JetSurF (Version 1.0)

Release date: September 15, 2009

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Performance

How to cite

Performance That We Know:

Validation tests for the base model can be found at the USC-Mech II website:

·         Ignition Delays

·         Species Profiles in Shock-Tube Oxidation

·         Laminar Flame Speeds

·         Flow Reactor

·         Burner Stabilized Flames

These tests include the oxidation of H₂, CO, CH₄, C₂H₂, C₂H₄, C₂H₆, pC₃H₄ (propyne), aC₃H₄ (allene), C₃H₆, C₃H₈, 1,3-C₄H₆ (1,3-butadiene), 1-C₄H₈ (1-butene), n-C₄H₁₀ (n-butane).

For higher-hydrocarbons, validation tests include (with * indicating uncertainty analysis).

• Laminar flame speeds

n-dodecane-air mixtures, p = 1 atm, T_u = 403 K.*

            You, Egolfopoulos & Wang (2008)

C_kH_2k+2 (5 ≤ k ≤ 10)-air mixtures, f = 0.7 to 1.5, p = 1 atm, T_u = 353. K for 5 ≤ k ≤ 8 and 403 K for k = 9 & 10. *

            Ji, Dames, Y.L. Wang, H. Wang & Egolfopoulos (2009)

n-pentane, n-hexane & n-heptane-air mixtures, p = 1 atm, T_u = 298 K.

            Davis & Law (1998).

n-Heptane-air mixtures, p = 0.5 to 2 atm, T_u = 350 K.

            Smallbone et al. (2008).

n-Pentane-air mixtures, p = 1, 2, 5 & 10 atm, T_u = 353 K.

            Kelley & Law (2008).

• Ignition delay times behind reflected shock waves

n-dodecane-oxygen-nitrogen, p₅ = 20 atm.*

            Vasu, Davidson, Hong, Vasudevan & Hanson (2008).

n-decane-oxygen-argon and n-heptane-oxygen-argon mixtures, 1 ≤ p₅ ≤ 4 atm.

            Horning, Davidson & Hanson (2002).

n-heptane-oxygen-argon mixtures, 1 ≤ p₅ ≤ 2 atm.*

            Smith, Simmie & Curran (2005).

n-decane-oxygen-argon mixtures, p₅ = 13 atm.*

            Zhukov, Sechenov, Starikovskii (2008).

n-C_kH_2k+2 (5 ≤ k ≤ 9)-oxygen-argon mixtures (1.7 ≤ p₅ ≤ 5 atm).*  

            Davidson & Hanson (2008).

• Species profiles behind reflected shock waves

n-decane-oxygen-argon and n-heptane-oxygen-argon mixtures, p₅ = 2 atm.

            Davidson, Herbon, Horning & Hanson (2001).

n-heptane-oxygen-argon mixtures, (1.61 ≤ p₅ ≤ 1.72 atm).

            Davidson, Oehlschlaeger & Hanson (2007).

• Species concentration profiles in Jet-Stirred and Flow Reactors

n-dodecane pyrolysis in jet-stirred reactor (p = 1 atm).*

            Herbinet, Marquaire, Battin-Leclerc & Fournet (2007).

n-dodecane pyrolysis in plug flow reactor (p = 1 atm).

            Dahm, Virk, Bounaceur, Battin-Leclerc, Marquaire, Fournet, Daniau &  Bouchez (2004).

n-dodecane oxidation in a flow reactor as a function of temperature (p = 8 atm, t = 120 ms, 625 ≤ T ≤ 825 K)

            Kurman, Natelson, Cernansky & Miller (2009).