The monitoring of the increasing levels of CO2 in atmosphere, together with the discrimination between the natural and anthropogenic sources of CO2, is of utmost importance to support climate change studies and the reduction of the CO2 emissions from human activities in the close future. The involvement of the metrological community is essential to achieve the comparability of results over space and time, to assure accuracy and metrological traceability, linking all the individual measurement results to common and stable reference standards. The availability of sound and affordable reference materials for the measurement of the isotopic composition of CO2 at ambient amount fraction is foreseen to support the researchers operating in the isotope measurement field, by means of spectroscopic techniques, to assure the metrological traceability for the determination of the isotopic composition of CO2 in air. Reference gas mixtures at known isotopic composition produced by means of primary methods, such as gravimetry, represent a good opportunity for this purpose. At INRiM, the Italian National Metrology Institute, the realization of gaseous reference materials of CO2 in air at known δ13C-CO2 started within the European Joint Research Project (JRP) 16ENV06 SIRS, and continued with the JRP 19ENV05 STELLAR. The reference mixtures are realized by the gravimetric method, following the ISO standard 6142-1, in high-pressure cylinders of aluminum alloy, obtaining low preparation uncertainties of 0.33 % for the CO2 amount fraction at atmospheric level. These mixtures are prepared from parent mixtures at higher amount fraction, realized at INRiM from different pure CO2 sources. Non Dispersive Infrared Spectroscopy (NDIR ABB URAS 14, Switzerland) is used to verify the mixtures for their amount fraction values while Fourier Transform Infrared Spectroscopy (FTIR Thermo Scientific Nicolet iS50, USA) is used for the δ13C-CO2 value assignment. The δ13C-CO2 values of the gravimetric mixtures span in the range from +1.3 ‰ to -42 ‰. Recently, a Cavity Ring-Down Spectrometer (CRDS G2131i Picarro, USA) was acquired to double-check the isotopic composition of the prepared mixtures. Preliminary tests were carried out for the metrological characterization of the instrument, followed by the set-up of the analytical methodology for the confirmation of the isotopic composition of some mixtures prepared within the STELLAR project and sent to other project partners for analysis in the past two years. The results of the tests carried out are presented in this work, together with some future perspectives for the realization of primary reference mixtures of CO2 in air at know isotopic composition on a larger scale.

Realisation of primary mixtures of CO2 in air at known isotopic composition / Rolle, Francesca; Durbiano, Francesca; Pavarelli, Stefano; Pennecchi, Francesca Romana; Sega, Michela. - EGU24-13177(2024). (Intervento presentato al convegno EGU General Assembly 2024 tenutosi a Vienna, Austria nel 14–19 April 2024) [10.5194/egusphere-egu24-13177].

Realisation of primary mixtures of CO2 in air at known isotopic composition

Rolle, Francesca
;
Durbiano, Francesca;Pavarelli, Stefano;Pennecchi, Francesca Romana;Sega, Michela
2024

Abstract

The monitoring of the increasing levels of CO2 in atmosphere, together with the discrimination between the natural and anthropogenic sources of CO2, is of utmost importance to support climate change studies and the reduction of the CO2 emissions from human activities in the close future. The involvement of the metrological community is essential to achieve the comparability of results over space and time, to assure accuracy and metrological traceability, linking all the individual measurement results to common and stable reference standards. The availability of sound and affordable reference materials for the measurement of the isotopic composition of CO2 at ambient amount fraction is foreseen to support the researchers operating in the isotope measurement field, by means of spectroscopic techniques, to assure the metrological traceability for the determination of the isotopic composition of CO2 in air. Reference gas mixtures at known isotopic composition produced by means of primary methods, such as gravimetry, represent a good opportunity for this purpose. At INRiM, the Italian National Metrology Institute, the realization of gaseous reference materials of CO2 in air at known δ13C-CO2 started within the European Joint Research Project (JRP) 16ENV06 SIRS, and continued with the JRP 19ENV05 STELLAR. The reference mixtures are realized by the gravimetric method, following the ISO standard 6142-1, in high-pressure cylinders of aluminum alloy, obtaining low preparation uncertainties of 0.33 % for the CO2 amount fraction at atmospheric level. These mixtures are prepared from parent mixtures at higher amount fraction, realized at INRiM from different pure CO2 sources. Non Dispersive Infrared Spectroscopy (NDIR ABB URAS 14, Switzerland) is used to verify the mixtures for their amount fraction values while Fourier Transform Infrared Spectroscopy (FTIR Thermo Scientific Nicolet iS50, USA) is used for the δ13C-CO2 value assignment. The δ13C-CO2 values of the gravimetric mixtures span in the range from +1.3 ‰ to -42 ‰. Recently, a Cavity Ring-Down Spectrometer (CRDS G2131i Picarro, USA) was acquired to double-check the isotopic composition of the prepared mixtures. Preliminary tests were carried out for the metrological characterization of the instrument, followed by the set-up of the analytical methodology for the confirmation of the isotopic composition of some mixtures prepared within the STELLAR project and sent to other project partners for analysis in the past two years. The results of the tests carried out are presented in this work, together with some future perspectives for the realization of primary reference mixtures of CO2 in air at know isotopic composition on a larger scale.
2024
EGU General Assembly 2024
14–19 April 2024
Vienna, Austria
open
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11696/80859
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