nerc.ac.uk

Refinement of ptr-ms methodology and application to the measurement of (o)vocs from cattle slurry

House, Emily. 2008 Refinement of ptr-ms methodology and application to the measurement of (o)vocs from cattle slurry. University of Edinburgh, College of Science and Engineering, PhD Thesis, 337pp.

Before downloading, please read NORA policies.
[thumbnail of PhD thesis]
Preview
Text (PhD thesis)
Full_thesis_25july2008_EH_final.pdf - Accepted Version

Download (3MB)
[thumbnail of 2._Specification_of_Proton_Transfer_Based_Chemical_Ionisation_Mass_Spectrometry_for_Additional_Compounds.pdf] Text
2._Specification_of_Proton_Transfer_Based_Chemical_Ionisation_Mass_Spectrometry_for_Additional_Compounds.pdf - Supplemental Material

Download (969kB)
[thumbnail of 3._Mass_list_notes.pdf]
Preview
Text
3._Mass_list_notes.pdf - Supplemental Material

Download (8kB)

Abstract/Summary

Oxygenated volatile organic compounds ((O)VOCs) contribute to ozone formation, affect the oxidising capacity of the troposphere and are sources of growth, and in some cases formation, of aerosols. It is therefore important to identify and quantify sources of (O)VOCs in the troposphere. In the late 1990s a unique technique for quantification of organic trace gas species, proton transfer reaction mass spectrometry (PTR-MS) was developed. PTR-MS potentially offers rapid response and high sensitivity without the need for sample preconcentration. Concentrations can be derived from the PTR-MS either by calibration or can be calculated from measured ion count rates and kinetic considerations. In this work, the methodology of PTR-MS application is critically assessed. The uncertainties and inaccuracies associated with each parameter employed in the calculation of concentrations are reviewed. This includes a critical appraisal of models for the calculation of the collisional rate constant currently applied in the field of PTR-MS. The use of a model to account for the effects of the electric field, available in the literature but not previously applied to the PTR-MS, is advocated. Collisional rate constants employing each of the models discussed have been calculated for the reactions of H3O+ with over 400 olecules for PTR-MS. In PTR-MS it cannot be assumed that the product ion occurs only at the protonated nondissociated mass. Few product distributions obtained from PTR-MS are cited in the literature, and even then the reaction chamber conditions (pressure, temperature and electric field strength) are not always specified. A large volume of product distributions for trace gases with H3O+ in select ion flow tube mass spectrometry (SIFT) exists in the literature and is reviewed. In SIFT, no electric field is applied to the reaction chamber and the extent and even nature of fragmentation can differ in PTR-MS. In addition to the application of an electric field, the energy in the reaction chamber can be increased by increasing the temperature or by variation of the reagent ion. In this work, the increase in energy via the three methods is approximated to enable a comparison of product istributions. The review of product distributions in PTR-MS, select ion flow drift tube mass spectrometry (SIFDT), variable temperature select ion flow tube mass spectrometry (VT-SIFT), SIFT, proton transfer reaction time of flight mass spectrometry (PTR-TOF-MS), proton transfer reaction ion trap mass spectrometry (PTR-ITMS) and electron ionisation mass spectrometry (EI-MS) is used alongside thermodynamic considerations to collate a list of potential contributors to a range of mass to charge ratios (m/z) in the PTR-MS. The need for further measurements of product distributions as a function of temperature, pressure and electric field strength for a wider range of (O)VOCs is highlighted. This enables dissociation to be better used as a tool for compound identification rather than being considered a hindrance. The collation of likely product distributions is applied to identify possible contributors to m/z observed during PTR-MS measurements of emission from cattle slurry. Field measurements were made during fertilisation of a grassland site south of Edinburgh in 2004 and 2005 and in laboratory-based measurements in 2006. Contextual reasoning, previous measurements and isotope ratios are used to narrow the list of possible contributors. Large concentrations of m/z cautiously identified as alcohols followed by a latter peak in carboxylic acids were observed during laboratory measurements. Increases in the corresponding m/z were also observed during the fertilisations. Other tentatively identified compounds emitted included phenol, methyl phenol, trimethylamine, and various sulphur containing compounds.

Item Type: Publication - Thesis (PhD)
Programmes: CEH Programmes pre-2009 publications > Biogeochemistry > BG01 Measuring and modelling trace gas, aerosol and carbon
UKCEH and CEH Sections/Science Areas: Billett (to November 2013)
Additional Pages: 144
Additional Information. Not used in RCUK Gateway to Research.: An Excel workbook containing computations of collisional rate constants is available
NORA Subject Terms: Atmospheric Sciences
Electronics, Engineering and Technology
Date made live: 18 Nov 2010 13:45 +0 (UTC)
URI: https://nora.nerc.ac.uk/id/eprint/9370

Actions (login required)

View Item View Item

Document Downloads

Downloads for past 30 days

Downloads per month over past year

More statistics for this item...