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New FT-ICR MS method for fingerprinting petroleum and other complex mixtures

8 August 2019 | News
by Ian Michael

Scientists at the University of Warwick, UK, have developed a more powerful method of analysing chemical mixtures, which has been able to assign 244,779 molecular compositions within a single sample of non-distillable fraction of crude oil. The new method was developed by the Barrow Group within the Department of Chemistry at the University of Warwick and is detailed in a paper in Chemical Science. It paves the way for analysis of challenging samples across different fields.

Assigning the compositions of molecules in a complex mixture is valuable tool for a number of industries, where determining the elemental composition of those molecules can provide valuable data for research, determine the mixture’s viability such as in the petrochemical industry, or even “fingerprint” a complex mixture such as oil or environmental samples. The researchers developed a new method, called operation at constant ultrahigh resolution (OCULAR), that combines experimental and data processing techniques that allowed them to characterise the most complex sample that they have ever worked on.

Using Fourier transform ion cyclotron resonance mass spectrometry (FT-ICR MS), the researchers analysed a sample of heavy petroleum in solution. The ultrahigh resolving power and mass accuracy of FT-ICR MS allows the scientists to determine the elemental compositions within even the most complex samples, with a high degree of confidence. Traditional analysis performed with a variety of Fourier transform mass spectrometers offers decreasing resolving power and confidence in assignments of the elemental compositions at higher m/z when studying a broad m/z range. In the new OCULAR method, ions are analysed using smaller data segments based upon their mass, where the experiment is designed in a way to ensure almost constant resolving power across the full mass range analysed; in the published example, a constant resolving power of 3 million was used to characterise a heavy petroleum sample.

Using an algorithm developed by the researchers, the segmented data can be automatically prepared and “stitched” together to generate a complete mass spectrum (relative abundance vs m/z). Each peak represents a single molecular composition, and so the entirety of the mass spectrum covers the compositional space of the sample. This allowed them to operate at much higher resolution and also addressed issues relating to space-charge effects, where a large number of ions will affect the accuracy of the mass measurement. The result was resolution, detection and assignment of the highest number of peaks within a sample to date.

The technique can be used for any analysis of a complex mixture and has potential applications in areas such energy (e.g. petroleum and biofuels), life sciences and healthcare (e.g. proteomics, cancer research and metabolomics), materials (e.g. polymers) and environmental analysis, including being used to “fingerprint” oil spills by their molecular composition.

Lead author Dr Diana Palacio Lozano, from the University of Warwick’s Department of Chemistry, said: “This method can improve the performance of a range of FTMS instruments, including high and low magnetic field FT-ICR MS instruments and Orbitrap instruments. We are now able to analyse mixtures that, due to their complexity, are challenging even for the most powerful analytical techniques. This technique is flexible as the performance can be selected according to the research needs.”

Petroleum samples are inherently highly complex and so were an ideal test for this method. As the world’s use of petroleum spurs the move to heavier oils, the samples are becoming more complex and so there is also a greater need for this type of analysis by petrochemical scientists. The low volatility of the heavier oil can now be explained by the extraordinarily complex elemental composition. The high complexity of heavy oils can interfere with catalysis and affects extraction, transport and refining processes. The OCULAR technique is also powerful enough to be used on samples that require the highest performance to assign compositions based on mass accuracy or fine isotopic patterns.

Principal investigator Dr Mark Barrow said: “The OCULAR approach allows us to push the current analytical limits for characterising the most complex samples. It significantly extends the performance of all FTMS instruments at no additional cost and works well with developments in the field, such as newer hardware designs, detection methods and data processing methods. OCULAR is highly versatile, the experiments and processing can be adapted as needed, and the approach can be applied to many research areas, including energy, healthcare and the environment.”

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