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IVES 9 IVES Conference Series 9 Macrowine 9 Macrowine 2025 9 Sensory properties: psychophysics, experimental economy, connections with neurosciences 9 Unveiling the chemical headspace of sparkling wine glasses by laser spectroscopy

Unveiling the chemical headspace of sparkling wine glasses by laser spectroscopy

Abstract

Right after serving a sparkling wine into a glass, thousands of rising and bursting bubbles convey gas-phase CO2 and volatile organic compounds (VOCs) in the headspace above the champagne surface, thus progressively modifying the gaseous chemical space perceived by the consumer [1]. Champagne and other traditional method sparkling wines being complex water/ethanol mixtures (with typically 12-13% ethanol by volume), gaseous ethanol is therefore undoubtedly the most abundant VOC in the glass headspace [1]. Yet, both gaseous ethanol and CO2 are known to have a multimodal influence on wine’s perception [2]. As their abundance increases, these two gaseous species stimulate the human trigeminal system, leading to the so-called carbonic bite (induced by excess gaseous CO2), while gaseous ethanol results in a tingling/burning sensation [2,3]. Monitoring simultaneously gaseous CO2 and ethanol (in space and time) in the headspace of sparkling wine glasses is therefore crucial to better understand the neuro-physicochemical mechanisms responsible for aroma release and flavour perception during sparkling wine tasting.

Over the past decade, a diode laser infrared spectrometer has been developed and progressively upgraded in our group to accurately monitor gaseous CO2 through the headspace of champagne glasses [4]. After the addition of a multipath system dedicated to the mapping of CO2 throughout the glass headspace [5,6], and the design of an optomechanical prototype dedicated to the replication of the human gesture of swirling wine [7], the spectrometer has recently been once again upgraded to monitor gaseous ethanol thanks to the recent interband cascade laser (ICL) technology [8]. From the start of sparkling wine serving, and during the next minutes following, kind of spatial-, temperature-, and glass shape-dependent gas-phase CO2 and ethanol footprints were revealed in the headspace of glasses. It is noteworthy to mention that accurately quantifying gaseous ethanol in the headspace of wine glasses is a first step towards quantifying the myriads of VOCs responsible for the wine’s bouquet, which also paves the way for a better understanding of the role of the glass and overall tasting conditions in the world of wine and spirits in the broad sense.

References

[1] Liger-Belair, G., & Cilindre, C. (2021). Annual Review of Analytical Chemistry, 14, 21–46.

[2] Ickes, C. M., & Cadwallader, K. R. (2017). Chemosensory Perception, 10, 119–134.

[3] Cain, W. S., & Murphy, C. L. (1980). Nature, 284, 255–257.

[4] Moriaux, A. L., Vallon, R., Cilindre, C., Parvitte, B., Liger-Belair, G., & Zeninari, V. (2018). Sensors and Actuators, B: Chemical, 257, 745–752.

[5] Moriaux, A.-L., Vallon, R., Lecasse, F., Chauvin, N., Parvitte, B., Zéninari, V., Liger-Belair, G., & Cilindre, C. (2021). Journal of Agricultural and Food Chemistry, 69, 2262–2270.

[6] Alfonso, V., Lecasse, F., Vallon, R., Cilindre, C., Parvitte, B., Zeninari, V., & Liger-Belair, G. (2024). Œno One, 58(2).

[7] Lecasse, F., Vallon, R., Polak, F., Cilindre, C., Parvitte, B., Liger-Belair, G. & Zéninari, V. (2022). Sensors, 22, 5764.

[8] Lecasse, F., Vallon, R., Jacquemin, C., Alfonso, V., Cilindre, C., Parvitte, B., Zéninari, V., & Liger-Belair, G. (2025). ACS Sensors, under review

Publication date: June 4, 2025

Type: Poster

Authors

Florian Lecasse1,*, Raphaël Vallon1, Clément Jacquemin1,2, Vincent Alfonso1, Clara Cilindre1, Bertrand Parvitte1, Virginie Zeninari1 and Gérard Liger-Belair1

1 GSMA, UMR CNRS 7331, Université de Reims Champagne-Ardenne, Reims, France
2 MirSense, 1 rue Jean Rostand, Campus Eiffel, 91400 Orsay, France

Contact the author*

Keywords

sparkling wines, Champagne, gaseous ethanol, CO2, spectroscopy, interband cascade laser

Tags

IVES Conference Series | Macrowine | Macrowine 2025

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