A coordinated investigation of the combustion chemistry of diisopropyl ketone, a prototype for biofuels produced by endophytic fungi

Joshua W. Allen, Adam M. Scheer, Connie W. Gao, Shamel S. Merchant, Subith S. Vasu, Oliver Welz, John D. Savee, David L. Osborn, Changyoul Lee, Stijn Vranckx, Zhandong Wang, Fei Qi, Ravi X. Fernandes, William H. Green*, Masood Z. Hadi, Craig A. Taatjes

*Corresponding author for this work

    Research output: Contribution to journalArticlepeer-review

    59 Scopus citations

    Abstract

    Several classes of endophytic fungi have been recently identified that convert cellulosic biomass to a range of ketones and other oxygenated molecules, which are potentially viable as biofuels, but whose oxidation chemistry is not yet well understood. In this work, we present a predictive kinetics model describing the pyrolysis and oxidation of diisopropyl ketone (DIPK) that was generated automatically using the Reaction Mechanism Generator (RMG) software package. The model predictions are evaluated against three experiments that cover a range of temperatures, pressures, and oxygen concentrations: (1) Synchrotron photoionization mass spectrometry (PIMS) measurements of pyrolysis in the range 800-1340. K at 30. Torr and 760. Torr; (2) Synchrotron PIMS measurements of laser photolytic Cl-initiated oxidation from 550. K to 700. K at 8. Torr; and (3) Rapid-compression machine measurements of ignition delay between 591. K and 720. K near 10. bar. Improvements made to the model parameters, particularly in the areas of hydrogen abstraction from the initial DIPK molecule and low-temperature peroxy chemistry, are discussed. Our ability to automatically generate this model and systematically improve its parameters without fitting to the experimental results demonstrates the usefulness of the predictive chemical kinetics paradigm.

    Original languageEnglish (US)
    Pages (from-to)711-724
    Number of pages14
    JournalCombustion and Flame
    Volume161
    Issue number3
    DOIs
    StatePublished - Mar 2014

    Keywords

    • Automatic mechanism generation
    • Combustion
    • Detailed kinetics modeling
    • Diisopropyl ketone
    • Ignition delay
    • Pyrolysis

    ASJC Scopus subject areas

    • General Chemistry
    • General Chemical Engineering
    • Fuel Technology
    • Energy Engineering and Power Technology
    • General Physics and Astronomy

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