Pr. Virginie ZENINARI

Virginie ZENINARI

VZ



Born in 1972

Full Professor
GSMA - UMR CNRS 7331
Assistant Director since 2024
Reims University
Head of the Master of Physics in Reims since 2011
Member of the Conseil National des Universités (CNU 30) 2019-2023
Co-founder of the AEROVIA start-up in 2010
Member of the council of the DoctoralSchoolSNI 2018-2023
Member of the Research Committee of URCA 2020-2024

Curriculum


1994 – Master of Physics and Instrumentation, Reims
1998 – Ph.D of Physics, Reims University
1999 – Post-doc researcher, Montpellier University

2000 – 2008 : Lecturer CNU 30, GSMA, URCA, Reims
2004 – Habilitation, GSMA, Reims
2006 – 2010 : Bonus for doctoral supervising and Research
2008 – 2012 : Member of the Health and Security committee of the University
2008 – 2013 : Member of the council of the Doctoral School (ED STS)

2008 – 2012 : Second class Professor, CNU 30, URCA
2008 - 2023 : Responsible of theme " Laser spectrometry and Applications" at GSMA, URCA
2009 – 2019 : Member of the scientific committee of GDR SpecMo of CNRS
2010 – 2014 : Bonus for Scientific Excellence
2010 – 2018 : Foundation and scientific advisory of the Start-up Aerovia
Since 2011 : Head of the Master of Physics Reims

2012 – 2018 : First-class Professor (CNU)
2014 - 2022 : Member of the Technical committee of the University
2014 – 2018 : Bonus for doctoral supervising and research
2016 – 2018 : Vice-president of the physics department of the sciences college

Since 2018 : Outstanding Class Professor (CNU)
2018 - 2023 : Member of the council of the Doctoral School SNI
2018 - 2022 : Bonus for doctoral supervising and research
2019 - 2023 : Member of the Conseil National des Universités (CNU 30)
2020 - 2024 : Member of the Research Committee of URCA
Since 2022 : Vice-president of the physics department of the sciences college
Since 2023 : Bonus RIPEC C3
Since 2024 : Assistant director of GSMA

Examinations board

PH.D THESES (without supervised theses)

2006 : Member of the board of the PhD thesis of Thibault LE BARBU (URCA)

2011 : Reviewer of the PhD thesis of Mohammad JAHJAH ( Univ. Montpellier II)

2012 : Reviewer of the PhD thesis of Christophe LENGIGNON (Univ. Littoral Cote d'Opale)

2012 : Member of the board of the PhD thesis of Guillaume BLOOM (Institut d'optique / Paris XIII)

2015 : Reviewer of the PhD thesis of Quentin CLEMENT (Ecole Polytechnique - ONERA)

2018 : Reviewer of the PhD thesis of Julie ARMOUGOM (ONERA - ED Grenoble)

2021 : Reviewer of the PhD thesis of Maxime DUQUESNOY (ONERA - ED Paris-Saclay)

2021 : Member of the board of the PhD thesis of Gregory QUINCHARD (Univ. Lille)

2023 : Reviewer of the PhD thesis of Diba AYACHE (Montpellier University)

RECRUITMENTS

From 2001 to 2008, I was a member of the committee of experts for CNU 30 in URCA. During this period 4 lecturers have been recuited.

Since 2008, I am regularly asked for various committees of recruitment :
➢ 2008, member of the recruitment committee of a research engineer in Reims.

➢ 2009, member of the recruitment committee of temporary physics teachers CNU 28-29-30.

➢ 2010, member of the selection committee of a lecturer in Reims, CNU 30.

➢ 2011, presidency of the recruitment committee of temporary physics teachers, CNU 30.

➢ 2012, member of the r ecruitment committee of temporary physics teachers CNU 30.

➢ 2013, member of the selection committee of a Professor in Reims, CNU 85.

➢ 2014, member of the recruitment committee of temporary physics teachers CNU 30.

➢ 2019, member of the selection committee of a Professor in Dunkerque, CNU 30.

➢ 2019, member of the selection committee of a Professor in Reims, CNU 31.

➢ 2019, member of the selection committee of a Professor in Bordeaux, CNU 28-29-30.

➢ 2020, member of the selection committee of a lecturer in Reims, CNU 30.

➢ 2022, presidency of the selection committee of a Professor in Reims, CNU 30.

➢ 2022, member of the selection committee of a Chaire de Professeur Junior in Reims, CNU 37.

➢ 2023, member of the recruitment committee of temporary physics teachers CNU 28.

➢ 2023, member of the selection committee of a Lecturer in Dunkerque, CNU 30.

Theses supervisions

Since october 2022 : Vincent ALFONSO (Université de Reims) « Développement de méthodes spectrométriques et chimiques pour l’étude de la désorption du CO2, de l’éthanol et des composés organiques volatils (COV) hors d’un vin de Champagne en conditions de dégustation »
Supervisors: V. ZENINARI (50 %), G. LIGER-BELAIR
Funding: URCA

2020-2023 : Clément JACQUEMIN (23/11/2023, Université de Reims) « Optimisation de spectromètres laser infrarouge pour la détection de gaz d'intérêt atmosphérique »
Supervisors: V. ZENINARI (50 %), B. PARVITTE
Funding: CIFRE from mirSense

2019-2023 : Florian LECASSE (25/10/2023, Université de Reims) « Désorption du CO2 et de l'éthanol dans l'espace de tête d'un verre de champagne, en condition statique et dynamique, par spectroscopie laser infrarouge »
Supervisors: V. ZENINARI (50 %), B. PARVITTE
Funding: Region and URCA. Continued in our lab.

2017-2023: Florent DEFOSSEZ (Co-tutelle 27/11/2023 Université de Mons - 21/12/2023 Université de Reims) « Contribution au développement d’un Système d’Analyse de Feux et Emanations par Spectroscopie Infrarouge à Distance et Embarquée »
Supervisors : V. ZENINARI, S. BROHEZ (UMONS)
Funding : INTERREG France-Wallonie-Flandres project SAFESIDE. Continued in multitel.be.

2017-2021 : Chehem MOHAMED IBRAHIM (03/12/2021 Université de Reims) « Spectrométrie Laser Photoacoustique : simulations et applications à la détection de gaz »
Supervisors : V. ZENINARI (50 %), B. PARVITTE
Funding : Djibouti. Continued as teacher in National Education.

2015-2019 : Laurent BIZET (14/02/2019 Université de Reims) « Spectrométrie Laser avec sources moyen infrarouge largement accordables et application à la détection de gaz »
Supervisors : V. ZENINARI (50 %), B. PARVITTE
Funding : DGA / Region. Continued as Post-Doc in LOA (loa.ensta-paris.fr)

2015-2018 : Anne-Laure MORIAUX (13/12/18 Université de Reims) « Etude de la désorption du CO2 dans l'espace de tête d'un verre de Champagne par spectrométrie laser infrarouge »
Supervisors : V. ZENINARI (50 %), G. LIGER-BELAIR
Funding : Ministry. Continued in post-doc in GSMA. Currently at ANSES (www.anses.fr)

2012-2016 : Marie-Hélène MAMMEZ (28/06/16 Université de Reims) « Détection hétérodyne de molécules d’intérêt atmosphérique à l’aide de laser à cascade quantique »
Supervisors : V. ZENINARI (50 %), B. PARVITTE
Funding : DGA-CNRS. Continued in post-doc in PhLAM-Lille and in LPCA in Dunkerque University.

2012-2015 : Justin ROUXEL (27/11/15 Université de Reims) « Conception et réalisation de cellules photoacoustiques miniaturisées pour la détection de traces de gaz »
Supervisors : V. ZENINARI (50 %), B. PARVITTE
Funding : CEA. Recruited by Evosens - Brest in 2016. Currently in sensors lab in IFREMER - Brest since 2019.

2012-2015 : Christophe RISSER (05/02/15 Université de Reims) « Réalisation d’instruments de détection de gaz par spectrométrie laser photoacoustique »
Supervisors : V. ZENINARI (50 %), B. PARVITTE
Funding : CIFRE from AEROVIA start-up. Recruited by Aerovia in 2015. He founded his own company in 2019.

2010-2013 : Dominique MAMMEZ (12/11/13 Université de Reims) « Détection de molécules gazeuses d’intérêt atmosphérique par spectrométrie infrarouge avec laser à cascade quantique largement accordable»
Supervisors : V. ZENINARI (50 %), B. PARVITTE
Funding : DGA-region. Continued in post-doc in ONERA then in Institut FOTON in Rennes University.

2006-2009 : Maxime MULIER (07/12/09 Université de Reims) « Mise en place d’un spectromètre laser infrarouge pour l’étude de la diffusion du CO2 gazeux hors du champagne et de quelques boissons effervescentes »
Supervisors : V. ZENINARI (50 %), G. LIGER-BELAIR
Funding : CPER/Region. Continued as Research Engineer in Orsay then as R&D engineer in the private sector.

2005-2008 : Bruno GROUIEZ (02/12/08 Université de Reims) « Applications des lasers à cascade quantique pulsés à l’étude de l’atmosphère »
Supervisors : V. ZENINARI (50 %), B. PARVITTE
Funding : region. Continued in Post-Doc at CEA Saclay. Currently Research Engineer in GSMA since 2013.

2004-2007 : Agnès GROSSEL (07/12/07 Université de Reims) « Spectrométrie infrarouge et détection de gaz à l’aide de lasers à cascade quantique »
Supervisors : V. ZENINARI (95 %), D. COURTOIS
Funding : DGA. Continued in Post-Doc in Germany. Currently INRA researcher in Orléans since 2010.

Research themes

- Implementation of tunable infrared lasers:

- Mid-Infrared Pb-salt diodes lasers (8-12 µm);
- Near-infrared diodes lasers (1-3 µm);
- Mid-Infrared Quantum Cascade Lasers (QCL) (4-10 µm);
- External cavity widely-tunable Quantum Cascade Lasers;
- Widely-tunable micro-stripes of QCLs;
- OPO laser sources based on non-linear optics
- Dual comb spectral source in the mid-infrared

- Trace gases detection by photoacoustics:

- C2H4 and O3 @10 µm with a CO2 laser;
- CH4 with near-infrared diodes lasers;
- NO @5 µm and CH4, N2O and H2O @8 µm with QCLs;
- Industrial development of a photoacoustic sensor: AEROVIA start-up
- Miniaturization of sensors within the MIRIADE ANR project
- Modelization of the sensors by the Finite Element Method.

- Laboratory measurements of spectroscopic parameters:

- of water vapor @1,4 µm ; atmospheric applications;
- of carbon dioxide @1,6 and @2 µm ; atmospheric applications;
- of H2O, CO2 and their isotopes ; applications to the Martian atmosphere
- of SO2 @9 µm ; demonstration of a hot band and of 34SO2
- of N2O @8 µm ; atmospheric applications;
- of CH4 @1,6 µm ; applications to the MERLIN spatial mission.

- Development of instruments with lasers for various applications :

- Ground and balloon-borne sensors of water vapor and its isotopologues;
- Ground CO2 measurements and inter-comparison campaign;
- Ground N2O and CH4 sensors for agronomical applications;
- Widely-tunable sensor for explosives detection;
- Developement of the intracavity technique in the mid-infrared;
- CO2 sensor for enological applications to Champagne;
- Ethanol detector for enological and health applications.

Funded research projects

[C40] Détecteur moyen infrarouge dans la gamme 5-20 µm, CNRS funding (V. ZÉNINARI, B. PARVITTE, R. VALLON), 2024 (≈ 20 k€).

[C39] Complement to the purchase of the "Spectromètre Peignes de Fréquence Infrarouge", CNRS funding (V. ZÉNINARI, B. PARVITTE, R. VALLON), 2023 (≈ 40 k€).

[C38] Spectromètre "Peignes de Fréquence Infrarouge", Grand-Reims / URCA Funding, 2023 (≈ 150 k€).

[C37] Mesure de l'éthanol par spectrométrie laser infrarouge pour des applications oenologiques, Tremplin@INP2020 CNRS (G. LIGER-BELAIR, V. ZÉNINARI, R. VALLON), 2020-2021 (≈ 25 k€).

[C36] Spectromètre par Transformée de Fourier à basse résolution pour la caractérisation des source lasers de nouvelle génération, CNRS Funding (V. ZÉNINARI, B. PARVITTE, R. VALLON), 2018-2019 (≈ 40 k€).

[C35] ETHYlomètre LASer (ETHYLAS), PRCE ANR with MirSense (Palaiseau-Grenoble), 2018-2021 (≈ 300 k€ with ≈ 120 k€ @GSMA).

[C34] Source COMB intégrée sur plateforme SiGe nonlinéaire émettant dans le moyen infra-rouge (MIRSiCOMB), PRC ANR with INL (C. GRILLET) and CEA-LETI, 2018-2021 (≈ 600 k€ with ≈ 50 k€ @GSMA).

[C33] SAFESIDE : Système d’Analyse de Feux et Emanations par Spectroscopie Infrarouge à Distance et Embarquée, Interreg V France Wallonie Vlaanderen with Multitel asbl (Mons, Belgique), Université de Mons (Belgique), Institut du risque (Belgique), Université de Gand (Belgique), et Université du Littoral Cote d’Opale (Dunkerque), 2017-2020 (≈ 1 M€ with ≈ 100 k€ @GSMA).

[C32] Spectrométrie Laser Intracavité avec des composants à Cascade Quantique (SLICQ), Joint Funding from the Région Champagne-Ardenne and the DGA for operating costs of the Ph.D. thesis of Laurent BIZET (V. ZENINARI, PI), 2015-2018 (≈ 30 k€).

[C31] Validation des concepts de couplage Cellule Photoacoustique avec Cellule Multipassage et d’une cellule Photoacoustique à résonance secondaire, Banque Publique d’Investissement (BPI-France – ex-OSEO) with AEROVIA, 2015 (≈ 100 k€ with 10 k€ @GSMA).

[C30] Détection à distance de gaz par lasers infrarouges à cascade quantique (QUantum cascade Infrared lasers GAs Remote DEtection, QUIGARDE), ANR ASTRID n°12-ASTR-0028 with III-V LAB Palaiseau and Laboratoire de Physique des Lasers (Paris-XIII), 2013-2016 (≈ 300 k€ with ≈ 85 k€ @GSMA).

[C29] Project MERLIN (MEthane Remote LIdar missioN) : Spectroscopie du méthane vers 1,6 µm, Mission Franco-Allemande R&T CNES TOSCA (Terre, Océan, Surfaces Continentales, Atmosphère) 2012-2019 (≈ 500 k€ each year with ≈ 100 k€ @GSMA)

[C28] COherent quantum Cascade laser Array for high SEnsitivity gas detection (COCASE), ANR ASTRID n° 11-ASTR-0027 with III-V LAB Palaiseau, 2012-2014 (≈ 300 k€ with ≈ 100 k€ @GSMA).

[C27] Mid-InfraRed Integrated photo-Acoustic spectrometer Device for Environment survey (MIRIADE), ANR ECOTECH n° 11-ECOT-004 with III-V LAB Palaiseau, CEA – LETI, LSCE and AEROVIA, 2012-2015 (≈ 1 M€ with ≈ 225 k€ @GSMA).

[C26] Aérovia : Instruments d’analyse de gaz innovants à hautes performances, Lauréat du Concours National OSEO : start-up AEROVIA, 2011-2012 (≈ 200 k€).

[C25] Compact Photo-Acoustic Mid-Infrared Spectroscopy Sensor for Extended Range of Chemical Agents, Région Champagne-Ardenne funding of AcousticNose [C24] program 2010-2012 (≈ 100 k€)

[C24] Compact Photo-Acoustic Mid-Infrared Spectroscopy Sensor for Extended Range of Chemical Agents (AcousticNose), Programme EURIPIDES/Eureka n° EUR-09-710 with Norsk Elektro Optikk AS, “NEO” (Norway) and Alcatel Thales III-V Lab, “ATL” (France), 2010-2012 (≈ 800 k€ with ≈ 150 k€ @ GSMA)

[C23] Validation de la mesure du N2O par le spectromètre Quantum Cascade Laser, Scientific project Institut Pierre-Simon Laplace, 2010 (≈ 10 k€).

[C22] Optimisation électronique d’un senseur photoacoustique ultra-sensible, Contract Bonus Qualité Recherche de l’Université de Reims Champagne-Ardenne, 2010 (≈ 20 k€).

[C21] Source Laser à Cascade quantique largement accordable pour la spectroscopie infrarouge (SELECTIF), « Recherche Exploratoire et Innovation » Contract n°2009.34.0040 DGA with Laboratoire III-V lab, 2009-2011 (≈ 450 k€ with ≈ 120 k€ @GSMA).

[C20] Instruments d’analyse de gaz innovants à hautes performances, Programme d’Aide au transfert d’OSEO vers l’industrie (foundation of AEROVIA), 2009-2010 (≈ 55 k€).

[C19] Capteurs lasers de nouvelle génération pour le suivi des gaz traces dans l’atmosphère, PEPS CNRS Contract, 2009-2010 (≈ 20 k€)

[C18] Spectrométrie laser à base de laser à cascade quantique pour l’étude de l’atmosphère, CNRS/INSU funding, 2009 (≈ 40 k€).

[C17] Mesure et modélisation des cycles CN : facteurs de décomposition des matières organiques et émission de N2O des sols, Contrat de Projet Etat-Région (CPER), 2008-010 (≈ 200 k€ with ≈ 120 k€ @GSMA).

[C16] Lutte contre les maladies de la vigne : stratégies alternatives à la lutte chimique. Contrat de Projet Etat-Région (CPER), 2007-2013 (≈ 1500 k€ with ≈ 60 k€ @GSMA for the thesis of M. MULIER).

[C15] Etude de faisabilité de détection à distance d’explosifs par spectroscopie dans l’infrarouge moyen, Contrat d’Etude pour la SAGEM, 2007 (≈ 12 k€).

[C14] Mesure à partir du sol du dioxyde de carbone atmosphérique, Contract Bonus Qualité Recherche de l’Université de Reims Champagne-Ardenne, 2007 (Montant ≈ 20 k€).

[C13] Etude de la vapeur d’eau dans l’UT-LS tropicale à l’aide de la sonde laser Pico-SDLA sous ballons météo, Programme National « Les Enveloppes Fluides et l’Environnement », Action « CHimie ATmosphérique », 2007-2008 (≈ 15 k€).

[C12] Mesure in situ de N2O avec des diodes lasers moyen infrarouge, Programme National « Les Enveloppes Fluides et l’Environnement », Action « CHimie ATmosphérique », with Laboratoire de Physique et Chimie de l’Environnement (LPCE) Orléans, 2006-2007 (≈ 10 k€).

[C11] Détection de Polluants Atmosphériques au moyen de Nouvelles Sources Infrarouges, Appel d’Offres Région « Emergence de nouvelles thématiques et/ou de nouveaux partenariats », 2006-2007 (≈ 40 k€).

[C10] Spectrométrie infrarouge des atmosphères planétaires, Contrat de Plan Etat-Région (CPER), 2006-2007 (≈ 130 k€)

[C9] Mesure de colonnes de CO2 atmosphérique vers 1.6 µm par le spectromètre à réseaux SOIR : spectroscopie et calibration en labo, Programme National de Télédétection Spatiale, 2005-2006 (≈ 15 k€).

[C8] Spectroscopie Infrarouge Mobile de Polluants Atmosphériques par Lasers à Cascade Quantique (SIMPA), Action Concertée Incitative with PC2A, B. HANOUNE and PhLAM, B. LEMOINE, 2004-2006 (≈ 120 k€ with ≈ 30 k€ @GSMA).

[C7] Mesure in situ des isotopes de la vapeur d’eau dans la tropopause et la basse stratosphère par diodes laser, Programme National « Chimie Atmosphérique », 2004-2005 (≈ 10 k€).

[C6] Spectrométrie laser infrarouge, Contrat de Plan Etat-Région (CPER), 2004-2005 (≈ 230 k€).

[C5] Nouvel instrument LAser portable pour la mesure des COmposés Chimiques à l’état de traces dans l’atmosphère (LACOC), Action Concertée Incitative « Nouvelles Méthodologies et Capteurs » with LPCA, W. CHEN and LSP, D. ROMANINI, 2003-2006 (≈ 120 k€ with ≈ 25 k€ @GSMA).

[C4] Mesure in situ de la vapeur d’eau stratosphérique par diode laser, Programme National « Chimie Atmosphérique » with SA, G. DURRY, 2003-2004 (≈ 10 k€).

[C3] Mesure in situ du dioxyde de carbone dans la troposphère et la basse stratosphère par diode laser, Programme National « Chimie Atmosphérique » with SA, G. DURRY and CEM2, A. VICET, 2002-2003 (≈ 10 k€).

[C2] Mesure in situ de la vapeur d’eau et de ses isotopes par diode laser dans le proche et le moyen infrarouge, Programme National « Chimie Atmosphérique » with Service d’Aéronomie (SA, G. DURRY), 2001-2002 (≈ 10 k€).

[C1] Détection sélective de gaz, notamment du méthane, par la méthode photoacoustique consistant à mesurer l’absorption du gaz excité par une diode laser, ANVAR and Région Champagne-Ardenne Contract n° A0002010GAT, 2000-2001 (≈ 1 MF ≈ 150 k€).

Scientific production

More than 155 papers and patents including 82 international peer-reviewed publications.
More than 280 oral or poster communications in national or international congresses including about fifteen invited oral communications.

2023

[157] Intrapulse Measurement Using a Quantum Cascade Laser Coupled with a Compact Dense Pattern Multipass Absorption Cell for Carbon Dioxide Monitoring, C. Jacquemin, F. Defossez, R. Vallon, B. Parvitte, G. Maisons, M. Carras, V. Zeninari, Journal of the Optical Society of America B: Optical Physics, 40, Issue 1, pp. A21-A27 (2023), https://doi.org/10.1364/JOSAB.469404

[156] Gas-detecting device with very high sensitivity based on a Helmholtz resonator, C. Risser, V. Zéninari, B. Parvitte, Brevet Européen n° EP2016080622, Publication n° EP 3 350 571 (B1), le 06.12.2023, https://patents.google.com/patent/EP3350571B1/en

[155] Development of a Breathalyzer for Ethanol Detection using Quantum Cascade Laser Array and a Dense Pattern Multipass Cell, C. Jacquemin, R. Vallon, B. Parvitte, G. Maisons, M. Carras, V. Zéninari, Conference Papers – Conference on Lasers and Electro-Optics – CLEO/EUROPE and European Quantum Electronics Conference – EQEC 2023, 10232325, 1 page (2023), https://doi.org/10.1109/CLEO/EUROPE-EQEC57999.2023.10232325

2022

[154] Mode-hop compensation for intracavity sensing via chip voltage in an external cavity QCL, L. Bizer, R. Vallon, B. Parvitte, G. Maisons, M. Carras, V. Zéninari, Applied Physics B, 128 (9), 166, 8 pages (2022), https://doi.org/10.1007/s00340-022-07882-z

[153] An infrared laser sensor for monitoring gas-phase CO2 in the headspace of Champagne glasses under wine swirling conditions, F. Lecasse, R. Vallon, F. Polak, C. Cilindre, B. Parvitte, G. Liger-Belair, V. Zeninari, Sensors, 22 (15), 5764. 12 pages (2022), https://doi.org/10.3390/s22155764

[152] Real-time and on-field CO2 sensing based on a fast frequency modulation OPO system, F. Defossez, Y. Hernandez, J-B Lecourt, A. Gognau, S. Boivinet, R. Vallon, B. Parvitte, V. Zeninari, S. Brohez, D. Dewaele, F. Cazier, A. Peremans, L. Lamard, A. Baylon, , SPIE Proceedings 12139 – Optical Sensing and Detection VII, 121390V, 9 pages (2022), https://doi.org/10.1117/12.2621659

[151] Intrapulse Measurement Using Quantum Cascade Laser Coupled with Compact Dense Pattern Multipass Absorption Cell for Carbon Dioxide Monitoring, C. Jacquemin, R. Vallon, F. Defossez, B. Parvitte, G. Maisons, M. Carras, V. Zeninari, Optics InfoBase Conference Papers – Part MF2C.2 -MICS, 2 pages (2022), https://doi.org/10.1364/MICS.2022.MF2C.2

[150] On-field NH3 remote sensing based on a fast wavelength modulated OPO system, F. Defossez, Y. Hernandez, J-B Lecourt, A. Gognau, S. Boivinet, R. Vallon, B. Parvitte, V. Zeninari, S. Brohez, D. Dewaele, F. Cazier, A. Peremans, L. Lamard, A. Baylon, Optics InfoBase Conference Papers – Part MF3C.5 -MICS, 2 pages (2022), https://doi.org/10.1364/MICS.2022.MF3C.5

2021

[149] How does gas-phase CO2 evolve in the headspace of champagne glasses?, A.-L. Moriaux, R. Vallon, F. Lecasse, N. Chauvin, B. Parvitte, V. Zeninari, G. Liger-Belair, C. Cilindre, Journal of Agricultural and Food Chemistry, 69, 7, 2262-2270 (2021), https://doi.org/10.1021/acs.jafc.0c02958

2020

[148] Widely-Tunable Quantum Cascade-based Sources for the Development of Optical Gas Sensors, V. Zeninari, R. Vallon, L. Bizet, C. Jacquemin, G. Aoust, G. Maisons, M. Carras, B. Parvitte, Sensors 20, pp. 6650 15 pages (2020), https://doi.org/10.3390/s20226650

[147] A first step towards the mapping of gas-phase CO2 in the headspace of champagne glasses, A.-L. Moriaux, R. Vallon, C. Cilindre, F. Polak, G. Liger-Belair, B. Parvitte, V. Zeninari, Infrared Physics and Technology 109, 103437, 9 pages (2020), https://doi.org/10.1016/j.infrared.2020.103437

[146] Quantitative Finite Element Modelling of Compact Photoacoustic Gas Sensors, B. Parvitte, R. Vallon, C. Mohamed Ibrahim, C. Jacquemin, V. Zeninari, Journal of Materials Sciences and Applications 3, pp. 1-8 (2020), https://doi.org/10.17303/jmsa.2020.4.101

[145] Gas-detecting device with very high sensitivity based on a Helmholtz resonator, C. Risser, V. Zéninari, B. Parvitte, Brevet US n° US15/769,516, Publication n° US 10 876 958 (B2), (2020) https://patents.google.com/patent/US10876958B2/en

[144] An infrared laser spectrometer for the mapping of gaseous CO2 in the headspace of champagne glasses, R. Vallon, A.-L. Moriaux, F. Lecasse, B. Parvitte,C. Cilindre, G. Liger-Belair, V. Zeninari, OSA Technical Digest (Optical Society of America), paper LM3A.4, 2 pages (2020), https://doi.org/10.1364/LACSEA.2020.LM3A.4

[143] Simulation of the non-linearity of photoacoustic signals for the detection of molecules of atmospheric interest, V. Zeninari, C. Mohamed Ibrahim, R. Vallon,B. Parvitte, OSA Technical Digest (Optical Society of America), paper JTu2A.9, 2 pages (2020), https://doi.org/10.1364/3D.2020.JTu2A.9

2019

[142] Design and implementation of a heliostat for atmospheric spectroscopy, M.-H. Mammez, R. Vallon, F. Polak, B. Parvitte, V. Zéninari, Infrared Physics and Technology 97, pp. 235-243 (2019), https://doi.org/10.1016/j.infrared.2019.01.006

[141] Tunable Mid-IR Hybrid Fiber/Crystal Laser for Gas Sensing, C.-E. Ouinten, F. Defossez, L. Lamard, A. Gognau, R. Vallon, B. Parvitte, V. Zeninari, J.-B. Lecourt, Y. Hernandez, A. Peremans, OSA Technical Digest (Optical Society of America), paper LW4B.3, 2 pages (2019), https://doi.org/10.1364/LSC.2019.LW4B.3

[140] Upgrading a Laser-Based Spectrometer for the Mapping of Gas-phase CO2 in the Headspace of Champagne Glasses, B. Parvitte, A. L. Moriaux, R. Vallon, C. Cilindre, G. Liger-Belair, V. Zeninari, Conference Papers – Conference on Lasers and Electro-Optics – CLEO/EUROPE and European Quantum Electronics Conference – EQEC 2019, 8872914, 1 page (2019), https://doi.org/10.1109/CLEOE-EQEC.2019.8872914

[139] Extended-Cavity-Quantum-Cascade-Laser-Voltage Intracavity Sensing and Application to Atmospheric Gas Detection, R. Vallon, L. Bizet, B. Parvitte, G. Maisons, M. Carras, V. Zeninari, Conference Papers – Conference on Lasers and Electro-Optics – CLEO/EUROPE and European Quantum Electronics Conference – EQEC 2019, 8871446, 1 page (2019), https://doi.org/10.1109/CLEOE-EQEC.2019.8871446

[138] Picosecond Widely-Tunable mid-IR Source for Gas Detection, F. Defossez, R. Vallon, B. Parvitte, C.-E. Ouinten A. Gognau, J.-B. Lecourt, Y. Hernandez, V. Zeninari, Conference Papers – Conference on Lasers and Electro-Optics – CLEO/EUROPE and European Quantum Electronics Conference – EQEC 2019, 8872325, 1 page (2019), https://doi.org/10.1109/CLEOE-EQEC.2019.8872325

[137] Fast tunable Mid-IR source pumped by a picosecond fiber laser, C.-E. Ouinten, F. Defossez, A. Gognau, Y. Hernandez, J.-B. Lecourt, R. Vallon, B. Parvitte, V. Zéninari, L. Lamard, A. Peremans, SPIE Proceedings 10896 – Solid State Lasers XXVIII: Technology and Devices, 1089602, 7 pages (2019) https://doi.org/10.1117/12.2507871

2018

[136] Monitoring gas-phase CO2 in the headspace of champagne glasses through combined diode laser spectrometry and micro-gas chromatography analysis, A.-L. Moriaux, R. Vallon, B. Parvitte, V. Zéninari, G. Liger-Belair, C. Cilindre, Food Chemistry 264, pp. 255-262 (2018), https://doi.org/10.1016/j.foodchem.2018.04.094

[135] Test and Development of an OPO-Based Spectrometer for SAFESIDE – An INTERREG V project for gases detection, F. Defossez, R. Vallon, B. Parvitte, S. Brohez, S. Guillemet, Y. Hernandez, V. Zéninari, Optics Infobase Conference papers - High-Brightness Sources and Light-driven Interactions: Mid-Infrared Coherent Sources, 2 pages (2018), https://doi.org/10.1364/EUVXRAY.2018.JT5A.19

[134] Intracavity Gas Detection with an extended-cavity Quantum Cascade Laser emitting @ 7.6 µm, L. Bizet, R. Vallon, B. Parvitte, G. Maisons, M. Carras, V. Zéninari, Optics Infobase Conference papers - High-Brightness Sources and Light-driven Interactions: Mid-Infrared Coherent Sources, 2 pages (2018), https://doi.org/10.1364/MICS.2018.MT3C.4

[133] Applications of IR Laser Spectrometry to the Monitoring of Gaseous CO2 in the Headspace of Champagne Glasses, R. Vallon, A.-L. Moriaux, B. Parvitte, C. Cilindre, G. Liger-Belair, V. Zéninari, Optics Infobase Conference papers - High-Brightness Sources and Light-driven Interactions: Mid-Infrared Coherent Sources, 2 pages (2018), https://doi.org/10.1364/EUVXRAY.2018.JT5A.13

[132] Gas-detecting device with very high sensitivity based on a Helmholtz resonator, C. Risser, V. Zéninari, B. Parvitte, Brevet US n° US15/769,516, Publication n° US 2018 0306704 (A1), (2018) https://patents.google.com/patent/US20180306704/en

[131] Monitoring of Gaseous CO2 in the Headspace of Champagne Glasses by Infrared Laser Spectrometry, R. Vallon, A.-L. Moriaux, B. Parvitte, C. Cilindre, G. Liger-Belair, V. Zéninari, Optics Infobase Conference papers - Imaging and Applied Optics: Laser Applications to Chemical, Security and Environmental Analysis, 2 pages (2018), https://doi.org/10.1364/3D.2018.JW4A.14

[130] Towards sub-mm-size Helmholtz Photoacoustic Cells for Atmospheric Gas Sensing: simulation and developments, V. Zéninari, C. Mohamed Ibrahim, R. Vallon, B. Parvitte, Optics Infobase Conference papers - Imaging and Applied Optics: Laser Applications to Chemical, Security and Environmental Analysis, 2 pages (2018), https://doi.org/10.1364/3D.2018.JM4A.26

[129] Detectorless Intracavity Technique with an EC-QCL for Atmospheric Gas Detection, R. Vallon, L. Bizet, B. Parvitte, G. Maisons, M. Carras, V. Zéninari, Optics Infobase Conference papers - Imaging and Applied Optics: Laser Applications to Chemical, Security and Environmental Analysis, 2 pages (2018), https://doi.org/10.1364/LACSEA.2018.LM5C.5

[128] Gas-detecting device with very high sensitivity based on a Helmholtz resonator, C. Risser, V. Zéninari, B. Parvitte, Brevet Européen n°EP2016080622, Publication n° EP 3 350 571 (A1), (2018) https://patents.google.com/patent/EP3350571A1/en

[127] Latest developments of a laser-based spectrometer devoted to the monitoring of gaseous CO2 for enological applications, R. Vallon, A.-L. Moriaux, B. Parvitte, C. Cilindre, G. Liger-Belair, V. Zéninari, Optics Infobase Conference papers - Advanced Photonics Congress: Optical Sensors Conference, 2 pages (2018) https://doi.org/10.1364/BGPPM.2018.JTu2A.72

[126] Latest results of an Intracavity-QCL based spectrometer for Atmospheric Gas Detection, B. Parvitte, L. Bizet, R. Vallon, G. Maisons, M. Carras, V. Zéninari, Optics Infobase Conference papers - Advanced Photonics Congress: Optical Sensors Conference, 2 pages (2018) https://doi.org/10.1364/BGPPM.2018.JTu2A.73

[125] Helmholtz-based photoacoustic sensors for trace gases detection, V. Zéninari, Optics Infobase Conference papers - Advanced Photonics Congress: Optical Sensors Conference, 2 pages (2018) https://doi.org/10.1364/SENSORS.2018.SeTh3E.1

[124] Development and validation of a diode laser sensor for gas-phase CO2 monitoring above champane and sparkling wines, A.-L. Moriaux, R. Vallon, C. Cilindre, G. Liger-Belair, B. Parvitte, V. Zéninari, Sensors and Actuators B : Chemical, 257, pp. 745-752 (2018), https://doi.org/10.1016/j.snb.2017.10.165

2017

[123] Gas-detecting device with very high sensitivity based on a Helmholtz resonator, C. Risser, V. Zéninari, B. Parvitte, Brevet International n° FR2016052741, Publication n° WO 2017 068301 (A1), (2017) https://patentscope.wipo.int/search/en/detail.jsf?docId=WO2017068301

[122] Dispositif de détection de gaz à très forte sensibilité basé sur un résonateur de Hemholtz C. Risser, V. Zéninari, B. Parvitte, Brevet Français n° FR20150060028, Publication n° FR 3 042 866 (A1), (2017) https://bases-brevets.inpi.fr/fr/document/FR3042866.html

[121] Dispositif de détection de gaz à très forte sensibilité basé sur un résonateur de Hemholtz C. Risser, V. Zéninari, B. Parvitte, Brevet Français n° FR20150060724, Publication n° FR 3 042 867 (A1), (2017) https://bases-brevets.inpi.fr/fr/document/FR3042867.html

[120] Procédé et dispositif de détection de traces de gaz multiples V. Zéninari, B. Parvitte, L. Joly, G. Durry, R. Le Loarer, J. C. Garcia, R. Hamelin Brevet Français n° FR20100055954, Publication n° FR 2 963 102 (B1), (2017) https://patents.google.com/patent/FR2963102B1/en

[119] Dispositif de détection de gaz à très forte sensibilité basé sur un résonateur de Hemholtz C. Risser, V. Zéninari, B. Parvitte, Brevet Français n° FR20150060724, Publication n° FR 3 042 867 (B1), (2017) https://patents.google.com/patent/FR3042867B1

[118] Photoacoustic gas sensor with a Helmholtz cell M. Brun, S. Nicoletti, B. Parvitte, V. Zéninari Brevet US 13/450,551, Publication US patent n° US 9551829 (B2), (2017) https://patents.google.com/patent/US9551829

[117] Dispositif d’analyse de gaz à très forte sensibilité V. Zéninari, B. Parvitte, R. Vallon, C. Risser, L. Colin, J. C. Garcia, Brevet Français n° FR 3017950 (B1) (2017), https://patents.google.com/patent/FR3017950B1/

[116] Multi-gas sensing with quantum cascade laser array in the mid-infrared region, L. Bizet, R. Vallon, B. Parvitte, M. Brun, G. Maisons, M. Carras, V. Zéninari, Applied Physics B, pp. 123-145 (2017), https://doi.org/10.1007/s00340-017-6716-9

2016

[115] Miniaturized differential Helmholtz resonators for photoacoustic trace gas detection, J. Rouxel, J.-G. Coutard, S. Gidon, O. Lartigue, S. Nicoletti, B. Parvitte, R. Vallon, V. Zéninari, A. Glière, Sensors & Actuators B : Chemical, 236, pp. 1104-1110 (2016), https://doi.org/10.1016/j.snb.2016.06.074

[114] Simulation and design of compact Helmholtz photoacoustic cells for atmospheric gas sensing, B. Parvitte, R. Vallon, V. Zéninari, Optics Infobase Conference papers - Imaging and Applied Optics, 3 pages (2016), https://doi.org/10.1364/3D.2016.JT3A.9

[113] Line profile study of the R6 multicomponent of CH4 around 1.6 µm for the French-German climate mission MERLIN, V. Zéninari, R. Vallon, B. Parvitte, T. Delahaye, H. Tran, Optics Infobase Conference papers - Imaging and Applied Optics, 3 pages (2016), https://doi.org/10.1364/3D.2016.JT3A.13

[112] External cavity coherent quantum cascade laser array, R. Vallon, B. Parvitte, L. Bizet, G.M. De Naurois, B. Simozrag, G. Maisons, M. Carras, V. Zéninari, Infrared Physics and Technology, 76, pp. 415-420 (2016), https://doi.org/10.1016/j.infrared.2016.03.013

[111] Photoacoustic detection of methane in large concentrations with a Helmholtz sensor: Simulation and experimentation, V. Zéninari, R. Vallon, C. Risser, B. Parvitte, International Journal of Thermophysics, 37, 1, pp. 1-11 (2016), https://doi.org/10.1007/s10765-015-2018-9

2015

[110] Optimization and complete characterization of a photoacoustic gas detector C. Risser, B. Parvitte, R. Vallon, V. Zéninari Applied Physics B, 118, 2, pp. 319-326 (2015) https://doi.org/10.1007/s00340-014-5988-6

[109] Dispositif d’analyse de gaz à très forte sensibilité V. Zéninari, B. Parvitte, R. Vallon, C. Risser, L. Colin, J. C. Garcia, Brevet Français n° FR 3017950 (A1) (2015), https://bases-brevets.inpi.fr/fr/document/FR3017950.html

[108] Simulation and design of compact photoacoustic gas sensors, B. Parvitte, C. Risser, R. Vallon, M. Carras, V. Zéninari Optics InfoBase Conference Papers – CLEO/EUROPE – EQEC 2015 (2015) https://www.scopus.com/record/display.uri?eid=2-s2.0-85019522215&origin=resultslist

[107] Development of a Miniaturized Differential Photoacoustic Gas Sensor, J. Rouxel, J.-G. Coutard, S. Gidon, O. Lartigue, S. Nicoletti, B. Parvitte, R. Vallon, V. Zéninari, A. Glière, Procedia Engineering, 120, pp. 396–399 (2015), https://doi.org/10.1016/j.proeng.2015.08.650

2014

[106] Challenges in the Design and Fabrication of a Lab-on-a-Chip Photoacoustic Gas Sensor A.Glière, J. Rouxel, M. Brun, B. Parvitte, V. Zéninari, S. Nicoletti Sensors, 14, 1, pp. 957-974 (2014) https://doi.org/10.3390/s140100957

[105] Détecteur de gaz photoacoustique à cellule de Helmholtz M. Brun, S. Nicoletti,B. Parvitte, V. Zéninari Brevet Français n° FR20110053471, Publication n° FR 2974413 (B1), (2014) https://patents.google.com/patent/FR2974413B1/en

[104] Dispositif de détection de trace de gaz V. Zéninari, L. Joly, B. Parvitte, T. Decarpenterie, G. Durry, R. Le Loarer Brevet Français n° FR20110056650, Publication n° FR 2 978 247 (B1), (2014) https://patents.google.com/patent/F2978247B1

[103] Coherent quantum cascade laser array at 8.2 µm in extended-cavity system R. Vallon, B. Parvitte, G. Maisons, M. Carras, V. Zéninari Optics InfoBase Conference Papers – LACSEA 2014 – 107131 (2014) https://doi.org/10.1364/LACSEA.2014.LM4D.2

[102] Complete characterization of trace gas photoacoustic sensors using a finite element method B. Parvitte, C. Risser, R. Vallon, V. Zéninari Optics InfoBase Conference Papers – Applied Industrial Optics: Spectroscopy, Imaging and Metrology (2014) https://doi.org/10.1364/AIO.2014.JTu4A.32

[101] Simulations and developments of Si-integrated photoacoustic cells for the optical sensing of the atmosphereV. Zéninari, J. Rouxel, B. Parvitte, R. Vallon, M. Brun, S. Nicoletti, A.Glière Optics InfoBase Conference Papers – Applied Industrial Optics: Spectroscopy, Imaging and Metrology (2014) https://doi.org/10.1364/AIO.2014.JTu4A.44

[100] Development of an external-cavity quantum cascade laser spectrometer at 7.5 µm and applications to gas detection D. Mammez, R. Vallon, B. Parvitte, M.-H. Mammez, M. Carras, V. Zéninari Applied Physics B, 116, 4, pp. 951-958 (2014) https://doi.org/10.1007/s00340-014-5782-5

2013

[99] Quantitative simulation of photoacoustic signals using finite element modelling software B. Parvitte, C. Risser, R. Vallon, V. Zéninari Applied Physics B, 111, 3, pp. 383-389 (2013) https://doi.org/10.1007/s00340-013-5344-2

[98] Device for detecting trace gases V. Zéninari, L. Joly, B. Parvitte, T. Decarpenterie, G. Durry, R. Le Loarer Brevet International n°PCT/EP2012/063897, Publication n° WO 2013 010984 (A3), (2013) https://patents.google.com/patent/WO2013010984A3/fr

[97] Photoacoustic gas sensing with a commercial external-cavity quantum cascade laser at 10.5 μm D. Mammez, C. Stoeffler, J. Cousin, R. Vallon, M.-H. Mammez, L. Joly, B. Parvitte, V. Zéninari Infrared Physics and Technology, 61, pp. 14-19 (2013) https://doi.org/10.1016/j.infrared.2013.07.002

[96] Photoacoustic gas sensor with Helmholtz cell M. Brun, S. Nicoletti, B. Parvitte, V. Zéninari Brevet Européen n° EP20120163300, Publication n° EP 2 515 096 (B1), (2012) https://patents.google.com/patent/EP2515096B1/en

[95] A coupled model for the simulation of miniaturised and integrated photoacoustic gas detector A. Glière, J. Rouxel, B. Parvitte, S. Boutami, V. Zéninari International Journal of Thermophysics, 34, 11, pp. 2119-2135 (2013) https://doi.org/10.1007/s10765-013-1534-8

[94] A coherent quantum cascade laser array for high power emission R. Vallon, B. Parvitte, D. Mammez, G.-M. De Naurois, M. Carras, V. Zéninari Optics InfoBase Conference Papers – CLEO/EUROPE – 6800810 (2013) https://doi.org/10.1109/CLEOE-IQEC.2013.6800810

[93] Method and device for detecting trace amounts of many gases V. Zéninari, B. Parvitte, L. Joly, G. Durry, R. Le Loarer, J. C. Garcia, R. Hamelin Brevet Européen n° EP20110752269 20110721, Publication n° EP 2 596 331 (A1), (2013) https://patents.google.com/patent/EP2596331A1/en

[92] Method and device for detecting trace amounts of many gases V. Zéninari, B. Parvitte, L. Joly, G. Durry, R. Le Loarer, J. C. Garcia, R. Hamelin Brevet US 13/811,364, Publication n° US 2013 0205871 (A1), (2013) https://patents.google.com/patent/US20130205871

[91] Method and device for emitting a laser beam in a housing V. Zéninari, B. Parvitte, L. Joly, V. Lecocq, G. Durry,R. Hamelin, R. Le Loarer Brevet Européen n° EP20110811105, Publication n° EP 2 652 845 (A1), (2013) https://patents.google.com/patent/EP2652845A1/en

[90] Method and device for emitting a laser beam in a housing V. Zéninari, B. Parvitte, L. Joly, V. Lecocq, G. Durry,R. Hamelin, R. Le Loarer Brevet US 13/994,996, Publication n° US 2013 0287053 (A1), (2013) https://patents.google.com/patent/US20130287053

[89] Dispositif de détection de trace de gaz V. Zéninari, L. Joly, B. Parvitte, T. Decarpenterie, G. Durry, R. Le Loarer Brevet Français n° FR20110056650, Publication n° FR 2 978 247 (A1), (2013) https://bases-brevets.inpi.fr/fr/document/FR2978247.html

[88] Device for detecting trace gases V. Zéninari, L. Joly, B. Parvitte, T. Decarpenterie, G. Durry, R. Le Loarer Brevet International n°PCT/EP2012/063897, Publication n° WO 2013 010984 (A2), (2013) https://patentscope.wipo.int/search/en/detail.jsf?docId=WO2013010984

[87] Optical waveguide M. Brun, S. Nicoletti,B. Parvitte, V. Zéninari Brevet Européen n° EP20130175136, Publication n° EP 2 662 714 (A1), (2013) https://patents.google.com/patent/EP2662714A1/en

[86] Optical waveguide having a varying index gradient M. Brun, S. Nicoletti,B. Parvitte, V. Zéninari Brevet US 13/952,472, Publication n° US 2013 0315547 (A1), (2013) https://patents.google.com/patent/US20130315547/en

2012

[85] Self-induced pressure shift and temperature dependence measurements of CO2 at 2.05 micron with a tunable diode laser spectrometer J.S. Li, G. Durry, J. Cousin, L. Joly, B. Parvitte, V. Zéninari Spectrochimica Acta Part A, 85, pp. 74-78 (2012) https://doi.org/10.1016/j.saa.2011.09.016

[84] Unraveling the evolving nature of gaseous and dissolved carbon dioxide in champagne wines: A state-of-the-art review, from the bottle to the tasting glass G. Liger-Belair, G. Polidori, V. Zéninari Analytica Chimica Acta, 732, pp. 1-15 (2012) https://doi.org/10.1016/j.aca.2011.10.007

[83] Procédé et dispositif d’émission d’un faisceau laser dans un boitier B. Parvitte, L. Joly, V. Lecocq, G. Durry, V. Zéninari, R. Hamelin, R. Le Loarer Brevet Français n° FR20100060587, Publication n° FR 2 969 315 (B1),(2012) https://patents.google.com/patent/FR2969315B1

[82] Wavelet denoising for infrared laser spectroscopy and gas detection I. Mappe-Fogaing, L. Joly, N. Dumelie, J.S. Li, G. Durry, B. Parvitte, V. Zéninari Applied Spectroscopy, 66, 6, pp. 700-710 (2012) https://doi.org/10.1366/11-06459

[81] Modelization of photoacoustic trace gases sensors B. Parvitte, C. Risser, R. Vallon, V. Zéninari Proceedings of the 2012 Comsol Conference in Milan, pp. 1-5 (2012) http://www.comsol.com/paper/download/151553/parvitte_paper.pdf

[80] Carbon dioxide and ethanol release from champagne glasses under standard tasting conditions G. Liger-Belair, F. Beaumont, M. Bourget, H. Pron, B. Parvitte, V. Zéninari, G. Polidori, C. Cilindre Advances in Food and Nutrition Research, 67, pp. 289-340 (2012) https://doi.org/10.1016/B978-0-12-394598-3.00007-1

[79] Procédé et dispositif de détection de traces de gaz multiples V. Zéninari, B. Parvitte, L. Joly, G. Durry, R. Le Loarer, J. C. Garcia, R. Hamelin Brevet Français n° FR20100055954, Publication n° FR 2 963 102 (A1), (2012) https://bases-brevets.inpi.fr/fr/document/FR2963102.html

[78] Method and device for detecting trace amounts of many gases V. Zéninari, B. Parvitte, L. Joly, G. Durry, R. Le Loarer, J. C. Garcia, R. Hamelin Brevet International n°PCT/FR2011/051766, Publication n° WO 2012 010806 (A1), (2012) https://patentscope.wipo.int/search/en/detail.jsf?docId=WO2012010806

[77] Procédé et dispositif d’émission d’un faisceau laser dans un boitier B. Parvitte, L. Joly, V. Lecocq, G. Durry, V. Zéninari,R. Hamelin, R. Le Loarer Brevet Français n° FR20100060587, Publication n° FR 2 969 315 (A1),(2012) https://bases-brevets.inpi.fr/fr/document/FR2969315.html

[76] Method and device for emitting a laser beam in a housing V. Zéninari, B. Parvitte, L. Joly, V. Lecocq, G. Durry,R. Hamelin, R. Le Loarer Brevet International n°PCT/FR2011/052970, Publication n° WO 2012 080652 (A1), (2012) https://patentscope.wipo.int/search/en/detail.jsf?docId=WO2012080652

[75] Détecteur de gaz photoacoustique à cellule de Helmholtz M. Brun, S. Nicoletti,B. Parvitte, V. Zéninari Brevet Français n° FR20110053471, Publication n° FR 2974413 (A1), (2012) https://bases-brevets.inpi.fr/fr/document/FR2974413.html

[74] Photoacoustic gas sensor with Helmholtz cell M. Brun, S. Nicoletti,B. Parvitte, V. Zéninari Brevet Européen n° EP20120163300, Publication n° EP 2 515 096 (A1), (2012) https://data.epo.org/publication-server/rest/v1.0/publication-dates/20121024/patents/EP2515096NWA1/document.pdf

[73] Photoacoustic gas sensor with a Helmholtz cell M. Brun, S. Nicoletti,B. Parvitte, V. Zéninari Brevet US 13/450,551, Publication US patent n° US 2012 0266655 (A1), (2012) https://patents.google.com/patent/US20120266655

2011

[72] Continuous-wave quantum cascade lasers absorption spectrometers for trace gas detection in the atmosphere L. Joly, V. Zeninari, T. Decarpenterie, J. Cousin, B. Grouiez, D. Mammez, G. Durry, M. Carras, X. Marcadet, B. Parvitte Laser Physics, 21, 4, pp. 805-812 (2011) https://doi.org/10.1134/S1054660X11070127

[71] Study of a thermophysical system with two time constants using an open photoacoustic cell B. Bonno, V. Zéninari, L. Joly, B. Parvitte International Journal of Thermophysics, 32, 3, pp. 630-640 (2011) https://doi.org/10.1007/s10765-011-0918-x

[70] Tunable diode laser measurement of pressure-induced shift coefficients of CO2 around 2.05 μm for Lidar application J.S. Li, G. Durry, J. Cousin, L. Joly, B. Parvitte, P.H. Flamant, F. Gibert, V. Zéninari Journal of Quantitative Spectroscopy and Radiative Transfer, 112, 9, pp. 1411-1419 (2011) https://doi.org/10.1016/j.jqsrt.2011.01.030

[69] Development of a versatile atmospheric N2O sensor based on quantum cascade laser technology at 4.5 µm L. Joly, T. Decarpenterie, N. Dumelié, X. Thomas, I. Mappe-Fogaing, J. Cousin, D. Mammez, R. Vallon, G. Durry, B. Parvitte, M. Carras, X. Marcadet, V. Zéninari Applied Physics B, 103, 3, pp. 717-723 (2011) https://doi.org/10.1007/s00340-011-4522-3

2010

[68] Photoacoustic spectroscopy for trace gas detection with cryogenic and room-temperature continuous wave quantum cascade lasers V. Zéninari, A. Grossel, L. Joly, T. Decarpenterie, B. Grouiez, B. Bonno, B. Parvitte Central European Journal of Physics, 8, 2, pp. 194-201 (2010) https://doi.org/10.2478/s11534-009-0042-8

[67] Continuous-wave Distributed FeedBack Quantum Cascade Laser Spectrometers for the study of the Atmosphere V. Zéninari, B. Parvitte, B. Grouiez, L. Joly Advances in Laser and Optics Research, Vol. 4, Nova Publisher Ed.; Chapitre 2, pp. 49-82, ISBN: 978-1-60741-854-2, (2010) https://www.scopus.com/inward/record.uri?eid=2-s2.0-85049243917&partnerID=40&md5=0ea0241dc70115bc0329b20c2ab2756a",Book Chapter,,Scopus,2-s2.0-85049243917

[66] Near infrared diode laser spectroscopy of C2H2, H2O, CO2 and their isotopologues and the application to TDLAS, a tunable diode laser spectrometer for the Martian PHOBOS-Grunt space mission. G. Durry, J.S. Li, I. Vinogradov, A. Titov, A.V. Kalyuzhny, L. Joly, J. Cousin, T. Decarpenterie, N. Amarouche, X. Liu, B. Parvitte, O. Korablev, M. Gerasimov, V. Zéninari Applied Physics B, 99, 1-2, pp. 339-351 (2010) https://doi.org/10.1007/s00340-010-3924-y

[65] Self-broadening coefficients and positions of acetylene around 1.533 µm studied by high-resolution diode laser absorption spectrometry J.S. Li, G. Durry, J. Cousin, L. Joly, B. Parvitte, V. Zéninari Journal of Quantitative Spectroscopy and Radiative Transfer, 111, 15, pp. 2332-2340 (2010) https://doi.org/10.1016/j.jqsrt.2010.04.025

[64] Pulsed quantum cascade laser spectroscopy with intermediate-size pulses: application to NH3 in the 10 µm region B. Grouiez, V. Zéninari, L. Joly, B. Parvitte Applied Physics B, 100, 2, pp. 265-273 (2010) https://doi.org/10.1007/s00340-010-3993-y

2009

[63] Intercomparison of 2µm-Heterodyne Differential Absorption Lidar, Laser Diode Spectrometer, LICOR NDIR analyzer and flasks measurements of near-ground atmospheric CO2 mixing ratio F.Gibert, L. Joly, I. XuEref-Rémy, M. Schmidt, A. Royer, P.H. Flamant, M. Ramonet, B. Parvitte, G. Durry, V. Zéninari Spectrochimica Acta Part A, 71, 5, pp. 1914-1921 (2009) https://doi.org/10.1016/j.saa.2008.07.010

[62] Development of a compact CO2 sensor based on near-infrared laser technology for enological applications M. Mulier, V. Zéninari, L. Joly, T. Decarpenterie, B. Parvitte, P. Jeandet, G. Liger-Belair Applied Physics B: Lasers and Optics, 94, 4, pp. 725–733 (2009) https://doi.org/10.1007/s00340-009-3389-z

[61] Alternative method for gas detection using pulsed quantum cascade laser spectrometers B. Grouiez, B. Parvitte, L. Joly, V. Zéninari Optics Letters, 34, 2, pp. 181-183 (2009) https://doi.org/10.1364/OL.34.000181

[60] Laser diode absorption spectroscopy for accurate CO2 line parameters at 2 µm. Consequences for space-based DIAL measurements and potential biases L. Joly, F. Marnas, F. Gibert, D. Bruneau, B. Grouiez, P.H. Flamant, G. Durry, N. Dumelie, B. Parvitte, V. Zéninari Applied Optics, 48, 29, pp. 5475-5483 (2009) https://doi.org/10.1364/AO.48.005475

[59] Focus sur la physique des bulles et la chimie de la mousse du Champagne P. Jeandet, C. Cilindre, R. Marchal, S. Villaume, A. Conreux, M. Parmentier, Y. Vasserot, V. Zeninari, R. Gougeon, P. Schmitt-Kopplin, G. Polidori, G. Liger-Belair La Champagne Viticole, 750, pp. 42-46 (2009) http://www.helmholtz-muenchen.de/fileadmin/IOEC/IMG/biogeochemistry/press/December__Champagne/Champagne_Viticole_750_2009_42_Focus_sur_la_physique_des_bulles_et_la_chimie_de_la_mousse_de_Champagne.pdf

[58] Diode laser spectroscopy of two acetylene isotopologues (12C2H2, 13C12CH2) in the 1.533 µm region for the PHOBOS-Grunt space mission J.S. Li, L. Joly, J. Cousin, B. Parvitte, B. Bonno, V. Zéninari, G. Durry Spectrochimica Acta Part A, 74, 5, pp. 1204-1208 (2009) https://doi.org/10.1016/j.saa.2009.09.037

2008

[57] Laser diode spectroscopy of the H2O isotopologues in the 2.64 micron region for the in situ monitoring of the Martian atmosphere G. Durry, L. Joly, T. Le Barbu, B. Parvitte, V. Zéninari Infrared Physics and Technology, 51, 3, pp. 229–235 (2008) https://doi.org/10.1016/j.infrared.2007.05.004

[56] Comparison of a Quantum Cascade Laser used in both cw and pulsed mode. Application to the study of SO2 lines around 9 µm B. Grouiez, B. Parvitte, L. Joly, D. Courtois, V. Zéninari Applied Physics B: Lasers and Optics, 90, 2, pp. 177–186 (2008) https://doi.org/10.1007/s00340-007-2857-6

[55] A complete study of line parameters of CO2 around 4845 cm-1 for Lidar applications L. Joly, F. Gibert, B. Grouiez, A. Grossel, B. Parvitte, G. Durry, V. Zéninari Journal of Quantitative Spectroscopy and Radiative Transfer, 109, 3, pp. 426-434 (2008) https://doi.org/10.1007/s00340-007-2884-3

[54] Development of a spectrometer using a cw DFB quantum cascade laser operating at room temperature for the simultaneous analysis of N2O and CH4 in the Earth’s atmosphere L. Joly, C. Robert, B. Parvitte, V. Catoire, G. Durry, G. Richard, B. Nicoullaud, V. Zéninari Applied Optics, 47, 9, pp. 1206-1214 (2008) https://doi.org/10.1364/AO.47.001206

[53] Laser diode spectroscopy of H2O at 2.63 micron for atmospheric applications G. Durry, N. Amarouche, L. Joly, X. Liu, B. Parvitte, V. Zéninari Applied Physics B: Lasers and Optics, 90, 3-4, pp. 573–580 (2008) https://doi.org/10.1007/s00340-007-2884-3

[52] Quantum cascade laser spectroscopy of N2O in the 7.9 µm region for the in situ monitoring of the atmosphere A. Grossel, V. Zéninari, B. Parvitte, L. Joly, G. Durry, D. Courtois Journal of Quantitative Spectroscopy and Radiative Transfer, 109, 10, pp. 1845-1855 (2008) https://doi.org/10.1016/j.jqsrt.2007.12.002

[51] Spectroscopy: Quantum-cascade-laser spectrometer measures gases in atmosphere V.C. Coffey, V. Zéninari et al Laser Focus World, 44, 6, pp. 31-33 (2008) https://www.laserfocusworld.com/test-measurement/test-measurement/article/16563596/spectroscopy-quantumcascadelaser-spectrometer-measures-gases-in-atmosphere

[50] A case study of CO2, CO and particles content evolution in the suburban atmospheric boundary layer using a 2-μm Doppler DIAL, a 1-µm backscatter lidar and an array of in-situ sensors F.Gibert, I. XuEref-Rémy, L. Joly, M. Schmidt, J. Cuesta, K. J. Davis, M. Ramonet, P.H. Flamant, B. Parvitte, V. Zéninari Boundary-Layer Meteorology, 128, 3, pp. 381-401 (2008) https://doi.org/10.1007/s10546-008-9296-8

2007

[49] Study of SO2 line parameters with a quantum cascade laser spectrometer around 1090 cm-1. Comparison with theoretical calculations of the nu1 and nu1 + nu2 – nu2 bands of 32SO2 and the nu1 band of 34SO2 V. Zéninari, L. Joly, B. Grouiez, B. Parvitte, A. Barbe Journal of Quantitative Spectroscopy and Radiative Transfer, 105, 2, pp. 312-325 (2007) https://doi.org/10.1016/j.jqsrt.2006.11.006

[48] Spectrométrie photoacoustique ; Application à l’analyse des gaz V. Zéninari Techniques de l’Ingénieur, P2890, pp. 1-11 (2007) https://www.techniques-ingenieur.fr/base-documentaire/mesures-analyses-th1/spectrometries-42390210/spectrometrie-photoacoustique-p2890/

[47] Spectrométrie photoacoustique ; Application à l’analyse des gaz : Pour en savoir plus V. Zéninari Techniques de l’Ingénieur, Doc. P2890, pp. 1-2 (2007) https://www.techniques-ingenieur.fr/base-documentaire/mesures-analyses-th1/spectrometries-42390210/spectrometrie-photoacoustique-p2890/

[46] Photoacoustic detection of nitric oxide with a Helmholtz resonant quantum cascade laser sensor A. Grossel, V. Zéninari, B. Parvitte, L. Joly, G. Durry, D. Courtois Infrared Physics and Technology, 51, 2, pp. 95-101 (2007) https://doi.org/10.1016/j.infrared.2006.11.004

[45] Development of a compact CO2 sensor open to the atmosphere and based on near-infrared laser technology at 2.68 µm L. Joly, B. Parvitte, V. Zéninari, G. Durry Applied Physics B: Lasers and Optics, 86, 4, pp. 743-748 (2007) https://doi.org/10.1007/s00340-006-2568-4

[44] Spectrométrie laser infrarouge et détection de gaz à l’aide de lasers à cascade quantique A. Grossel, D. Courtois, V. Zéninari Bulletin POLOQ de la DGA, 2007-1, pp. 75-82 (2007) http://www.defense.gouv.fr/dga

[43] Optimization of a compact photoacoustic quantum cascade laser spectrometer for atmospheric flux measurements: application to the detection of methane and nitrous oxide A. Grossel, V. Zéninari, B. Parvitte, L. Joly, D. Courtois Applied Physics B: Lasers and Optics, 88, 3, pp. 483–492 (2007) https://doi.org/10.1007/s00340-007-2719-2

2006

[42] Water vapor isotope ratio measurements in air with a quantum cascade laser spectrometer L. Joly, V. Zéninari, B. Parvitte, D. Courtois, G. Durry Optics Letters, 31, 2, pp. 143-145 (2006) https://doi.org/10.1364/OL.31.000143

[41] Line strengths and self-broadening coefficients of carbon dioxide isotopologues (13CO2 and 18O12C16O) near 2.04µm for the in situ laser sensing of the Martian atmosphere T. Le Barbu, V. Zéninari, B. Parvitte, D. Courtois, G. Durry Journal of Quantitative Spectroscopy and Radiative Transfer, 98, 2, pp. 264-276 (2006) https://doi.org/10.1016/j.jqsrt.2005.05.089

[40] Diode laser spectroscopy of H2O and CO2 in the 1.877 µm region for the in situ monitoring of the Martian atmosphere T. Le Barbu, B. Parvitte, V. Zéninari, I. Vinogradov, O. Korablev, G. Durry Applied Physics B: Lasers and Optics, 82, 1, pp. 133-140, (2006) https://doi.org/10.1007/s00340-005-2020-1

[39] The absorption line profiles of H2O near 1.39 µm in binary mixtures with N2, O2, and H2 at low pressures Y.N. Ponomarev, I.V. Ptashnik, V. Zéninari, B. Parvitte, D. Courtois, G. Durry Optics and Spectroscopy, 100, 5, pp. 682-688 (2006) https://doi.org/10.1134/S0030400X06050079

[38] New improvements in methane detection using a Helmholtz resonant photoacoustic laser sensor: a comparison between near-IR diode lasers and mid-IR quantum cascade lasers A. Grossel, V. Zéninari, L. Joly, B. Parvitte, G. Durry, D. Courtois Spectrochimica Acta Part A, 63, 5, pp. 1021-1028 (2006) https://doi.org/10.1016/j.saa.2005.11.002

[37] A complete study of the line intensities of four bands of CO2 around 1.6 and 2.0 µm: A comparison between Fourier transform and diode laser measurements L. Régalia-Jarlot, V. Zéninari, B. Parvitte, A. Grossel, X. Thomas, P. Von Der Heyden, G. Durry Journal of Quantitative Spectroscopy and Radiative Transfer, 101, 2, pp. 325-336 (2006) https://doi.org/10.1016/j.jqsrt.2005.11.021

[36] A spectroscopic study of water vapor isotopologues H216O, H218O and HDO using a continuous wave DFB quantum cascade laser in the 6.7µm region for atmospheric applications L. Joly, B. Parvitte, V. Zéninari, D. Courtois, G. Durry Journal of Quantitative Spectroscopy and Radiative Transfer, 102, 2, pp. 129-138 (2006) https://doi.org/10.1016/j.jqsrt.2005.11.023

[35] Development of a compact instrument using fiber laser based Difference-Frequency Generation source for chemical gas detection J. Cousin, W. Chen, D. Boucher, S. Kassi, D. Romanini, V. Zéninari, B. Parvitte, D. Courtois IEEE Proc. Joint 31st Int. Conf. Inf. Mill. Waves and 14th Conf. THz Elec., p. 582 (2006) https://doi.org/10.1109/ICIMW.2006.368789

[34] Laboratory spectroscopic calibration of infrared tunable laser spectrometers for the in situ sensing of the Earth and Martian atmospheres V. Zéninari, B. Parvitte, L. Joly, T. Le Barbu, N. Amarouche, G. Durry Applied Physics B: Lasers and Optics, 85, 2-3, pp. 265-272 (2006) https://doi.org/10.1007/s00340-006-2331-x

2005

[33] Pressure-broadening coefficients and line strengths of H2O near 1.39 µm: Application to the in situ sensing of the middle atmosphere with balloonborne diode lasers G. Durry, V. Zéninari, B. Parvitte, T. Le Barbu, F. Lefèvre, J. Ovarlez, R.R. Gamache Journal of Quantitative Spectroscopy and Radiative Transfer, 94, 3-4, pp. 387-403 (2005) https://doi.org/10.1016/j.jqsrt.2004.09.033

2004

[32] Diode laser spectroscopy of CO2 in the 1.6 µm region for the in situ sensing of the middle atmosphere, I. Pouchet,V. Zéninari, B. Parvitte, G. Durry,Journal of Quantitative Spectroscopy and Radiative Transfer, 83, 3-4, pp. 619-628 (2004) https://doi.org/10.1016/S0022-4073(03)00108-0

[31] Measured and calculated parameters of water vapor line contour induced by hydrogen and helium pressure in the 1.4 µm region V. Zéninari, B. Parvitte, D. Courtois, I. Pouchet, G. Durry, N.N. Lavrentieva, Y.N. Ponomarev SPIE Proc. – The International Society for Optical Engineering, 5311, pp. 234-239 (2004) https://doi.org/10.1117/12.545682

[30] Infrared laser heterodyne systems B. Parvitte, V. Zéninari, C. Thiébeaux, A. Delahaigue, D. Courtois Spectrochimica Acta Part A, 60, 5, pp. 1193-1213 (2004) https://doi.org/10.1016/j.saa.2003.07.006

[29] In situ sensing of atmospheric CO2 with laser diodes near 2.05µm: a spectroscopic study V. Zéninari, A. Vicet, B. Parvitte, L. Joly, G. Durry Infrared Physics and Technology, 45, 3, pp. 229-237 (2004) https://doi.org/10.1016/j.infrared.2003.11.004

[28] Preliminary results of heterodyne detection with quantum cascade lasers in the 9.1µm region B. Parvitte, L. Joly, V. Zéninari, D. Courtois Spectrochimica Acta Part A, 60, 14, pp. 3285-3290 (2004) https://doi.org/10.1016/j.saa.2003.12.053

[27] In situ sensing of the middle atmosphere with balloonborne near-IR laser diodes G. Durry, N. Amarouche, V. Zéninari, B. Parvitte, T. Le Barbu, J. Ovarlez Spectrochimica Acta Part A, 60, 14, pp. 3371-3379 (2004) https://doi.org/10.1016/j.saa.2003.11.050

[26] Pressure broadening and shift coefficients of H2O due to perturbation by N2, O2, H2 and He in the 1.39 µm region: experiment and calculations V. Zéninari, B. Parvitte, D. Courtois, N.N. Lavrentieva, Y.N. Ponomarev, G. Durry Molecular Physics, 102, 16-17, pp. 1697-1706 (2004) https://doi.org/10.1080/00268970412331287133

2003

[25] Methane detection on the sub-ppm level with a near-infrared diode laser photoacoustic sensor, V. Zéninari, B. Parvitte, D.Courtois, V.A. Kapitanov, Y.N. Ponomarev, Infrared Physics and Technology, 44, 4, pp. 253-261 (2003) https://doi.org/10.1016/S1350-4495(03)00135-X

[24] Dispositif de détection de gaz, V. Zéninari, B. Parvitte, D. Courtois, V.A. Kapitanov, Y.N. Ponomarev, Brevet Français n° 00 12757, Publication n° FR 2 815 122 (B1), (2003) https://patents.google.com/patent/FR2815122B1/en

[23] Pressure lineshift and broadening coefficient of H2O by hydrogen and helium in the 1.39µm region with a tunable diode laser spectrometer, V. Zéninari,B. Parvitte, D. Courtois, I. Pouchet, G. Durry, Y.N. Ponomarev, Atmospheric and Oceanic Optics, 16, 3, pp. 189-192 (2003) http://ao.iao.ru/en/content/vol.16-2003/iss.03/?&annot=8

[22] Gas detection device,V. Zéninari, B. Parvitte, D. Courtois, V.A. Kapitanov, Y.N. Ponomarev, Brevet International n°PCT/FR2002/001155, Publication n° WO 2003 083455 (A1), (2003) https://patentscope.wipo.int/search/en/detail.jsf?docId=WO2003083455

[21] Spectroscopic study of the nu1 band of SO2 using a cw DFB QCL at 9.1µm, L. Joly, V. Zéninari, B. Parvitte, D. Weidmann, D. Courtois, Y. Bonetti, T. Aellen, M. Beck, J. Faist, D. Hofstetter, Applied Physics B: Lasers and Optics, 77, 6-7, pp. 703-706 (2003), https://doi.org/10.1007/s00340-003-1310-8

[20] Gas detection device,V. Zéninari, B. Parvitte, D. Courtois, V.A. Kapitanov, Y.N. Ponomarev, Brevet Australien n° 20020307967 20020403, Publication n° AU 2002 307967 (A1), (2003), https://patents.google.com/patent/AU2002307967A1/en

2002

[19] Diode laser spectroscopy of H2O in the 7165-7185 cm-1 range for atmospheric applications, B. Parvitte, V. Zéninari, I. Pouchet, G. Durry, Journal of Quantitative Spectroscopy and Radiative Transfer, 75, 4, pp. 493-505 (2002) https://doi.org/10.1016/S0022-4073(02)00033-X

[18] Optimisationof photoacoustic resonant cells with commercial microphones for diode laser gas detection, V.A. Kapitanov, V. Zéninari, B. Parvitte, D. Courtois, Y.N. Ponomarev, Spectrochimica Acta Part A, 58, 11, pp. 2397-2404 (2002) https://doi.org/10.1016/S1386-1425(02)00054-9

[17] In situ measurement of H2O and CH4 with telecommunication laser diodes in the lower stratosphere: dehydration and indication of a tropical air intrusion at mid-latitudes, G. Durry, A. Hauchecorne, J. Ovarlez, H. Ovarlez, I. Pouchet, V. Zéninari, B. Parvitte, Journal of Atmospheric Chemistry, 43, 3, pp. 175-194 (2002) https://doi.org/10.1023/A:1020674208207

[16] Differential Helmholtz resonant photoacoustic cell for spectroscopy and gas analysis with room temperature diode lasers, K. Song, H.K. Cha, V.A. Kapitanov, Y.N. Ponomarev, A.P. Rostov, D. Courtois, B. Parvitte, V. Zéninari, Applied Physics B: Lasers and Optics, 75, 2-3, pp. 215-227 (2002) https://doi.org/10.1007/s00340-002-1000-y

[15] Detection and analysis of atmospheric gases by infrared laser spectroscopy D. Courtois, A. Delahaigue, B. Parvitte, C. Thiébeaux, D. Weidmann, V. Zéninari Recent Research Developments in Applied Spectroscopy Vol. 4, Research Signpost Ed., ISBN 81-7736-197-X, pp. 1-22 (2002) http://www.ressign.com/home.aspx

[14] Dispositif de détection de gaz, V. Zéninari, B. Parvitte, D. Courtois, V.A. Kapitanov, Y.N. Ponomarev, Brevet Français n° 00 12757, Publication n° FR 2 815 122 (A1), (2002) https://bases-brevets.inpi.fr/fr/document/FR2815122.html

2001

[13] Measurements of air and noble gases broadening and shift coefficients of the methane R3 triplet of 2nu3band, V. Zéninari, B. Parvitte, D. Courtois, V.A. Kapitanov, Y.N. Ponomarev, Applied Physics B: Lasers and Optics, 72, 8, pp. 953–959 (2001) https://doi.org/10.1007/s003400100586

2000

[12] Photoacoustic measurements of the vibrational relaxation of the selectively excited ozone (nu3) molecule in pure ozone and its binary mixtures with O2, N2, and noble gases, V. Zéninari, B.A. Tikhomirov, Y.N. Ponomarev, D. Courtois , Journal of Chemical Physics, 112, 4, pp. 1835-1843 (2000) https://doi.org/10.1063/1.480747

1999

[11] Design and characteristics of a differential Helmholtz resonant photoacoustic cell for infrared gas detection, V. Zéninari, V.A. Kapitanov, D. Courtois, Y.N. Ponomarev, Infrared Physics and Technology, 40, 1, pp. 1-23 (1999) https://doi.org/10.1016/S1350-4495(98)00038-3

[10] Helmholtz resonant photoacoustic cell for spectroscopy of weakly absorbing gases and gas analysis, V.A. Kapitanov, V. Zéninari, D. Courtois, Y.N. Ponomarev, Atmospheric and Oceanic Optics, 12, 10, pp. 928-940 (1999) http://ao.iao.ru/en/content/vol.12-1999/iss.10/?&annot=1024

[9] Optical acoustic gas analyzer, V.A. Kapitanov, Y.N. Ponomarev, D. Courtois, V. Zéninari, Brevet Russe n° RU 10 461 (U1) (1999) https://www1.fips.ru/en/

1998

[8] Tunable diode laser spectrometer apparatus function, M.R. De Backer-Barilly, B. Parvitte, X. Thomas, V. Zéninari, D. Courtois, Journal of Quantitative Spectroscopy and Radiative Transfer, 59, 3-5, pp. 345-352 (1998) https://doi.org/10.1016/S0022-4073(97)00110-6

[7] Preliminary results on photoacoustic study of the relaxation of vibrationally excited ozone (nu3), V. Zéninari, B.A. Tikhomirov, Y. N. Ponomarev, D. Courtois Journal of Quantitative Spectroscopy and Radiative Transfer, 59, 3-5, pp. 369-375 (1998) https://doi.org/10.1016/S0022-4073(97)00108-8

[6] Linewidth narrowing of 10 µm diode lasers by external feedback, B. Parvitte, V. Zéninari, D. Courtois, A. Delahaigue, C. Thiébeaux, T. Beyer, H. Schlegelmich, A. Lambrecht, M. Tacke, Journal of Quantitative Spectroscopy and Radiative Transfer, 59, 3-5, pp. 361-368 (1998) https://doi.org/10.1016/S0022-4073(97)00132-5

[5] Vibrational kinetics of the ozone molecule in binary mixtures with noble gases, O.Y. Nikiforova, Y.N. Ponomarev, B.A. Tikhomirov, V. Zéninari, D. Courtois, SPIE Proc. – The International Society for Optical Engineering, 3583, pp. 75-79 (1998) https://doi.org/10.1117/12.336993

[4] An instrument for atmospheric detection of NH3 by laser heterodyne radiometry, V. Zéninari, B. Parvitte, D. Courtois, A. Delahaigue, C. Thiébeaux, Journal of Quantitative Spectroscopy and Radiative Transfer, 59, 3-5, pp. 353-359 (1998) https://doi.org/10.1016/S0022-4073(97)00119-2

1997

[3] Study of vibrational relaxation of O3 (001) using the photoacoustic technique , D. Courtois, B. Parvitte, Y.N. Ponomarev, O.V. Tikhomirova, B.A. Tikhomirov, V. Zéninari, Chinese Journal of Acoustics, 16, 4, pp. 372-376 (1997) http://caod.oriprobe.com/articles/34770802/Study_of_vibrational_relaxation_of_O_sub_3__sub___001_using_photoacous.htm

1996

[2] Absolute intensity measurement of nu3 ozone line at saturated vapor pressure with a laser heterodyne spectrometer, V. Zéninari, M.R. De Backer, B. Parvitte, D. Courtois, Applied Physics B: Lasers and Optics, 63, 2, pp. 179-183 (1996) https://doi.org/10.1007/BF01095270

1995

[1] Precise and absolute intensity measurement of the nu3 (10,5,6)-(9,5,5) ozone line with high resolution spectrometer, M.R. De Backer, B. Parvitte, V. Zéninari, D. Courtois, Journal of Quantitative Spectroscopy and Radiative Transfer, 54, 6, pp. 1009-1018 (1995) https://doi.org/10.1016/0022-4073(95)00124-4