GC-TOFMS Application: Multifaceted crude oil analysis using GC-EI/FI, blank tube-FI, and FD on JMS-T2000GC

JMS-T2000GC can switch ionization methods without breaking the vacuum by using a EI/FI/FD* combination ion source. In this MSTips, we will introduce crude oil analysis that takes advantage of these ionization methods. Figure 1 shows a schematic diagram of the four analytical methods used in this experiment, and Table 1 shows their characteristics. In ①GC-EI and ②GC-FI, the sample is introduced into the GC injection port, separated by the GC column, and measured using hard ionization EI and soft ionization FI. These two measured data can be integrated and analyzed using msFineAnalysis AI. In ③Blank tube-FI, the sample is introduced into the GC injection port, passed through the blank tube, and measured using soft ionization FI. In ④FD, the sample is applied directly to the emitter and measured using a soft ionization FD. These mass spectra obtained by soft ionization can be easily analyzed using msRepeatFinder.
*EI: Electron Ionization, FI: Field Ionization, FD: Field Desorption, **KMD：Kendrick Mass Defect

Figure 1 Measurement method for crude oil in JMS-T2000GC

Table 1 Characteristics of each measurement method

Standard reference material (SRM) 2779 provided by NIST was used as the sample. The GC conditions of GC-EI and GC-FI were based on standard test method D6730 provided by ASTM International. In this method, it is possible to obtain a highly separated chromatogram by connecting two columns in series. Rtx-5 and Rtx-DHA manufactured by Restek corporation were used as columns. Table 2 shows the measurement conditions for each method.

Table 2 Measurement conditions

Figure 2 shows the TIC chromatograms of GC-EI and GC-FI. A large number of peaks were detected, including linear alkanes with carbon numbers from C₅ to C₃₂.

Figure 2 TIC chromatograms of GC-EI and GC-FI

Figure 3 shows the integrated analysis results of GC-EI and GC-FI using msFineAnalysis AI. The chromatograms were expanded around the retention time of Heptadecane (C₁₇H₃₆) to Eicosane (C₂₀H₄₂). The main components were simple hydrocarbons consisting of only C and H, but the minor component which is sulfur compound alkylated dibenzothiophenes were detected. Although this compound was not registered in the NIST library, its structural formula could be obtained using AI structural analysis.

Figure 3 Result of integrated analysis using msFineAnalysis AI

Figure 4 shows the TIC chromatograms and mass spectra of Blank tube-FI and FD. In both method, the molecular weight distribution could be confirmed with a short measurement time of less than 1 minute. Blank tube-FI can measure a wide range of components from low to high mass components. Although FD can measure higher mass components, lower mass components are lost due to volatilization when the emitter probe is introduced into the ion source. Therefore, it is necessary to select the method according to the sample type and purpose.

Figure 4 TIC chromatograms and mass spectra of Blank tube-FI and FD

Figure 5 shows the KMD plot and group data of FD created by msRepeatFinder. Using KMD plot, it is easily to evaluate the characteristics of main components hydrocarbons such as the distribution of the degree of unsaturation and degree of polymerization. Similar analysis is also possible with blank tube-FI.

Figure 5 KMD plot and group data of FD

Crude oil is a complex mixture, and it is difficult to obtain all the information using a single analytical method. JMS-T2000GC allows multifaceted analysis by switching the ionization method. In blank tube - FI and FD, it is easy to evaluate the main component hydrocarbons. In GC-EI and GC-FI, it is easily to analyze minor component. Furthermore, structural analysis of unknown compound is also possible using msFineAnalysis AI.

Chemistry

Plastic / Polymer