Abstract
Shock-induced oxidation of two higher-order linear alkanes was measured using a heated shock tube facility. Experimental overlap in stoichiometric ignition delay times obtained under dilute (99 % Ar) conditions near atmospheric pressure was observed in the temperature-dependent ignition trends of n-nonane (n-C9H20) and n-undecane (n-C11H24). Despite the overlap, model predictions of ignition using two different detailed chemical kinetics mechanisms show discrepancies relative to both the measured data as well as to one another. The present study therefore focuses on the differences observed in the modeled, high-temperature ignition delay times of higher-order n-alkanes, which are generally regarded to have identical ignition behavior for carbon numbers above C7. Comparisons are drawn using experimental data from the present study and from recent work by the authors relative to two existing chemical kinetics mechanisms. Time histories from the shock-tube OH* measurements are also compared to the model predictions; a double-peaked structure observed in the data shows that the time response of the detector electronics is crucial for properly capturing the first, incipient peak near time zero. Calculations using the two mechanisms were carried out at the dilution level employed in the shock-tube experiments for lean \({({\rm {\phi}} = 0.5)}\), stoichiometric, and rich \({({\rm {\phi}} = 2.0)}\) equivalence ratios, 1230–1620 K, and for both 1.5 and 10 atm. In general, the models show differing trends relative to both measured data and to one another, indicating that agreement among chemical kinetics models for higher-order n-alkanes is not consistent. For example, under certain conditions, one mechanism predicts the ignition delay times to be virtually identical between the n-nonane and n-undecane fuels (in fact, also for all alkanes between at least C8 and C12), which is in agreement with the experiment, while the other mechanism predicts the larger fuels to ignite progressively more slowly.
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References
Davidson D.F., Ranganath S.C., Lam K.-Y., Liaw M., Hong Z., Hanson R.K.: Ignition delay time measurements of normal alkanes and simple oxygenates. J. Propuls. Power 26, 280–287 (2010)
Dagaut P., Reuillon M., Cathonnet M.: High pressure oxidation of liquid fuels from low to high temperature. 1. n-heptane and iso-octane. Combust. Sci. Technol. 95, 233–260 (1994)
Shen H.-P.S., Steinberg J., Vanderover J., Oehlschlaeger M.A.: A shock tube study of the ignition of n-heptane, n-decane, n-dodecane, and n-tetradecane at elevated pressures. Energy Fuels 23, 2482–2489 (2009)
Rotavera B., Dievart P., Togbé C., Dagaut P., Petersen E.L.: Oxidation kinetics of n-nonane: Measurements and modeling of ignition delay times and product concentrations. Proc. Combust. Inst. 33, 175–183 (2011)
Horning D.C., Davidson D.F., Hanson R.K.: Study of the high-temperature autoignition of n-alkane/O2/Ar mixtures. J. Propuls. Power 18, 363–371 (2002)
Vasu S.S., Davidson D.F., Hong Z., Vasudevan V., Hanson R.K.: n-Dodecane oxidation at high-pressures: Measurements of ignition delay times and OH concentration time-histories. Proc. Combust. Inst. 32, 173–180 (2009)
Haylett D.R., Cook R.D., Davidson D.F., Hanson R.K.: OH and C2H4 species time-histories during hexadecane and diesel ignition behind reflected shock waves. Proc. Combust. Inst. 33, 167–173 (2011)
Curran H.J., Gaffuri P., Pitz W.J., Westbrook C.K.: A comprehensive modeling study of n-heptane oxidation. Combust. Flame 114, 149–177 (1998)
Zeppieri S.P., Klotz S.D., Dryer F.L.: Modeling concepts for larger carbon number alkanes: a partially reduced skeletal mechanism for n-decane oxidation and pyrolysis. Proc. Combust. Inst. 28, 1587–1595 (2000)
Westbrook C.K., Pitz W.J., Herbinet O., Curran H.J., Silke E.J.: A comprehensive detailed chemical kinetic reaction mechanism for combustion of n-alkane hydrocarbons from n-octane to n-hexadecane. Combust. Flame 156, 181–199 (2009)
Sarathy S.M., Westbrook C.K., Mehl M., Pitz W.J., Togbé C., Dagaut P., Wang H., Oehlschlaeger M.A., Niemann U., Seshadri K., Veloo P.S., Ji C., Egolfopoulos F.N., Lu T.: Comb. Flame. 158, 2338–2357 (2011)
Wang, H., Dames, E., Sirjean, B., Sheen, D.A., Tangko, R., Violi, A., Lai, J.Y.W., Egolfopoulos, F.N., Davidson, D.F., Hanson, R.K., Bowman, C.T., Law, C.K., Tsang, W., Cernansky, N.P., Miller, D.L., Lindstedt, R.P.: JetSurF version 2.0 http://melchior.usc.edu/JetSurF/JetSurF2.0 (2010)
Rotavera, B.: Chemiluminescence and ignition delay time measurements of C9H20. M.S. Thesis, Texas A&M University, College Station, Texas (2009)
Kopp, M.M., Brower, M.L., Güethe, F., Petersen, E.: Effect of filter choice on OH* chemiluminescence kinetics at low and elevated pressures. 7th US Nat. Tech. Mtg. Comb. Inst., March 20–23 (2011)
Rotavera, B., Petersen, E.L., Dagaut, P.: in preparation
Hall J.M., Petersen E.L.: An optimized kinetics model for OH chemiluminescence at high temperatures and atmospheric pressures. Int. J. Chem. Kinet. 38, 714–724 (2006)
Petersen E.L., Hanson R.K.: Nonideal effects behind reflected shock waves in a high-pressure shock tube. Shock Waves 10, 405–420 (2001)
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Communicated by D. Zeitoun and K. Kontis.
The paper was based on work that was presented at the 28th International Symposium on Shock Waves, 17–22 July 2011, Manchester, UK.
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Rotavera, B., Petersen, E.L. Model predictions of higher-order normal alkane ignition from dilute shock-tube experiments. Shock Waves 23, 345–359 (2013). https://doi.org/10.1007/s00193-012-0387-6
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DOI: https://doi.org/10.1007/s00193-012-0387-6