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Oxidative Stability of Middle Distillate Fuels. Part 1: Exploring the Soluble Macromolecular Oxidatively Reactive Species (SMORS) Mechanism with Jet Fuels Christopher G. Kabana,† Shanielle Botha,‡ Colin Schmucker,† Chris Woolard,‡ and Bruce Beaver*,† † ‡
Department of Chemistry and Biochemistry, Duquesne University, Pittsburgh, Pennsylvania 15282, United States Sasol Advanced Fuels Laboratory, University of Cape Town, Rondebosch, Cape Town 7700, South Africa
bS Supporting Information ABSTRACT: The soluble macromolecular oxidatively reactive species (SMORS) mechanism has recently been applied to jet fuel thermal oxidative degradation at high temperatures (250�550 °C). The primary purpose of this work is to further test the extant SMORS mechanism with carefully designed experiments at lower temperatures. First, synthetic SMORS precursors, 2-methylindole and 1,4-benzoquinone, were doped into a stable Jet A-1 in both mono- and oligomeric forms. Flask oxidative stress of these solutions at 90 °C for 60 min with an oxygen sparge significantly increases jet fuel thermal oxidative degradation. Second, a model compound experiment suggests SMORS precursors, phenol and 1,4-benzoquinone, are generated in situ from flask oxidation of a natural jet fuel component cumene (isopropylbezene) at 160 °C with an air sparge for 300 min. This observation is particularly significant for the thermal oxidative degradation of ultra-low sulfur diesel (ULSD) because it suggests that fuels with low heteroatom content may oxidatively degrade by the SMORS mechanism. Third, doping parts per million (ppm) levels of 2,4-dimethylpyrrole into oxidatively stable jet fuels followed by flask oxidation at 95 °C with an air sparge for 30 min results in significant oxidation of the jet fuels. This observation is particularly significant for the storage and thermal oxidative stability of Athabasca-tar-sands-derived middle distillates, which have previously been shown to contain alkylpyrroles; these middle distillates are predominate across the northern tier of the United States.
’ INTRODUCTION Thermal oxidative degradation of jet and diesel fuels has been an issue for many years.1�4 For example, an increase of in-flight fuel filter blockages were noted in commercial aviation in the early 2000s.5�9 Anecdotal evidence suggests that replacing fuel filters more frequently has decreased the incidence of this problem. However, such an approach does not address a potential contributing factor to this problem: the low-temperature (∼100 °C) oxidative degradation of certain jet fuels. For this reason, a better understanding of the mechanism of oxidative deposit formation from jet fuel is warranted. For middle distillate fuels, oxidative degradation involves the incorporation of low-molecular-weight heteroatomic molecules10�14 into higher molecular-weight structures that incorporate molecular oxygen.1�3,14 A foundational study on the oxidative degradation of diesel fuels has been reported by Hardy and Wechter.1 In their study, both a general concept for deposit formation as well as a general procedure for analysis of the process [the soluble macromolecular oxidatively reactive species (SMORS) methodology] were proposed. In 2005, generic molecular structures for deposit precursors were proposed,2b as well as a mechanism for thermal oxidative deposit (TOD) formation. This proposal was based on elemental analysis data from five oxidatively degraded light-cycle oil-doped diesel fuels provided by Hardy and Wechter.1 It should be noted that the proposed mechanism is generic in the sense that the molecules represented should be thought of as generalizations of chemical entities. In the current paper, the 2005 mechanism is r 2011 American Chemical Society
modified to better reflect that a variety of molecular entities can be incorporated into oxidative deposits and precursors. In addition, the proposed mechanism is more consistent with the reactivity of indole-substituted hydroquinones and is more consistent with Hardy and Wechter’s1 elemental analysis data. In Scheme 1, middle distillate oxidative degradation begins with the oxidation of phenolic compounds indigenous to jet fuel15,16 via a peroxyl radical chain mechanism.3,17,18 Phenol oxidation by a peroxyl radial yields a resonance-stabilized radical, which presumably reacts with a second equivalent of peroxyl radical, ultimately yielding benzoquinone (step 3 in Scheme 1). Quinones are robust electrophiles that can act as molecular coupling promoters. This coupling ability is showcased through electrophilic aromatic substitution (EAS) reactions with electron-rich heterocycles, such as the substituted carbazole or pyrrole reactions, illustrated in step 4 in Scheme 1. Oxidation in step 5 yields quinone dimers 2a and 2b. In reaction 6, EAS reactions followed by further oxidation yields compound 3; this structure precisely matches the average elemental analysis of diesel fuel deposit precursors observed by Hardy and Wechter1 and has a molecular weight of 636 Da. Presumably, this process repeats itself until the molecular weight and polarity cause deposit precursors to precipitate. Hardy and Wechter1 have presented additional data that suggests that the diesel fuel TOD molecular weight is in the range of 1000 Da. Received: July 1, 2011 Revised: October 12, 2011 Published: October 13, 2011 5145
dx.doi.org/10.1021/ef200964z | Energy Fuels 2011, 25, 5145–5157
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Scheme 1. SMORS Mechanism for Jet Fuel TOD Formation
The significant aspects of this hypothesis deserve to be reiterated. Mechanistically, it chemically describes how compounds in the parts per million concentration range oxidize and form higher molecular-weight oxidation precursors that ultimately yield a TOD. This is primarily due to the selectivity of peroxyl radicals in hydrogen atom abstraction reactions.3,19,20 For instance, the conjugated hydroquinone molecules 1a and 1b are more susceptible to reaction with peroxyl radicals than simple phenols. This is due to the increased stability offered by the resulting radical from conjugation. It should also be noted that the proposed mechanism is generic in the sense that many electron-rich aromatic compounds can undergo EAS with benzoquinones. In Scheme 1, note that both substituted carbazole and pyrrole react with benzoquinone to yield compounds 1a and 1b. Other molecules that can react with quinones include anisole derivatives, alkyl-substituted benzenes, naphthalenes, phenols, thiols, amines, and thiophenols. For instance, Commodo et al.21 recently reported electrospray ionization�mass spectrometry (ESI�MS) data from an oxidized Jet A-1 of a homologous series derived from a parent structure with a (M + H)+ ion peak at m/z 275.1. Such a compound could be generated by the reaction of indigenous 4-hydroxybezenethiol with substituted 1,4-benzoquinone produced by phenol oxidation, as suggested in reaction 1.
Finally, Scheme 1 accounts for the formation of color bodies during the oxidative degradation of middle distillates by the
growth of higher molecular-weight conjugated molecules, such as compound 3.22 The purpose of this study is multifaceted. The proposed SMORS mechanism for jet fuel oxidative degradation will be experimentally examined under model flask oxidative conditions. The experiments include (1) enhancing the oxidative degradation of a stable jet fuel by doping with proposed SMORS precursors followed by stressing, (2) spectroscopically examining the TOD and its soluble precursors, (3) experimentally establishing that SMORS precursors, phenol and benzoquinone, can be produced in an oxidatively degrading alkylaromatic model system, and (4) experimentally establishing that trace levels of a model π-excessive heterocycle, 2,4-dimethylpyrrole, can promote both oxidative deposit formation and significant fuel oxygenation.
’ EXPERIMENTAL SECTION Materials. Dodecane, decane, and hexane were purchased from Sigma Aldrich and used as received. Methanol was purchased from Alfa Aesar and used as received. 2,4-Dimethylpyrrole (DMP) was purchased from Sigma Aldrich and purified by Kugelrohr distillation, yielding a colorless solution. After distillation, DMP was purged with argon and placed in a 10 mL volumetric flask capped with a glass stopper, parafilmed, wrapped with aluminum foil, and stored in a refrigerator. Note that, despite these precautions, the DMP still slowly oxidizes to a light brown color. 1,10 -Azobis(cyclohexanecarbonitrile) (ACHN) was purchased from Sigma Aldrich and used as received. The various jet fuels were obtained from Wright-Patterson Air Force Base (WPAFB) in Dayton, OH, and from the Intertek Laboratory in Robinson, PA. Table 1 shows specifications from WPAFB fuels. All fuels were stored under argon upon receipt. 5146
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Table 1. Select Specification Data of Jet Fuels Examined 4877a
2827b
2827c
thermal stability at 260 °C; change in pressure (mmHg)
0
0
2
0
thermal deposit rating
