Separation & Identification of Organic Compounds in Lubricating Oil Additives Using TLC & GC-MS

Abstract: Thin layer chromatography (TLC) and Gas Chromatography-Mass Spectrometry (GC-MS) techniques are proposed for qualitative analysis of lubricating oil additives (Hitec 2915). The additives were dissolved in heptanes, extracted with mixed solvents heptane: acetonitrile (3:2) and spotted on TLC paper. The best combination solvents as developer for TLC analysis were carbon tetrachloride: heptanes (9:1) mixture. Each separated streak was scraped, redissolved in acetonitrile and evaporated to 0.5 ml volume then analy… Show more

“…Although we have not performed a detailed structural analysis of these marker ions, as our goal was to achieve mainly quality control and adulteration/counterfeiting screening, it is likely that these ions are from impurities or the additives added to improve performance. 4,5,19 Figure 3 shows the superimposed FTIR-ATR spectra for the same representative samples of mineral and synthetic oil used before (Figure 1). Previous studies have applied IR spectroscopy mainly to investigate the degrees of oxidation of lubricating oils, 9 although reports from the control agency in Brazil (ANP) usually claim to have detected non-conformities in synthetic oils via IR spectroscopy.…”

“…To improve performance, additives are also added to lubricant oils, particularly to the more valuable and higher performance synthetic oils, and may represent 5-25% of their molecular composition. 4,5 Viscosity analysis is one of the parameters most used for quality control in automotive lubricating oils, 6 but techniques focused on the measurement of gross physicochemical properties are expected to display poor performance when the task is to identify adulterations of lubricating oils. The most common adulteration involves mixing less valuable mineral oils with synthetic oils to increase profit in selling.…”

“…Synthetic oils come from laboratory synthesis, which, due to much more controlled conditions and fewer “building blocks,” normally display a lower number of trace components, therefore offering greater performance. To improve performance, additives are also added to lubricant oils, particularly to the more valuable and higher performance synthetic oils, and may represent 5–25% of their molecular composition 4,5 …”

“…[7][8][9] Nuclear magnetic resonance (NMR) spectroscopy 10,11 has been applied to lubricant oil analysis and reported to identify the presence of some solvents, water, or oxidized materials. Mass spectrometry (MS) analysis at the detailed molecular level coupled with gas chromatography (GC-MS) has also been used to differentiate and control the quality of lubricating oils 5,12,13 and is efficient in discriminating the three major types of lubricating oils, but GC-MS is considerably more demanding, more expensive, and time-consuming. Less demanding MS-only techniques applying ambient ionization techniques, such as easy ambient sonic spray ionization mass spectrometry (ESI-MS), have also been applied to molecular fingerprinting of oils and fuels in general.…”

Mass spectrometry molecular fingerprinting of mineral and synthetic lubricant oils

“…Although we have not performed a detailed structural analysis of these marker ions, as our goal was to achieve mainly quality control and adulteration/counterfeiting screening, it is likely that these ions are from impurities or the additives added to improve performance. 4,5,19 Figure 3 shows the superimposed FTIR-ATR spectra for the same representative samples of mineral and synthetic oil used before (Figure 1). Previous studies have applied IR spectroscopy mainly to investigate the degrees of oxidation of lubricating oils, 9 although reports from the control agency in Brazil (ANP) usually claim to have detected non-conformities in synthetic oils via IR spectroscopy.…”

“…To improve performance, additives are also added to lubricant oils, particularly to the more valuable and higher performance synthetic oils, and may represent 5-25% of their molecular composition. 4,5 Viscosity analysis is one of the parameters most used for quality control in automotive lubricating oils, 6 but techniques focused on the measurement of gross physicochemical properties are expected to display poor performance when the task is to identify adulterations of lubricating oils. The most common adulteration involves mixing less valuable mineral oils with synthetic oils to increase profit in selling.…”

“…Synthetic oils come from laboratory synthesis, which, due to much more controlled conditions and fewer “building blocks,” normally display a lower number of trace components, therefore offering greater performance. To improve performance, additives are also added to lubricant oils, particularly to the more valuable and higher performance synthetic oils, and may represent 5–25% of their molecular composition 4,5 …”

“…[7][8][9] Nuclear magnetic resonance (NMR) spectroscopy 10,11 has been applied to lubricant oil analysis and reported to identify the presence of some solvents, water, or oxidized materials. Mass spectrometry (MS) analysis at the detailed molecular level coupled with gas chromatography (GC-MS) has also been used to differentiate and control the quality of lubricating oils 5,12,13 and is efficient in discriminating the three major types of lubricating oils, but GC-MS is considerably more demanding, more expensive, and time-consuming. Less demanding MS-only techniques applying ambient ionization techniques, such as easy ambient sonic spray ionization mass spectrometry (ESI-MS), have also been applied to molecular fingerprinting of oils and fuels in general.…”

Mass spectrometry molecular fingerprinting of mineral and synthetic lubricant oils

“…Heavy metals analyzed in this research are metal Pb, Fe, Cu, Cd. Maoura, et al [11] in the study explains that the oil waste has a substance that is carcinogenic such as PAH so that the research aims to reduce the content of PAH in used oil. The best method of waste lubricating oil treatment has been done by Mohammed et al [3].…”

The effect of treatment with activated carbon on the metal content in reuse of lubricating oil waste