotopic variability must be considered. We also find that dual isotope plots are effective for semi‐quantitative attribution of co‐occurring N2O production and reduction processes. More recently, process‐based N2O isotopic models have been developed for natural abundance and 15N‐tracing studies, and have been shown to be effective, particularly for data with adequate temporal resolution. Despite the significant progress made over the last decade, there is still great need and potential for future work, including development of analytical techniques, reference materials and inter‐laboratory comparisons, further exploration of N2O formation and destruction mechanisms, more observations across scales, and design and validation of interpretation and modelling approaches. Synthesizing all these efforts, we are confident that the N2O isotope community will continue to advance our understanding of N2O transformation processes in all spheres of the Earth, and in turn to gain improved constraints on regional and global budgets.

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Section: Analyticsmentioning

confidence: 99%

What can we learn from N₂O isotope data? – Analytics, processes and modelling

Harris

Lewicka‐Szczebak

et al. 2020

Rapid Comm Mass Spectrometry

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115

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“…It is commonly agreed that for a robust d scale, the absolute ratio R 13 C/ 12 C of the zero point (VPDB) must be known with a relative uncertainty of 0.01& or lower. 23 This means that also the relative uncertainty associated with the absolute isotope ratio of material A 0 must be less than 0.01&.…”

Section: Simulationmentioning

confidence: 99%

“…A relative uncertainty of 0.01& or better would be required. 23 NBS19 has now been exhausted. Therefore, the International Atomic Energy Agency (IAEA) in Vienna has managed, with much effort, to prepare a new reference material, IAEA-603, 24 realizing the VPDB scale.…”

Section: Introductionmentioning

confidence: 99%

“…These drawbacks can be eliminated by making the scale traceable to the SI, requiring an uncertainty low enough to achieve d 13 C values with uncertainties of 0.01& or lower. 23 The issues which arose with the use of NBS19 and LSVEC (or any other not SI-traceable anchor) illustrate clearly why a method of obtaining SI-traceable isotope ratios of carbon dioxide is highly desirable. One potential way of achieving this is the so-called gravimetric isotope mixture approach, which has been developed by Nier.…”

Section: Introductionmentioning

confidence: 99%

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Absolute isotope ratios of carbon dioxide – a feasibility study

Flierl

Rienitz

Brewer

et al. 2020

J. Anal. At. Spectrom.

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“…In addition to the compound concentration, the stable isotopic composition enables identification of GHG sources and sinks 5–9 . However, the inclusion of isotopic analysis requires different considerations and an appropriate analyzer, such as an isotope ratio mass spectrometer, or optical devices based on tunable diode laser adsorption spectroscopy or Fourier transform infrared spectroscopy 10 . While optical devices are customized to analyze specific compounds only (e.g.…”

Section: Introductionmentioning

confidence: 99%

Successive and automated stable isotope analysis of CO₂, CH₄ and N₂O paving the way for unmanned aerial vehicle‐based sampling

Leitner

Hood‐Nowotny

Watzinger

2020

Rapid Comm Mass Spectrometry

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Rationale Measurement of greenhouse gas (GHG) concentrations and isotopic compositions in the atmosphere is a valuable tool for predicting their sources and sinks, and ultimately how they affect Earth's climate. Easy access to unmanned aerial vehicles (UAVs) has opened up new opportunities for remote gas sampling and provides logistical and economic opportunities to improve GHG measurements. Methods This study presents synchronized gas chromatography/isotope ratio mass spectrometry (GC/IRMS) methods for the analysis of atmospheric gas samples (20‐mL glass vessels) to determine the stable isotope ratios and concentrations of CO2, CH4 and N2O. To our knowledge there is no comprehensive GC/IRMS setup for successive measurement of CO2, CH4 and N2O analysis meshed with a UAV‐based sampling system. The systems were built using off‐the‐shelf instruments augmented with minor modifications. Results The precision of working gas standards achieved for δ13C and δ18O values of CO2 was 0.2‰ and 0.3‰, respectively. The mid‐term precision for δ13C and δ15N values of CH4 and N2O working gas standards was 0.4‰ and 0.3‰, respectively. Injection quantities of working gas standards indicated a relative standard deviation of 1%, 5% and 5% for CO2, CH4 and N2O, respectively. Measurements of atmospheric air samples demonstrated a standard deviation of 0.3‰ and 0.4‰ for the δ13C and δ18O values, respectively, of CO2, 0.5‰ for the δ13C value of CH4 and 0.3‰ for the δ15N value of N2O. Conclusions Results from internal calibration and field sample analysis, as well as comparisons with similar measurement techniques, suggest that the method is applicable for the stable isotope analysis of these three important GHGs. In contrast to previously reported findings, the presented method enables successive analysis of all three GHGs from a single ambient atmospheric gas sample.

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Advances in reference materials and measurement techniques for greenhouse gas atmospheric observations

Cited by 29 publications

References 231 publications

What can we learn from N₂O isotope data? – Analytics, processes and modelling

What can we learn from N₂O isotope data? – Analytics, processes and modelling

Absolute isotope ratios of carbon dioxide – a feasibility study

Successive and automated stable isotope analysis of CO₂, CH₄ and N₂O paving the way for unmanned aerial vehicle‐based sampling

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Advances in reference materials and measurement techniques for greenhouse gas atmospheric observations

Cited by 29 publications

References 231 publications

What can we learn from N2O isotope data? – Analytics, processes and modelling

What can we learn from N2O isotope data? – Analytics, processes and modelling

Absolute isotope ratios of carbon dioxide – a feasibility study

Successive and automated stable isotope analysis of CO2, CH4 and N2O paving the way for unmanned aerial vehicle‐based sampling

Contact Info

Product

Resources

About

What can we learn from N₂O isotope data? – Analytics, processes and modelling

What can we learn from N₂O isotope data? – Analytics, processes and modelling

Successive and automated stable isotope analysis of CO₂, CH₄ and N₂O paving the way for unmanned aerial vehicle‐based sampling