Skeletal Mechanism Generation
- K. E. Niemeyer, C. J. Sung, and M. P. Raju, “Skeletal Mechanism Generation for Surrogate Fuels using Directed Relation Graph with Error Propagation and Sensitivity Analysis,” Combustion and Flame 157 (9), 1760-1770 (2010).
- K. E. Niemeyer and C. J. Sung, “On the Importance of Graph Search Algorithms for DRGEP-based Mechanism Reduction Methods,” Combustion and Flame 158 (8), 1439-1443 (2011).
- K. E. Niemeyer and C. J. Sung, “Mechanism Reduction for Multicomponent Surrogates: A Case Study using Toluene Reference Fuels,” Combustion and Flame 161 (11), 2752-2764 (2014).
- K. E. Niemeyer and C. J. Sung, “Reduced Chemistry for a Gasoline Surrogate Valid at Engine-Relevant Conditions,” Energy and Fuels 29 (2), 1172-1185 (2015).
- N. J. Curtis, K. E. Niemeyer, and C. J. Sung, “An Automated Target Species Selection Method for Dynamic Adaptive Chemistry Simulations,” Combustion and Flame 162 (4), 1358-1374 (2015).
- F. Q. Zhong, S. G. Ma, X. Y. Zhang, C. J. Sung, and K. E. Niemeyer, “Development of Efficient and Accurate Skeletal Mechanisms for Hydrocarbon Fuels and Kerosene Surrogate,” Acta Mechanica Sinica 31 (5), 732-740 (2015).
- O. Samimi Abianeh, M. A. Oehlschlaeger, and C. J. Sung, “A Surrogate Mixture and Kinetic Mechanism for Emulating the Evaporation and Autoignition Characteristics of Gasoline Fuel”, Combustion and Flame 162 (10), 3773-3784 (2015).
- X. Hui, K. E. Niemeyer, K. B. Brady, and C. J. Sung, “Reduced Chemistry for Butanol Isomers at Engine-Relevant Conditions,” Energy and Fuels 31 (1), 867-881 (2017).