Compositional effects on the ignition of FACE gasolines

Sarathy, S. Mani; Kukkadapu, Goutham; Mehl, Marco; Javed, Tamour; Ahmed, Ahfaz; Naser, Nimal; Tekawade, Aniket; Kosiba, Graham; Alabbad, Mohammed; Singh, Eshan; Park, Sungwoo; Rashidi, Mariam Al; Chung, Suk Ho; Roberts, William L.; Oehlschlaeger, Matthew A.; Sung, Chih-Jen; Farooq, Aamir

doi:10.1016/j.combustflame.2016.04.010

Cited by 177 publications

(243 citation statements)

References 86 publications

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“…It was also shown that these discrepancies in IDT at low temperatures can result in significant differences in the combustion phasing of a CI engine operating at low loads [28,34]. [29], FACE A & C from [35], HSRN from [28], GCI blend from this work.…”

Section: Fig 1 Measured Ignition Delay Times Of the Gci Blend And Tmentioning

confidence: 99%

“…Even though molecular structure is a very important indicator of the fuel reactivity, matching the molecular structure of all components of the real fuel can be challenging and can lead to a relatively large surrogate mixture [29] for which detailed or reduced chemical kinetic models may not be available. Computational cost will also be high for surrogates containing too many components.…”

Section: Fuel Characterization and Surrogate Formulationmentioning

confidence: 99%

“…2 compares IDTs of GCI blend (RON 77) with those of straight-run naphtha (RON 60) [28], FACE A/C (RON 83.5 and 84.7) [35] and FACE F/G (RON 94.4 and RON 96.8) [29]. Detailed comparison of these fuels is available in It may be concluded from the experimental data of the GCI blend and the two surrogates that a multi-component surrogate with non-paraffinic content is needed to match the reactivity at low temperatures where PRF surrogate tends to be too reactive.…”

Section: Fig 1 Measured Ignition Delay Times Of the Gci Blend And Tmentioning

confidence: 99%

“…The FACE gasolines mechanism by Sarathy et al [29] and the gasoline surrogate mechanism by Mehl et al [38] were used to perform simulations in Chemkin-Pro with a homogeneous batch reactor. The gradual increase in pressure (dP/dt) behind reflected shock waves was considered by employing a corresponding volume profile in shock tube simulations.…”

Section: Ignition Delay Time Simulationsmentioning

confidence: 99%

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Ignition delay measurements of a low-octane gasoline blend, designed for gasoline compression ignition (GCI) engines

Alabbad

Badra

Djebbi

et al. 2019

Proceedings of the Combustion Institute

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A blend of low-octane (light and heavy naphtha) and high-octane (reformate) distillate fuels has been proposed for powering gasoline compression ignition (GCI) engines. The formulated 'GCI blend' has a research octane number (RON) of 77 and a motor octane number (MON) of 73.9. In addition to ~ 64 mole% paraffinic components, the blend contains ~ 20 mole% aromatics and ~ 15 mole% naphthenes.Experimental and modelling studies have been conducted in this work to assess autoignition characteristics of the GCI blend. Ignition delay times were measured in a shock tube and a rapid comparison machine over wide ranges of experimental conditions (20 and 40 bar, 640 -1175 K,  = 0.5, 1 and 2). Reactivity of the GCI blend was compared with experimental measurements of two surrogates: a multi-component surrogate (MCS) and a two-component primary reference fuel (PRF 77). Both surrogates capture the reactivity of the fuel quite well at high and intermediate temperatures.The MCS does a better job of emulating the fuel reactivity at low temperatures, where PRF 77 is more reactive than the GCI blend. Ignition delay times of the two surrogates are also simulated using detailed chemical kinetic models, and the simulations agree well with the experimental findings. The results of rate-of-production analyses show important role of cycloalkane chemistry in the overall autoignition behavior of the fuel at low temperatures.

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Section: Fig 1 Measured Ignition Delay Times Of the Gci Blend And Tmentioning

confidence: 99%

Section: Fuel Characterization and Surrogate Formulationmentioning

confidence: 99%

Section: Fig 1 Measured Ignition Delay Times Of the Gci Blend And Tmentioning

confidence: 99%

Section: Ignition Delay Time Simulationsmentioning

confidence: 99%

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Ignition delay measurements of a low-octane gasoline blend, designed for gasoline compression ignition (GCI) engines

Alabbad

Badra

Djebbi

et al. 2019

Proceedings of the Combustion Institute

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“…However, 4-component surrogates involving TRF/1-pentene and TRF/2-pentene have also been formulated and investigated by e.g. [14][15][16], as well as complex multicomponent surrogates for various non-oxygenated gasolines [17,18]. The reasonable extent of agreement between TRF and gasoline, in addition to the availability of well validated chemical mechanisms of its oxidation pathways, makes it currently a more feasible surrogate for gasoline in terms of ignition delay modelling compared to more complex surrogates [19] and blending effects, and hence it is used in this work.…”

Section: Surrogate Formulationmentioning

confidence: 99%

The influence of n -butanol blending on the ignition delay times of gasoline and its surrogate at high pressures

Agbro

Tomlin

Lawes

et al. 2017

Fuel

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The influence of blending n-butanol at 20% by volume on the ignition delay times for a reference gasoline was studied in a rapid compression machine (RCM) for stoichiometric fuel/air mixtures at 20 bar and 678 K-858 K. Delay times for the blend lay between those of stoichiometric gasoline and stoichiometric n-butanol across the temperature range studied. At lower temperatures, delays for the blend were however, much closer to those of n-butanol than gasoline despite n-butanol being only 20% of the mixture. Under these conditions n-butanol acted as an octane enhancer over and above what might be expected from a simple linear blending law. The ability of a gasoline surrogate, based on a toluene reference fuel (TRF), to capture the main trends of the gasoline/ n-butanol blending behaviour was also tested within the RCM. The 3-component TRF based on a mixture of toluene, n-heptane and iso-octane was able to capture the trends well across the temperature range studied. Simulations of ignition delay times were also performed using a detailed blended nbutanol/TRF mechanism based on the adiabatic core assumption and volume histories from the experimental data. Overall, the model captured the main features of the blending behaviour, although at the lowest temperatures, predicted ignition delays for stoichiometric n-butanol were longer than those observed. A bruteforce local sensitivity analysis was performed to evaluate the main chemical processes driving the ignition behaviour of the TRF, n-butanol and blended fuels. The reactions of fuel + OH dominated the sensitivities at lower temperatures, with H abstraction from nn-butanol and the blend. At higher temperatures the decomposition of H 2 O 2 and reactions of HO 2 and that of formaldehyde with OH became critical, in common with the ignition behaviour of other fuels. Remaining uncertainties in the rates of these key reactions are discussed.

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Developing the Low‐Temperature Oxidation Mechanism of Cyclopentane: An Experimental and Theoretical Study

Shi

Jiang

et al. 2022

Chemistry A European J

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At present, the reactivity of cyclic alkanes is estimated by comparison with acyclic hydrocarbons. Due to the difference in the structure of cycloalkanes and acycloalkanes, the thermodynamic data obtained by analogy are not applicable. In this study, a molecular beam sampling vacuum ultraviolet photoionization time‐of‐flight mass spectrometer (MB‐VUV‐PI‐TOFMS) was applied to study the low‐temperature oxidation of cyclopentane (CPT) at a total pressure range from 1–3 atm and low‐temperature range between 500 and 800 K. Low‐temperature reaction products including cyclic olefins, cyclic ethers, and highly oxygenated intermediates (e. g., ketohydroperoxide KHP, keto‐dihydroperoxide KDHP, olefinic hydroperoxides OHP and ketone structure products) were observed. Further investigation of the oxidation of CPT – electronic structure calculations – were carried out at the UCCSD(T)‐F12a/aug‐cc‐pVDZ//B3LYP/6‐31+ G(d,p) level to explore the reactivity of O2 molecules adding sequentially to cyclopentyl radicals. Experimental and theoretical observations showed that the dominant product channel in the reaction of CPT radicals with O2 is HO2 elimination yielding cyclopentene. The pathways of second and third O2 addition – the dissociation of hydroperoxide – were further confirmed. The results of this study will develop the low‐temperature oxidation mechanism of CPT, which can be used for future research on accurately simulating the combustion process of CPT.

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Compositional effects on the ignition of FACE gasolines

Cited by 177 publications

References 86 publications

Ignition delay measurements of a low-octane gasoline blend, designed for gasoline compression ignition (GCI) engines

Ignition delay measurements of a low-octane gasoline blend, designed for gasoline compression ignition (GCI) engines

The influence of n -butanol blending on the ignition delay times of gasoline and its surrogate at high pressures

Developing the Low‐Temperature Oxidation Mechanism of Cyclopentane: An Experimental and Theoretical Study

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