- P-ISSN 2233-4203
- E-ISSN 2093-8950
- Apply for Authority
- P-ISSN2233-4203
- E-ISSN2093-8950
Article Detail
Home > Article Detail
Application of Comprehensive 2D GC-MS and APPI FT-ICR MS for More Complete Understanding of Chemicals in Diesel Fuel
Mass Spectrometry Letters / Mass Spectrometry Letters, (P)2233-4203; (E)2093-8950
2012, v.3 no.2, pp.43-46
https://doi.org/10.5478/MSL.2012.3.2.43
(Kyungpook National University)
(Kyungpook National University)
(Kyungpook National University)
(Kyungpook National University)
(Kyungpook National University)
(Kyungpook National University)
(Kyungpook National University)
Cho,
Y., Annana,
I.
, Arif,
A.
, &
Kim,
S.
(2012). Application of Comprehensive 2D GC-MS and APPI FT-ICR MS for More Complete Understanding of Chemicals in Diesel Fuel. Mass Spectrometry Letters, 3(2), 43-46, https://doi.org/10.5478/MSL.2012.3.2.43
- Downloaded
- Viewed
Abstract
In this study, comprehensive two dimension gas chromatography (2D GC-MS) and 15 T Fourier transform ion cyclotronresonance mass spectrometry (15T FT-ICR MS) connected to atmospheric pressure photo ionization (APPI) have beencombined to obtain detailed chemical composition of a diesel oil sample. With 2D GC-MS, compounds with aliphatic alkyl, saturatedcyclic ring(s), and one aromatic ring structures were mainly identified. Sensitivity toward aromatic compounds with morethan two aromatic rings was low with 2D GC-MS. In contrast, aromatic compounds containing up to four benzene rings wereidentified by APPI FT-ICR MS. Relatively smaller abundance of cyclic ring compounds were found but no aliphatic alkyl compoundswere observed by APPI FT-ICR MS. The data presented in this study clearly shows that 2D GC-MS and 15T FT-ICRMS provides different aspect of an oil sample and hence they have to be considered as complementary techniques to each otherfor more complete understanding of oil samples.
- keywords
- 2D GC-MS, High resolution mass spectrometry, FT-ICR MS, Oil
Reference
1
Silva, S. L. (2011). . Anal. Chimi. Acta, 707, 18-.
2
Ai-Thamir, W. K. (1988). . Fuel, 67, 871-.
3
Müller, A. L. H. (2012). . Spectro. Acta Part A: Mol. and Biomol. Spectro, 89, 82-.
4
Genov, G. (2008). . Org. Geochem, 39, 1229-.
5
Li, M. (2002). . Coll. and Surf. A: Phys. and Eng. Asp, 197, 193-.
6
Wang, Z. D. (2006). . Env. Foren, 7, 105-.
7
Marriott, P. J. (2001). . Chromatogr. A, 936, 1-.
8
Tabanca, N. (2005). . J. Chromatogr. A, 1097, 192-.
9
Dallüge, J. (2003). . J. Chromatogr. A, 1000, 69-.
10
Marriott, P. (2002). . TrAC Trends Anal. Chem, 21, 573-.
11
Marshall, A. G. (1985). . Acc. Chem. Res, 18, 316-.
12
Maikhunthod, B. (2010). . J. Chromatogr. A, 1217, 1522-.
13
Dutriez, T. (2010). . Fuel, 89, 2338-.
14
Flego, C. (2011). . Fuel, 90, 2863-.
15
Marsman, J. H. (2007). . J. Chromatogr. A, 1150, 21-.
16
Nizio, K. D. . J. Chromatogr. A, , -.
17
Eunkyoung Kim. (2011). Compositional Characterization of Petroleum Heavy Oils Generated from Vacuum Distillation and Catalytic Cracking by Positive-mode APPI FT-ICR Mass Spectrometry. Mass Spectrometry Letters, 2(2), 41-44. http://dx.doi.org/10.5478/MSL.2011.2.2.041.
18
Marshall, A. G. (1998). . Mass Spec. Rev, 17, 1-.
19
Rodgers R. P. (2002). . Fuel Chem. Div. Prep, 47, 636-.
20
Wang, J. (2011). . Chemosphere, 85, 609-.
21
Hughey, C. A. (2002). . Org. Geochem, 33, 743-.
22
Helms, J. R. (2012). . Org. Geochem, 44, 21-.
23
Miyabayashi, K. (2008). . Fuel Pro.Tech, 89, 397-.
24
Hur, M. (2009). (-). Interpretation of Crude Oil High Resolution Spectra obtained by ESI and APPI FT-ICR Mass Spectrometry using Principal Components Analysis In 57th ASMS Conference on Mass Spectrometry and Allied Topics.
25
Manhoi Hur. (2009). Optimized Automatic Noise Level Calculations for Broadband FT-ICR Mass Spectra of Petroleum Give More Reliable and Faster Peak Picking Results. Bulletin of the Korean Chemical Society, 30(11), 2665-2668.
26
Reichenbach, S. E. (2004). . Chemo. and Intell. Lab. Sys, 71, 107-.
27
Murphy, R. E. (1998). . Anal. Chem, 70, 1585-.
28
Reichenbach, S. E. (2003). . J. Chromatogr. A, 985, 47-.
29
Kallio, M. (2007). . J. Chromatogr. A, 1148, 228-.
30
Vendeuvre, C. (2005). . J. Chromatogr. A, 1086, 21-.
31
Adam, F. (2008). . J. Chromatogr. A, 1186, 236-.
32
Cookson, D. J. (1987). . Fuel, 66, 758-.
33
Dutriez, T. (2012). . Fuel, 96, 108-.
34
Adahchour, M. (2006). . TrAC Tren. in Anal. Chem, 25, 726-.
- Submission Date
- 2012-06-08
- Revised Date
- 2012-06-17
- Accepted Date
- 2012-06-17
Other articles from this issue
- Gas Chromatography-High Resolution Tandem Mass Spectrometry Using a GC-APPI-LIT Orbitrap for Complex Volatile Compounds Analysis
- An Application of Electrostatic Repulsion Hydrophilic Interaction Chromatography in Phospho- and Glycoproteome Profiling of Epicardial Adipose Tissue in Obesity Mouse
- Application of Comprehensive 2D GC-MS and APPI FT-ICR MS for More Complete Understanding of Chemicals in Diesel Fuel
- Microwave-assisted Weak Acid Hydrolysis of Proteins
- Simultaneous Determination of Synthetic Phosphodiesterase-5 Inhibitors in Dietary Supplements by Liquid Chromatography-High Resolution/Mass Spectrometry
- Isotope Measurement of Uranium at Ultratrace Levels Using Multicollector Inductively Coupled Plasma Mass Spectrometry
- Determination of Mercury in Fly Ash by Using Flow Injection Cold Vapor Isotope Dilution Inductively Coupled Plasma Mass Spectrometry
- more
Recommanded Articles
This website recommended the use the Chrome browser for journal website.