Iterative and function-continuation Fourier deconvolution methods for enhancing mass spectrometer resolution
Abstract
Mass spectrometer data in the form of ion current versus mass-to-charge ratio often include overlapping mass peaks, especially in low- and medium-resolution instruments. Numerical deconvolution of such data effectively enhances the resolution by decreasing the overlap of mass peaks. In this paper two approaches to deconvolution are presented: a function-domain iterative technique and a Fourier transform method which uses transform-domain function-continuation. Both techniques include data smoothing to reduce the sensitivity of the deconvolution to noise. The efficacy of these methods is demonstrated through application to representative mass spectrometer data and the deconvolved results are discussed and compared to data obtained from a spectrometer with sufficient resolution to achieve separation of the mass peaks studied. A case for which the deconvolution is seriously affected by Gibbs oscillations is analyzed.
- Publication:
-
International Journal of Mass Spectrometry and Ion Processes
- Pub Date:
- 1984
- Bibcode:
- 1984IJMSI..55...93I
- Keywords:
-
- Convolution Integrals;
- Fourier Transformation;
- Gibbs Phenomenon;
- High Resolution;
- Iterative Solution;
- Mass Spectrometers;
- Methane;
- Oxygen;
- Signal To Noise Ratios