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A. Agarwal and M.F. Trujillo (2019) “The Effect of Nozzle Internal Flow on Spray Atomization,” (accepted Int. J. Engine Research-ECN special issue).
D. Ryddner and M.F. Trujillo (2019) “A Study of Mass Loading Limits in Spray Desuperheating,”
Atomization and Sprays, 29(4), pp.305-329. R. Bardia and M.F. Trujillo (2019) “Assessing the Physical Validity of Highly-Resolved Simulation Benchmark Tests for Flows Undergoing Phase Change,”
International Journal of Multiphase Flow, 112, pp.52-62. M.F. Trujillo, S. Gurjar, M. Mason, and A. Agarwal (2018) “Global Characterization of the Spray Formation Process,”
Atomization and Sprays, 28(9), pp.811-835.
A. Agarwal and M.F. Trujillo (2018) “A Closer Look at Linear Stability Theory in Modeling Spray Atomization,” International Journal of Multiphase Flow, pp.1-13 (in press).
C.-W. Tsang, C.-W. Kuo, M. Trujillo, and C. Rutland (2018) “Evaluation and validation of Large-Eddy-Simulation sub-grid spray dispersion models using high-fidelity Volume-of-Fluid simulation data and engine combustion network experimental data,” . International Journal of Engine Research (in press)
L.Anumolu and M.F. Trujillo (2018) “Gradient augmented level set method for phase change simulations,” Journal of Computational Physics, 353:pp.377-406. M.F Trujillo, L. Anumolu, and D. Ryddner, (2018) “Direct Numerical Simulations for Two-Phase Flows with Phase Change,” Chapter 8 in
Encyclopedia of Two-Phase Heat Transfer and Flow III (Vol.1), World Scientific Publishers, Editor-in-chief, John R. Thome.
M.F Trujillo, L. Anumolu, and D. Ryddner (2017) “The distortion of the level set gradient under advection”, Journal of Computational Physics, 334:pp.81-101. M.F. Trujillo and Reitz, R.D. (2017) “Liquid Atomization and Spraying,” Chapter 4, section 18 published in
CRC Handbook of Thermal Engineering, 2 nd Edition, Taylo&Francis.
R. Bardia, Z. Liang, P. Keblinski, and M.F. Trujillo (2016) “Continuum and molecular-dynamics simulation of nanodroplet collisions,” Physical Review E, 93 (053104):pp.1-13.
S.S. Deshpande, S.R. Gurjar, and M.F. Trujillo (2015) “A Computational Study of an Atomizing Liquid Sheet,” Physics of Fluids, 27 (082108):pp.1-25. D.T. Ryddner and M.F. Trujillo (2015) “Modeling Urea-Water Solution Droplet Evaporation,”
Emission Control Science & Technology, 1:pp.80-97. C.-W. Tsang, M.F. Trujillo, and C.J. Rutland (2014) “Large-Eddy Simulation of Shear Flows and High-Speed Vaporizing Liquid Fuel Sprays,”
Computers & Fluids, 105:pp.262-279. R. Reitz, L. Pickett, and M.F. Trujillo (2014) “Fuel Introduction,”
Encyclopedia of Automotive Engineering, John Wiley & Sons, DOI: 10.1002/9781118354179.auto118. S.S. Deshpande, M.F. Trujillo, and S. Kim (2013) “Computational Study of Fluid Property Effects on the Capillary Breakup of a Ligament,”
Atomization and Sprays, 23:pp.1167-1195. S.R. Lewis, L. Anumolu, and M.F. Trujillo (2013) “Numerical Simulations of Droplet Train and Free Surface Jet Impingement,”
Int. J. Heat Fluid Flow, 44:pp.610-623. S.S. Deshpande and M.F. Trujillo (2013) ” Distinguishing Features of Shallow Angle Plunging Jets,”
Physics of Fluids, 25 (082103):pp.1-17. L. Anumolu and M.F. Trujillo (2013) “Gradient Augmented Reinitialization Scheme for the Level Set Method,”
International Journal of Numerical Methods in Fluids, pp.1011-1041. 73:
S.S. Deshpande, L. Anumolu, and M.F. Trujillo, (2012) “Evaluating the Performance of the Two-Phase Flow Solver interFoam,” Computational Science & Discovery, 5 (014016):pp.1-36.
M.F. Trujillo and S.R. Lewis (2012) “Thermal Boundary Layer Analysis Corresponding to Droplet Train Impingement, ” Physics of Fluids, 24 (112102):pp.1-22.
S.S. Deshpande, M.F. Trujillo, X. Wu, and G. Chahine, (2012) “Computational and Experimental Characterization of a Liquid Jet Plunging into a Quiescent Pool at Shallow Inclination,” Int. J. Heat Fluid Flow, 34:1-14.
S.S. Deshpande, J. Gao, and M.F. Trujillo, (2011) “Characteristics of Hollow Cone Sprays in Crossflow,” Atomization and Sprays 21:349-361.
M.F. Trujillo, J. Alvarado, E. Gehring, and G.S. Soriano, (2011) “Numerical Simulations and Experimental Characterization of Heat Transfer from a Periodic Impingement of Droplets,” J. Heat Trans. 133, 122201.
M.F. Trujillo and A.E. Parkhill, (2011) “A Local Lagrangian Analysis of Passive Particle Advection in a Gas Flow Field,” Int. J. Multiphase Flow 37:1201-1208, doi:10.1016/j.ijmultiphaseflow.2011.06.003
J. Gao, M.F. Trujillo, and S. Deshpande, (2011) “Numerical Simulation of Hollow-Cone Sprays Interacting with Uniform Crossflow for Gasoline Direct Injection Engines,” SAE Int. J. Engines 4:2207-2221, doi: 10.4271/2011-24-0007
B.A. Petrilla, M.F. Trujillo, and M.M. Micci, (2010) “n-Heptane Droplet Vaporization using Molecular Dynamics,” Atomization Sprays 20:581-593. E. Gehring, G.S. Soriano, J. Alvarado, and M.F. Trujillo (2010) “Film Dynamics Relevant to Spray Cooling,” Advanced Computational Methods and Experiments in Heat Transfer XI, WIT Press (2010).
R.L. Culver and M.F. Trujillo (2008) “Array Gain Degradation Due to Nearby Bubbles,”
The Journal of the Acoustical Society of America, 123, pp.3347. R.L. Culver and M.F. Trujillo (2007) “Effects of Scattering by Air Bubbles on Performance of an Underwater Acoustic Array,”
The Journal of the Acoustical Society of America, 121, pp.3033.
D.J. Torres and M.F. Trujillo, (2006) “KIVA-4: An Unstructured ALE Code for Compressible Gas Flow With Sprays,” J. Comput. Phys. 219:943-975 .
M.F. Trujillo, D.J. Torres, and P.J. O’Rourke, (2004) “High Pressure Multicomponent Liquid Sprays: Departure from Ideal Behavior,” Int. J. Engine Res. 5:229-246.
M.F. Trujillo and C.F. Lee, (2003) “Modeling Film Formation in Spray Impingement,” J. Fluid Eng. 125:104-112 .
M.F. Trujillo, P.O’Rourke, and D. Torres (2002) “Generalizing the Thermodynamics State Relationships in KIVA-3V,” Los Alamos Technical Report LA-13981.
M.F. Trujillo and C.F. Lee, (2001) “Modeling Crown Formation due to the Splashing of a Droplet,” Phys. Fluids 13:2503-2516.
M.F. Trujillo, W.S. Mathews, C.F. Lee, and J.E. Peters, (2000) “Modeling and Experiment of Impingement and Atomization of a Liquid Spray on a Wall,” Int. J. Engine Res. 1:87-105.