Athospheric oxidation processes of partially fluorinated ethers

Ziel

This project is concerned with the study of the reaction kinetics of hydroxyl radicals, chlorine atoms, and nitrate radicals with a series of partially fluorinated ethers, which may be used as potential alternatives of chlorofluorocarbons (CFCs). The gas phase reactions of chlorine atoms, hydroxyl and nitrate radicals with partially fluorinated ethers, such as CF2HOCHF2, CF3OCHF2, CF3CH2OCH3, CF3CH2OCHF2, CF3CH2OCH2CF3, and CHF2CF2OCH2CH=CH2, will be studied. They do not contain chlorine or bromine that could be released and enter the ozone destruction cycle. The degree of fluorination in these molecules is expected to affect the rate constants and the temperature dependence of these reactions. The main objectives concerning the atmospheric processes of partially fluorinated ethers are:
- Measure the reaction rate constants of hydroxyl radicals, chlorine atoms, and nitrate radicals with a series of partially fluorinated ethers in the gas phase and over the temperature range 250-370 K.
- Identify the primary reaction channels and the position of the initial attack on partially fluorinated ethers by OH, Cl, and NO3 radicals. This will provide information about the initial steps in the atmospheric degradation of the partially fluorinated ethers.
- Evaluate the degradation processes of the partially fluorinated ethers under atmospheric conditions.

This project will be carry out by using three experimental methods:
1.The Very Low Pressure Reactor technique will be used to study the reaction of Cl atoms with partially
fluorinated ethers. This is a technique for the study of fast radical-molecule reactions in the gas phase, without
complications from secondary reactions, and provides accurate absolute rate constant measurements over a wide
range of temperatures. Cl atoms are produced in a microwave discharge of a Cl2/He mixture. Reaction takes
place at very low pressures in a cylindrical Knudsen reactor coated with Teflon. Reactants and products are
continuously discharged into a two-stage vacuum system, and form an effusive molecular beam that is modulated
by a tuning fork chopper. Chemical analysis and estimation of the concentrations of both reactants and products
is done by a quadrupole mass spectrometer.
2. The Relative Rate technique will be used to study the reaction of OH radicals with partially fluorinated
ethers. This technique provides accurate relative rate constant measurements for radical-molecule reactions, in
relation to the known rate constant of a reference compound. OH radicals are produced via photolysis of O3 in
the presence of water vapor, and reactant and reference compounds are monitored by gas chromatography and
FTIR spectroscopy. Product distribution studies are carried out in a 7 lt Pyrex cell fitted with a White
multireflection optics system, giving pathlengths up to 40 m. Reactant and product analysis is done by in-situ
FTIR spectroscopy, which is capable of determining concentrations in the ppm range. The cell is temperature
controlled and allows the variation of total pressure from 10 to 760 Torr. Products are also analyzed by capillary
gas chromatography coupled with mass spectrometry.
3. The Molecular Beam Mass Spectrometric (MBMS) technique will be used to study the reaction of NO3 and
Cl with partially fluorinated ethers. This a technique for the study of fast radical-molecule reactions in the gas
phase, and provides accurate absolute rate constant measurements over a wide range of temperatures. It includes
focusing magnetic and electrostatic lenses that enables the detection of paramagnetic species and the mass
spectroscopic identification of free radicals and polar species. Furthermore, electrical focusing determines the
geometrical structure of the product radicals. The reactions take place at two ranges of pressures: the low
pressure regime and the near atmospheric pressure regime. Finally, it provides the possibility to investigate the
pressure dependence of bimolecular reactions, at near atmospheric conditions.

Wissenschaftliches Gebiet (EuroSciVoc)

CORDIS klassifiziert Projekte mit EuroSciVoc, einer mehrsprachigen Taxonomie der Wissenschaftsbereiche, durch einen halbautomatischen Prozess, der auf Verfahren der Verarbeitung natürlicher Sprache beruht. Siehe: Das European Science Vocabulary.

• Naturwissenschaften Chemiewissenschaften Elektrochemie Elektrolyse
• Naturwissenschaften Chemiewissenschaften anorganische Chemie Halogen
• Naturwissenschaften Geowissenschaften und verwandte Umweltwissenschaften Atmosphärenwissenschaften Meteorologie Luftdruck
• Naturwissenschaften Chemiewissenschaften analytische Chemie Massenspektrometrie
• Naturwissenschaften Naturwissenschaften Optik Spektroskopie

Programm/Programme

Mehrjährige Finanzierungsprogramme, in denen die Prioritäten der EU für Forschung und Innovation festgelegt sind.

• FP4-ENV 2C - Specific programme of research and technological development in the field of environment and climate, 1994-1998

Thema/Themen

Aufforderungen zur Einreichung von Vorschlägen sind nach Themen gegliedert. Ein Thema definiert einen bestimmten Bereich oder ein Gebiet, zu dem Vorschläge eingereicht werden können. Die Beschreibung eines Themas umfasst seinen spezifischen Umfang und die erwarteten Auswirkungen des finanzierten Projekts.

• 01020101 - Stratospheric chemistry and depletion of the ozone layer

Aufforderung zur Vorschlagseinreichung

Verfahren zur Aufforderung zur Einreichung von Projektvorschlägen mit dem Ziel, eine EU-Finanzierung zu erhalten.

Finanzierungsplan

Finanzierungsregelung (oder „Art der Maßnahme“) innerhalb eines Programms mit gemeinsamen Merkmalen. Sieht folgendes vor: den Umfang der finanzierten Maßnahmen, den Erstattungssatz, spezifische Bewertungskriterien für die Finanzierung und die Verwendung vereinfachter Kostenformen wie Pauschalbeträge.

CSC - Cost-sharing contracts

Koordinator

Beteiligte (4)