[1] S. Wallin and A. Johansson. "A complete explicit algebraic Reynolds stress model for incompressible and compressible flows". Journal of Fluid Mechanics. 403. 89–132. 2000.

[2] Fuel Cell Handbook (5th Edition). E G & G Services and Parsons Inc. and Science Applications International Corporation. 2000.

[3] Recommended Practice DNV-RP-C205. Environmental Conditions and Environmental Loads. Det Norske Veritas. October 2010.

[4] "Recommended Practice - RP O501 - Erosive Wear in Piping Systems". Rev 4.2. Det Norske Veritas. 2007.

[5] User Manual for 1993 Version Pulverized Coal Gasification and Combustion 3-Dimensional (pcgc-3). Advanced Combustion Engineering Research Center, Brigham Young University. 1993.

[6] J. Abrahamson. “Collision Rates of Small Particles in a Vigorously Turbulent Fluid”. Chemical Engineering Science. 30. 1371–1379. 1975.

[7] B. Abramzon and Sirignano. “Droplet Vaporization Model for Spray Combustion Calculations”. Int. J. Heat Mass Transfer. 32 (9). 1605-1689. 1989.

[8] M. Agrawal, A. Bakker, and M. T. Prinkey. "Macroscopic Particle Model – Tracking Big Particles in CFD". AIChE 2004 Annual Meeting. Particle Technology Forum - Paper 268b. Austin, Texas, USA: 2004.

[9] M. Agrawal, K. Ogawa. "Drag force formulation in macroscopic particle model and its validation". AIChE 2009 Annual Meeting. Paper 163b. Nashville, TN, USA: 2009.

[10] T. Ahmad, S. L. Plee, and J. P. Myers. "Computation of Nitric Oxide and Soot Emissions from Turbulent Diffusion Flames". J. of Engineering for Gas Turbines and Power. 107. 48–53. 1985.

[11] F. Akao, K. Araki, S. Mori, and A. Moriyama. Deformation Behaviors of a Liquid Droplet Impinging onto Hot Metal Surface. 107. 737–743. Trans. Iron and Steel Institute of Japan. 1980.

[12] 1. A. Åkesjö, M. Gourdon, L. Vamling, F. Innings, and S. Sasic . "Experimental and numerical study of heat transfer in a large–scale vertical falling film pilot unit". Int. J. of Heat and Mass Transfer. 125. 53–65. 2018.

[13] Shah Shahood Alam et al. "Single and multicomponent droplet models for spray applications". American J. Energy Eng.. Vol. 2. No. 5. 108–126. 1960.

[14] B. J. Alder and T. E. Wainwright. "Studies in Molecular Dynamics II: Behaviour of a Small Number of Elastic Spheres". J. Chem. Phys. 33. 1439. 1960.

[15] S. Alfaki, W. Tabakoff. “Erosion Study of Radial Flow Compressor With Splitters”. Transactions of the ASME. 109. 62-69. January 1987.

[16] A. A. Amsden. "KIVA-3: A KIVA Program with Block-Structured Mesh for Complex Geometries". Technical Report LA-12503-MS, UC-361. Los Alamos National Laboratory, Los Alamos, New Mexico. March 1993.

[17] M. Andersson, X. Lu, J. Yuan, and B. Sundén. "Analysis of Microscopic Anode Structure Effects on an Anode-Supported SOFC Including Knudsen Diffusion". ECS Transactions. 35 (1). 1799–1809. 2011.

[18] T. B. Anderson and R. Jackson. "A Fluid Mechanical Description of Fluidized Beds". I & EC Fundam. 6. 527–534. 1967.

[19] W. Anderson and D. L. Bonhus. "An Implicit Upwind Algorithm for Computing Turbulent Flows on Unstructured Grids". Computers Fluids. 23(1). 1–21. 1994.

[20] S. P. Antal, R. T. Lahey, and J. E. Flaherty. "Analysis of phase distribution in fully developed laminar bubbly two-phase flow". International Journal of Multiphase Flow. 17. 5. 635–652. 1991.

[21] A. Antifora, M. Sala, A. Perera, and L. Vigevano. "NOx Emissions in Combustion Systems of Coal Fired Furnaces with a Reducing Environment: Predictions and Measurements". Fourth International Conference on Technologies and Combustion for a Clean Environment. Lisbon, Portugal. 1997.

[22] J. Appel, H. Bockhorn, and M. Frenklach. "Kinetic Modeling of Soot Formation with Detailed Chemistry and Physics: Laminar Premixed Flames of C2 Hydrocarbons". Combustion and Flame. 121. 122 – 136. 2000.

[23] D.D. Apsley and M.A. Leschziner. "A new low-reynolds-number nonlinear two-equation turbulence model for complex flows". International Journal of Heat and Fluid Flow. 19. 209–222. 1998.

[24] S. V. Apte, M. Gorokhovski, and P. Moin. "LES of Atomizing Spray with Stochastic Modeling of Secondary Breakup". International Journal of Multiphase Flow. 29. 1503 –1522. 2003.

[25] S. V. Apte, K. Mahesh, and T. Lundgren. “Accounting for finite-size effects in simulations of dispersed particle-laden flows”. International Journal of Multiphase Flow. 34(3). 260–271. 2008.

[26] D. Aquaro and E. Fontani. “Erosion of ductile and brittle materials: comparison between theoretical and numerical models and experimental data”. AIMETA International Tribology Conference. 20-22. Aquila, Italy. September 2000.

[27] D. Aquaro and E. Fontani. “Erosion of ductile and brittle materials”. E. Meccanica. 36. 651-661. Aquila, Italy. 2001.

[28] S. Armsfield and R. Street. "The Fractional-Step Method for the Navier-Stokes Equations on Staggered Grids: Accuracy of Three Variations". Journal of Computational Physics. 153. 660–665. 1999.

[29] D. Arnal, M. Habiballah, and E. Coustols. "Théorie de l'instabilité laminaire et critères de transition en écoulement bi et tridimensionnel". La Recherche aérospatiale. 2. 125–143. 1984.

[30] M. J. Augenstein, A. M. Tenenbaum, Y. Langsam. Data Structures Using C. Prentice Hall. 1990.

[31] R.H. Aungier. "Centrifugal Compressors: A strategy for Aerodynamic Design and Analysis". ASME Press, New York. 2000.

[32] B. Aupoix. "Roughness Corrections for the k-ω Shear Stress Transport Model: Status and Proposals " . Journal of Fluids Engineering. 137.

[33] B. Aupoix, P. R. Spalart. "Extensions of the Spalart–Allmaras turbulence model to account for wall roughness ". International Journal of Heat and Fluid Flow. 2003. 24. 454-462.

[34] L. Austin, K. Shoji, V. Bhatia, V. Jindal, K. Savage, and R. Klimpel. “Some Results on the Description of Size Distribution as a Rate Process in Various Mills”. Industrial Engineering and Chemical Process Design Devices. 15(1). 187–196. 1976.

[35] F. Backmier, K. H. Eberius, and T. Just. Comb. Sci. Tech. 7. 77. 1973.

[36] S. Badzioch and P. G. W. Hawksley. "Kinetics of Thermal Decomposition of Pulverized Coal Particles". Ind. Eng. Chem. Process Design and Development. 9. 521–530. 1970.

[37] C. Bai and A. Gosman. "Development of Methodology for Spray Impingement Simulation". "SAE Technical Paper 950283". 1995.

[38] J. Baldyga. "Turbulent mixer model with application to homogeneous instantaneous chemical reactions". Chem. Eng. Sci. 44. 1175–1182. 1989.

[39] J. Baldyga and W. Orciuch. “Barium Sulfate Precipitation in a Pipe – An Experimental Study and CFD Modeling”. Chemical Engineering Science. 56. 2435–2444. 2001.

[40] R. S. Barlow, G. J. Fiechtner, C. D. Carter, and J. Y. Chen. "Experiments on the Scalar Structure of Turbulent CO// Jet Flames". Combustion and Flame. 120. 549–569. 2000.

[41] F. J. Barnes, J. H. Bromly, T. J. Edwards, and R. Madngezewsky. "NOx Emissions from Radiant Gas Burners". Journal of the Institute of Energy. 155. 184–188. 1988.

[42] J. C. Barrett and C. F. Clement. "Growth rates for liquid drops". J. Aerosol. Sci.. 19(2). 223-242. 1988.

[43] Y. Bartosiewicz, J. Lavieville, J.M. Seynhaeve. "A first assessment of the NEPTUNE_CFD code: instabilities in a stratified flow comparison between the VOF method and a two-field approach". International Journal of Heat and Fluid Flow. 29. 2. 2008.

[44] T. J. Barth and D. Jespersen. "The design and application of upwind schemes on unstructured meshes". Technical Report AIAA-89-0366. AIAA 27th Aerospace Sciences Meeting, Reno, Nevada. 1989.

[45] H. Barths, C. Antoni, and N. Peters. "Three-Dimensional Simulation of Pollutant Formation in a DI-Diesel Engine Using Multiple Interactive Flamelets". SAE Paper. SAE. 1998.

[46] H. Barths, N. Peters, N. Brehm, A. Mack M. Pfitzner, and V. Smiljanowski. "Simulation of pollutant formation in a gas turbine combustor using unsteady flamelets". 27th Symp. (Int’l.) on Combustion. The Combustion Institute. 1841–1847. 1998.

[47] G. K. Batchelor. An Introduction to Fluid Dynamics. Cambridge Univ.Press. Cambridge, England. 1967.

[48] D. L. Baulch, D. D. Drysdall, D. G. Horne, and A. C. Lloyd. Evaluated Kinetic Data for High Temperature Reactions. 1,2,3. Butterworth. 1973.

[49] D. L. Baulch et al. "Evaluated Kinetic Data for Combustion Modelling". J. Physical and Chemical Reference Data. 21(3). 1992.

[50] M. M. Baum and P. J. Street. "Predicting the Combustion Behavior of Coal Particles". Combust. Sci. Tech. 3(5). 231–243. 1971.

[51] K. J. Baumeister and F. F. Simon. "Leidenfrost Temperature—Its Correlation for Liquid Metals, Cryogens, Hydrocarbons, and Water". J. Heat Transfer. 95(2). 166–173. May 1973.

[52] L. L. Baxter. "Turbulent Transport of Particles". PhD Thesis. Brigham Young University, Provo, Utah. 1989.

[53] L. L. Baxter and P. J. Smith. "Turbulent Dispersion of Particles: The STP Model". Energy & Fuels. 7. 852–859. 1993.

[54] J. C. Beale and R. D. Reitz. "Modeling Spray Atomization with the Kelvin-Helmholtz/Rayleigh-Taylor Hybrid Model". Atomization and Sprays. 9. 623–650. 1999.

[55] W. Bechara, C. Bailly, P. Lafon, and S. Candel. "Stochastic Approach to Noise Modeling for Free Turbulent Flows". AIAA Journal. 32. 3. 1994.

[56] M. Behnia, S. Parneix, Y. Shabany, and P. A. Durbin. "Numerical Study of Turbulent Heat Transfer in Confined and Unconfined Impinging Jets". International Journal of Heat and Fluid Flow. 20. 1–9. 1999.

[57] F. Bhaktar, M. Piran. "Thermodynamic Properties of Supercooled Steam". Int. J. Heat and Fluid Flow. 1(2). 53–62. 1979.

[58] F. Bhaktar, K Zidi. "Nuleation Phenomena in Flowing High-Pressure Steam". Part 2: Theoretical Analysis, Proc. Instn. Mech. Engrs., Part A: Journal of Power and Energy. 204. 233–242.

[59] M. Asghar Bhatti. Advanced Topics in Finite Element Analysis of Structures: With Mathematica and MATLAB Computations. John Wiley and Sons, New York. 2006.

[60] R. W. Bilger and R. E. Beck. 15th Symp. (Int’l.) on Combustion. The Combustion Institute. 541. 1975.

[61] R. W. Bilger, M. B. Esler, and S. H. Starner. "On Reduced Mechanisms for Methane-Air Combustion". Lecture Notes in Physics. Springer-Verlag. 384. page 86. 1991.

[62] B. Binniger, M. Chan, G. Paczkko, and M. Herrmann. "Numerical Simulation of Turbulent Partially Premixed Hydrogen Flames with the Flamelet Model". Technical reportAdvanced Combustion Gmbh. Internal Report. 1998.

[63] G. A. Bird. Molecular Gas Dynamics and the direct Simulation of Gas Flows. Oxford University Press, New York. 1994.

[64] G. Blanquart, H. Pitsch. “A Joint Volume-Surface-Hydrogen Multi-Variate Model for Soot Formation, in Combustion Generated Fine Carbonaceous Particles”. Karlsruhe University Press. 439-466. 2009.

[65] F. Birkhold. “Selektive katalytische Reduktion von Stickoxiden in Kraftfahrzeugen: Untersuchung der Einspritzung von Harnstoffwasserlösung”. Dissertation. University of Karlsruhe. 541. 2007.

[66] F. Birkhold, U. Meingast, P. Wassermann, and O. Deutschmann. “Analysis of the Injection of Urea-Water-Solution for Automotive SCR DeNOx-Systems: Modeling of Two-Phase Flow and Spray/Wall-Interaction”. SAE Technical Paper 2006-01-0643. University of Karlsruhe. 2006.

[67] F. Birkhold, U. Meingast, P. Wassermann, and O. Deutschmann. “Modeling and simulation of the injection of urea-water-solution for automotive SCR DeNOx-systems”. Applied Catalysis B: Environmental. 70(1). 119-127. 2007.

[68] J. Blauvens, B. Smets, and J. Peters. In 16th Symp.(Int’l.) on Combustion. The Combustion Institute. 1977.

[69] Blint. Principles of Combustion. Wiley-Interscience. New York1988.

[70] P. Boudier and et al. "A model for Turbulent Flame Ignition and Propagation in Spark Ignition Engines". In Twenty Fourth Symposium (international) on Combustion, Sydney, Australia. 1992.

[71] R. M. Bowen. "Theory of Mixtures". In A. C. Eringen, editorContinuum Physics. Academic Press, New York. 1–127. 1976.

[72] C. T. Bowman. "Chemistry of Gaseous Pollutant Formation and Destruction". In W. Bartok and A. F. Sarofim, editorsFossil Fuel Combustion. J. Wiley and Sons, Canada. 1991.

[73] R. K. Boyd and J. H. Kent. "Three-dimensional furnace computer modeling". In 21st Symp. (Int’l.) on Combustion. The Combustion Institute. 265–274. 1986.

[74] J. U. Brackbill, D. B. Kothe, and C. Zemach. "A Continuum Method for Modeling Surface Tension". J. Comput. Phys. 100. 335–354. 1992.

[75] A. Brandt. "Multi-level Adaptive Computations in Fluid Dynamics". Technical Report AIAA-79-1455. AIAA, Williamsburg, VA. 1979.

[76] K. Bray, P. Domingo and L. Vervisch. "Role of the Progress Variable in Models for Partially Premixed Turbulent Combustion". Combustion and Flame. 141. 431–437. 2005.

[77] K. N. Bray and N. Peters. "Laminar Flamelets in Turbulent Flames". In P. A. Libby and F. A. Williams, editorsTurbulent Reacting Flows. Academic Press. 63–114. 1994.

[78] C. E. Brennen. Cavitation and Bubble Dynamics. Oxford University Press. 1995.

[79] K. S. Brentner and F. Farassat. "An Analytical Comparison of the Acoustic Analogy and Kirchhoff Formulations for Moving Surfaces". AIAA Journal. 36(8). 1998.

[80] M. Brocchini, D.H. Peregrine. "The dynamics of strong turbulence at free sur-faces, part 1: description". J. Fluid Mech.. 449. 225–254. 2001.

[81] S. J. Brookes and J. B. Moss. "Prediction of Soot and Thermal Radiation in Confined Turbulent Jet Diffusion Flames". Combustion and Flame. 116. 486–503. 1999.

[82] J. Brouwer, M. P. Heap, D. W. Pershing, and P. J. Smith. "A Model for Prediction of Selective Non-Catalytic Reduction of Nitrogen Oxides by Ammonia, Urea, and Cyanuric Acid with Mixing Limitations in the Presence of CO". In 26th Symposium (Int’l) on Combustion. The Combustion Institute. 1996.

[83] A. L. Brown. "Modeling Soot in Pulverized Coal Flames". MSc thesis. Brigham Young University, Utah, USA. 1997.

[84] A. Brucato, F. Grisafi, and G. Montante. “Particle drag coefficients in turbulent fluids”. Chemical Engineering Science. 53(18). 3295–3314. 1998.

[85] S. Brunauer. The Absorption of Gases and Vapors. Princeton University Press, Princeton, NJ. 1943.

[86] M. Budakli . "Hydrodynamics and Heat Transfer in Gas–Driven Liquid Film Flow". PhD Thesis. Institute of Technical Thermodynamics of the Technische Universitat Darmstadt, Germany. 2015.

[87] Trong T. Bui. "A Parallel Finite-Volume Algorithm for Large-Eddy Simulation of Turbulent Flows". Technical Memorandum NASA/TM-1999-206570. 1999.

[88] A. D. B. Burns, Th. Frank, I. Hamill, and J.-M. Shi. The Favre Averaged Drag Model for Turbulent Dispersion in Eulerian Multi-Phase Flows. Fifth International Conference on Multiphase Flow, ICMF-2004, Yokohama, Japan. 2004.

[89] D. Butterworth. "The correlation of cross flow pressure drop data by means of a permeability concept". UKAEA Report AERE–R9435. 1979.

[90] L. Cai and R. E. White. “Reduction of Model Order Based on Proper Orthogonal Decomposition for Lithium-Ion Battery Simulations”. J. of Electrochemical Soc.. 156(3). A154-A161. 2009.

[91] S. Candel and T. Poinsot. "Flame stretch and the balance equation for the flame area". Combustion Science and Technology. 70. 1–15. 1990.

[92] R. Cao and S. B. Pope. "Numerical Integration of Stochastic Differential Equations: Weak Second-Order Mid-Point Scheme for Application in the Composition PDF Method". Journal of Computational Physics. 185(1). 194–212. 2003.

[93] N. F. Carnahan and K. E. Starling. "Equations of State for Non-Attracting Rigid Spheres". J. Chem. Phys. 51. 635–636. 1969.

[94] M. G. Carvalho, T. Farias, and P. Fontes. "Predicting Radiative Heat Transfer in Absorbing, Emitting, and Scattering Media Using the Discrete Transfer Method". In W. A. Fiveland et al., editorFundamentals of Radiation Heat Transfer. 160. ASME HTD. pages 17–26. 1991.

[95] J. R. Cash and A. H. Karp. "A variable order Runge-Kutta method for initial value problems with rapidly varying right-hand sides". ACM Transactions on Mathematical Software. 16. 201–222. 1990.

[96] G.V. Candler, and R.W. MacCormack. "Computation of Weakly Ionized Hypersonic Flows in Thermochemical Nonequilibrium". Journal of Thermophysics and Heat Transfer . 5. 3. 266–273. 1991.

[97] Cantera. http://sourceforge.net/projects/cantera/ . 2012.

[98] T. Cebeci and P. Bradshaw. Momentum Transfer in Boundary Layers. Hemisphere Publishing Corporation, New York. 1977.

[99] S. Chapman and T. G. Cowling. The Mathematical Theory of Non-Uniform Gases. 3rd edition. Cambridge University Press, Cambridge, England. 1990.

[100] F. Charlette, C. Meneveau, and D. Veynante. "A Power-Law Flame Wrinkling Model for LES of Premixed Turbulent Combustion, Part I: Non-Dynamic Formulation and Initial Tests". Combustion and Flame. 131. 1–2. 159–180. 2002.

[101] S. Charpenay, M. A. Serio, and P. R. Solomon. In 24th Symp. (Int’l.) on Combustion. 1189–1197. The Combustion Institute. 1992.

[102] CHEMKIN-PRO 15112. Reaction Design. San Diego: 2012.

[103] H. C. Chen and V. C. Patel. "Near-Wall Turbulence Models for Complex Flows Including Separation". AIAA Journal. 26(6). 641–648. 1988.

[104] J. C. Chen. "Correlation for Boiling Heat Transfer to Saturated Fluids in Convective Flow". Industrial & Engineering Chemistry Process Design and Development. 5. 322–329. 1966.

[105] M. Chen and G. A. Rincon-Mora. “Accurate Electrical Battery Model Capable of Predicting Runtime and I-V Performance”. IEEE Trans. On Energy Conversion. Vol. 21. No.2. A154-A161. June 2006.

[106] P. Cheng. "Two-Dimensional Radiating Gas Flow by a Moment Method". AIAA Journal. 2. 1662–1664. 1964.

[107] R. V. Chima and M. S. Liou. "Comparison of the AUSM+ and H-CUSP Schemes for Turbomachinery Applications". NASA TM-2003-212457. 2003.

[108] A. J. Chorin. "Numerical solution of navier-stokes equations". Mathematics of Computation. 22. 745–762. 1968.

[109] B. H. Chowdhury. "Emission Control Alternatives for Electric Utility Power Plants". Energy Sources. 18(4). 393–406. October 1996.

[110] E. H. Chui and G. D. Raithby. "Computation of Radiant Heat Transfer on a Non-Orthogonal Mesh Using the Finite-Volume Method". Numerical Heat Transfer, Part B. 23. 269–288. 1993.

[111] Clift, Grace, and Weber. "Bubbles, Drops, and Particles". Technical Report. Academic Press. 1978.

[112] P. J. Coelho and N. Peters. "Unsteady Modelling of a Piloted Methane/Air Jet Flame Based on the Eulerian Particle Flamelet Model". Combustion and Flame. 122. 444–465. 2001.

[113] M. F. Cohen and D. P. Greenberg. "The hemi-cube: a radiosity solution for complex environments". ACM SIGGRAPH Computer Graphics. 19(3). 31–40. 1985.

[114] D. Cokljat, V. A. Ivanov, F. J. Sarasola, and S. A. Vasquez. "Multiphase k-epsilon Models for Unstructured Meshes". In ASME 2000 Fluids Engineering Division Summer Meeting. Boston, MA, USA. 2000.

[115] D. Cokljat, M. Slack, and S. A. Vasquez. "Reynolds-Stress Model for Eulerian Multiphase". In Y. Nagano K. Hanjalic and M. J. Tummers, editors. Proceedings of the 4th International Symposium on Turbulence Heat and Mass Transfer. Begell House, Inc. 1047–1054. 2003.

[116] R. Cole. "A Photographic Study of Pool Boiling in the Region of the Critical Heat Flux". AIChE J. 6. 533–542. 1960.

[117] H. W. Coleman and B. K. Hodge and R. P. Taylor. "A Re-Evaluation of Schlichting’s Surface Roughness Experiment". Journal of Fluids Engineering. 106. 1984.

[118] O. Colin, C. Angelberger, and A. Benkenida. "3D Modeling of Mixing, Ignition and Combustion Phenomena in Highly Stratified Gasoline Engines". Oil & Gas Science and Technology. Rev IFP. 58. 1. 47–62. 2003.

[119] O. Colin, F. Ducros, D. Venante, T. Poinsot . "A thickened flame model for large eddy simulations of turbulent premixed combustion". Physics of Fluids. 12. 7. 1843–1863. 2000.

[120] P. T. Coman, E.C. Darcy, C.T. Veje, and R.E. White. "Modelling Li-Ion Cell Thermal Runaway Triggered by an Internal Short Circuit Device Using an Efficiency Factor and Arrhenius Formulations". Journal of the Electrochemical Society. 164. 4. A587–A593. 2017.

[121] A. Coppalle and P. Vervisch. "The Total Emissivities of High-Temperature Flames". Combustion and Flame. 49. 101–108. 1983.

[122] S. M. Correa. "A Review of NOx Formation Under Gas-Turbine Combustion Conditions". Combustion Science and Technology. 87. 329–362. 1992.

[123] C. A. Coulaloglou and L. L. Tavlarides. “Description of Interaction Processes in Agitated Liquid-Liquid Dispersions”. Chemical Engineering Science. 32. 1289–1297. 1977.

[124] C. Crowe, M. Sommerfield, and Yutaka Tsuji. Multiphase Flows with Droplets and Particles. CRC Press. 1998.

[125] G. T. Csanady. "Turbulent Diffusion of Heavy Particles in the Atmosphere". J. Atmos. Science. 20. 201–208. 1963.

[126] P. A. Cundall and O. D. L. Strack. "A Discrete Numerical Model for Granular Assemblies". Geotechnique. 29. 47–65. 1979.

[127] Yang H.Q., Shinghal A.K., Megahed M., . "The Full Cavitation Model". VKI, Lecture Series 2005-04, Industrial Two-Phase Flow CFD. May 23-27, 2005.

[128] N. Curle. "The Influence of Solid Boundaries upon Aerodynamic Sound". Proceedings of the Royal Society of London. Series A, Mathematical and Physical Sciences, 231. 505–514. 1955.

[129] J. Dacles-Mariani, G. G. Zilliac, J. S. Chow, and P. Bradshaw. "Numerical/Experimental Study of a Wingtip Vortex in the Near Field". AIAA Journal. 33(9). 1561–1568. 1995.

[130] D. Dajnak and F. C. Lockwood. "Modelling of Toxic Heavy Metal Mercury Partitioning from Pulverized Fuel Combustion". IFRF Combustion Journal.

[131] J. M. Dalla Valle. Micromeritics. Pitman, London. 1948.

[132] B. J. Daly and F. H. Harlow. "Transport Equations in Turbulence". Phys. Fluids. 13. 2634–2649. 1970.

[133] S. Das, H. Punekar. "On Development of a Semi-Mechanistic Wall Boiling Model". Journal of Heat Transfer. 138. 6. 061501-1–10. 2005. February 2016.

[134] J. F. Daunenhofer and J. R. Baron. "Grid Adaption for the 2D Euler Equations". Technical Report AIAA-85-0484. American Institute of Aeronautics and Astronautics. 1985.

[135] Deendarlianto; T. Höhne, D. Lucas, C. Vallée, G. Montoya. "CFD studies on the phenomena around counter-current flow limitations of gas/liquid two-phase flow in a model of a PWR hot leg". Nuclear Eng. and Des.. 241. 12. 5138–5148. 2011.

[136] V. H. Del Valle and D. B. R. Kenning. "Subcooled flow boiling at high heat flux". International Journal of Heat and Mass Transfer. 28(10). 1907–1920. 1985.

[137] S. C. R. Dennis, S. N. Singh, D. B. Ingham. "The steady flow due to a rotating sphere at low and moderate Reynolds numbers". J. Fluid Mech.. 101. 257-279. 1980.

[138] M. K. Denison and B. W. Webb. "A Spectral Line-Based Weighted-Sum-of-Gray-Gases Model for Arbitrary RTE Solvers". J. Heat Transfer. 115. 1002–1012. 1993.

[139] G. G. DeSoete. "Overall Reaction Rates of NO and Formation from Fuel Nitrogen". In 15th Symp. (Int’l.) on Combustion. The Combustion Institute. 1093–1102. 1975.

[140] H. Dette and W. J. Studden. The Theory of Canonical Moments with Applications in Statistics, Probability, and Analysis. John Wiley & Sons. New York, NY1997.

[141] R. B. Diemer and J. H. Olson. “A Moment Methodology for Coagulation and Breakage Problems Part 3—Generalized Daughter Distribution Functions”. Chemical Engineering Science. 57(19). 4187–4198. 2002.

[142] J. Ding and D. Gidaspow. "A Bubbling Fluidization Model Using Kinetic Theory of Granular Flow". AIChE J. 36(4). 523–538. 1990.

[143] G. Dixon-Lewis. "Structure of Laminar Flames". In 23rd Symp. (Int’l.) on Combustion. The Combustion Institute. 305–324. 1990.

[144] N. Dombrowski and P. C. Hooper. "The effect of ambient density or drop formation in sprays". Chemical Engineering Science. 17. 291–305. 1962.

[145] N. Dombrowski and W. R. Johns. "The Aerodynamic Instability and Disintegration of Viscous Liquid Sheets". Chemical Engineering Science. 18. 203. 1963.

[146] C. Dopazo and E. E. O’Brien. "Functional Formulation of Nonisothermal Turbulent Reactive Flows". Phys. Fluids. 17. 1968. 1975.

[147] A. M. Douaud and P. Eyzat. "Four-Octane-Number Method for Predicting the Anti-Knock Behavior of Fuels in Engines". SAE Technical Paper. v87 780080. SAE. 1978.

[148] M. Doyle, T. F. Fuller and J. Newman. “Modeling of Galvanostatic Charge and Discharge of the Lithium/Polymer/Insertion Cell”. J. of Electrochemical Soc.. Vol 140, No. 6. 1526-1533. 1993.

[149] M. C. Drake and R. J. Blint. "Relative Importance of Nitrogen Oxide Formation Mechanisms in Laminar Opposed-Flow Diffusion Flames". Combustion and Flame. 83. 185–203. 1991.

[150] M. C. Drake, S. M. Correa, R. W. Pitz, W. Shyy, and C. P. Fenimore. "Superequilibrium and Thermal Nitric Oxide Formation in Turbulent Diffusion Flames". Combustion and Flame. 69. 347–365. 1987.

[151] M. C. Drake, R. W. Pitz, M. Lapp, C. P. Fenimore, R. P. Lucht, D. W. Sweeney, and N. M. Laurendeau. In 20th Symp. (Int’l.) on Combustion. The Combustion Institute. 327. 1984.

[152] D. A. Drew and R. T. Lahey. In Particulate Two-Phase Flow. Butterworth-Heinemann. Boston, MA509–566. 1993.

[153] J. K. Dukowwicz and A. S. Dvinsky. "Approximate Factorization as a High-Order Splitting for the Implicit Incompressible Flow Equations". Journal of Computational Physics. 102. 336–347. 1992.

[154] L. Durand and W. Polifke. "Implementation of the Thickened Flame Model for Large Eddy Simulation of Turbulent Premixed Combustion in a Commercial Solver". ASME Turbo Expo 2007: Power for Land, Sea, and Air. GT2007-28188. 869–878. 2007.

[155] P. A. Durbin. "Separated Flow Computations with the - - Model". AIAA Journal. 33(4). 659–664. 1995.

[156] Brandon M. Eaton. "One-dimensional, Transient Model of Heat, Mass, and Charge Transfer in a Proton Exchange Membrane". M.S. Thesis. 2001.

[157] E. R. G. Eckert and R. M. Drake. Analysis of Heat and Mass Transfer. McGraw-Hill Co. 1972.

[158] D. K. Edwards and R. Matavosian. "Scaling Rules for Total Absorptivity and Emissivity of Gases". J. Heat Transfer. 106. 684–689. 1984.

[159] J. K. Edwards, B. S. McLaury, and S. A. Shirazi. "Supplementing a CFD Code with Erosion Prediction Capabilities". In Proceedings of ASME FEDSM’98: ASME 1998 Fluids Engineering Division Summer Meeting, Washington DC. June 1998.

[160] J. K. Edwards, B. S. McLaury, and S. A. Shirazi. "Evaluation of Alternative Pipe Bend Fittings in Erosive Service". In Proceedings of ASME FEDSM’00: ASME 2000 Fluids Engineering Division Summer Meeting, Boston, MA. June 2000.

[161] Y. Egorov. "Contact Condensation in Stratified Steam-Water Flow". EVOL-ECORDA-D 07. 2004.

[162] Y. Egorov, F. Menter. "Contact Condensation in Stratified Steam–Water Flow". EVOL-ECORA-D 07. 2004.

[163] S. E. Elgobashi and T. W. Abou-Arab. "A Two-Equation Turbulence Model for Two-Phase Flows". Phys. Fluids. 26(4). 931–938. 1983.

[164] S. Ergun. "Fluid Flow through Packed Columns". Chem. Eng. Prog. 48(2). 89–94. 1952.

[165] G. Erlebacher, M. Y. Hussaini, C. G. Speziale, and T. A. Zang. "Toward the Large-Eddy Simulation of Compressible Turbulent Flows". J. Fluid Mech. 238. 155–185. 1992.

[166] M.J. Evans, C. Petre, P.R. Medwell, and A. Parente. "Generalisation of the eddy-dissipation concept for jet flames with low turbulence and low Damköhler number". Proceedings of the Combustion Institute. 37. 4497–4505. 2019.

[167] J. Ewald. "A Level Set Based Flamelet Model for the Prediction of Combustion in Homogeneous Charge and Direct Injection Spark Ignition Engines". PhD Thesis. Aachen University. 2006.

[168] R. Ewert and W. Schroeder. "Acoustic perturbation equations based on flow decomposition via source filtering". Journal of Computational Physics. Volume 188, Issue 2. 365–398. 2003.

[169] R. Fan, D. L. Marchisio and R. O. Fox. Application of the Direct Quadrature Method of Moments to Poly-disperse Gas-solid Fluidized Beds. Power Technology. 139. 7–20. 2004.

[170] R. F. Fedors and R. F. Landell. "An Empirical Method of Estimating the Void Fraction in Mixtures of Uniform Particles of Different Size". Powder Technology. 23. 225–231.

[171] C. P. Fenimore. "Formation of Nitric Oxide in Premixed Hydrocarbon Flames". In 13th Symp.(Int’l.)on Combustion. The Combustion Institute. 373. 1971.

[172] C. P. Fenimore. "Destruction of NO by in Lean Burnt Gas". Combustion and Flame. 37. 245. 1980.

[173] C. P. Fenimore and G. W. Jones. "Oxidation of soot by hydroxyl radicals". J. Phys. Chem. 71. 593–597. 1967.

[174] John D. Fenton. "A Fifth-Order Stokes Theory for Steady Waves". Journal of Waterway, Port, Coastal and Ocean Engineering. 111, No.2. March 1985.

[175] John D. Fenton. "The Cnoidal Theory of Water Waves". Developments in Offshore Engineering. J. B. Herbich, Houston. 1998.

[176] M. Ferrarotti, Z. Li, and A. Parente. "On the role of mixing models in the simulation of MILD combustion using finite-rate chemistry combustion models". Proceedings of the Combustion Institute. 37. 4. 4531–4538. 2019.

[177] J. L. Ferzieger and M. Peric. Computational Methods for Fluid Dynamics. Springer-Verlag, Heidelberg. 1996.

[178] J. E. Ffowcs-Williams and D. L. Hawkings. "Sound Generation by Turbulence and Surfaces in Arbitrary Motion". Proc. Roy. Soc. London. A264. 321–342. 1969.

[179] M. A. Field. "Rate of Combustion of Size-Graded Fractions of Char from a Low Rank Coal between 1200 K–2000 K". Combustion and Flame. 13. 237–252. 1969.

[180] I. Finnie. "Erosion of Surfaces by Solid Particles". Wear. 3. 87–103. 1960.

[181] W. A. Fiveland and A. S. Jamaluddin. "Three-Dimensional Spectral Radiative Heat Transfer Solutions by the Discrete Ordinates Method". Heat Transfer Phenomena in Radiation, Combustion and Fires. HTD Vol. 10643–48. 1989.

[182] T. H. Fletcher and D. R. Hardesty. "Compilation of Sandia coal devolatilization data: Milestone report". Sandia Report SAND92-8209. 1992.

[183] T. H. Fletcher and A. R. Kerstein. "Chemical percolation model for devolatilization: 3. Direct use of C NMR data to predict effects of coal type". Energy and Fuels. 6. 414. 1992.

[184] T. H. Fletcher, A. R. Kerstein, R. J. Pugmire, and D. M. Grant. "Chemical percolation model for devolatilization: 2. Temperature and heating rate effects on product yields". Energy and Fuels. 4. 54. 1990.

[185] P. J. Flory. “Thermodynamics of High Polymer Solutions”. Journal of Chemical Physics. 10. 51–61. 1942.

[186] W. L. Flower, R. K. Hanson, and C. H. Kruger. In 15th Symp. (Int’l.) on Combustion. The Combustion Institute. 823. 1975.

[187] R. O. Fox. Computational Models for Turbulent Reacting Flows. Cambridge University Press, Cambridge, England. 2003.

[188] J. A. Foucart, Private Communication .

[189] Th. Frank. "Parallele Algorithmen für die numerische Simulation dreidimensionaler, disperser Mehrphasenströmungen und deren Anwendung in der Verfahrenstechnick". Chemnitz, Techn. Univ., Habil-Schr. Shaker Verlag. 2002.

[190] Th. Frank, J. M. Shi, and A. D. Burns. "Validation of Eulerian Multiphase Flow Models for Nuclear Safety Applications". Third International Symposium on Two-Phase Flow Modeling and Experimentation, Pisa, Italy. Sept. 22–24, 2004.

[191] Th. Frank, P. J. Zwart, E. Krepper, H.-M. Prasser, and D. Lucas. "Validation of CFD models for mono- and polydisperse air-water two-phase flows in pipes". J. Nuclear Engineering & Design. 238. 647–659. March 2008.

[192] M. Frenklach. "Method of moments with interpolative closure". Chemical Engineering Science. 57. 2229-2239. 2002.

[193] M. A. Friedrich, H. Lan, J. L. Wegner, J. A. Drallmeier, and B. F. Armaly . "A Separation Criterion with Experimental Validation for Shear-Driven Films in Separated Flows". Journal of Fluids Engineering. 130. May 2008.

[194] S. Fu, B. E. Launder, and M. A. Leschziner. "Modeling Strongly Swirling Recirculating Jet Flow with Reynolds-Stress Transport Closures". In Sixth Symposium on Turbulent Shear Flows. Toulouse, France. 1987.

[195] B. Gampert. Grenzschichttheoretische Probleme des aerodynamischen Schmelzspinnprozesses. PhD Thesis from the Technical University of Berlin. Berlin, Germany 1973.

[196] F. Garcia-Ochoa and E. Gomez. "Bioreactor scale-up and oxygen transfer rate in microbial processes: An overview". Biotechnology Advances. 27(2). 153–176. 2009.

[197] J. Garside and M. R. Al-Dibouni. "Velocity-Voidage Relationships for Fluidization and Sedimentation". I & EC Process Des. Dev. 16. 206–214. 1977.

[198] J. A. Gasper, N. C. Widmer, J. A. Cole, and W. R. Seeker. "Study of Mercury Speciation in a Simulated Municipal Waste Incinerator Flue". In Proceedings of 1997 International Conference on Incineration and Thermal Treatment Technologies. Oakland, California. 1997.

[199] M. Germano, U. Piomelli, P. Moin, and W. H. Cabot. "Dynamic Subgrid-Scale Eddy Viscosity Model". In Summer Workshop. Center for Turbulence Research, Stanford, CA. 1996.

[200] T. Gessner. "Dynamic Mesh Adaption for Supersonic Combustion Waves Modeled with Detailed Reaction Mechanisms". PhD thesis. University of Freiburg, Freiburg, Germany. 2001.

[201] M. Ghadiri and Z. Zhang. “Impact Attrition of Particulate Solids Part 1. A Theoretical Model of Chipping”. Chemical Engineering Science. 57. 3659–3669. 2002.

[202] L. G. Gibilaro, R. Di Felice and S. P. Waldram. "Generalized Friction Factor and Drag Coefficient Correlations for Fluid-particle Interactions". Chem. Eng. Sci. 40(10). 1817-1823. 1985.

[203] M. M. Gibson and B. E. Launder. "Ground Effects on Pressure Fluctuations in the Atmospheric Boundary Layer". J. Fluid Mech. 86. 491–511. 1978.

[204] D. Gidaspow. Multiphase Flow and Fluidization. Academic Press, Boston, MA. 1994.

[205] D. Gidaspow, R. Bezburuah, and J. Ding. "Hydrodynamics of Circulating Fluidized Beds, Kinetic Theory Approach". In Fluidization VII, Proceedings of the 7th Engineering Foundation Conference on Fluidization. 75–82. 1992.

[206] R. G. Gilbert, K. Luther, and J. Troe. Ber. Bunsenges. Phys. Chem. 87. 1983.

[207] P. Glarborg, J. E. Johnsson, and K. Dam-Johansen. "Kinetics of Homogeneous Nitrous Oxide Decomposition”. Combustion and Flame. ,99. 523–532. 1994.

[208] H. M. Glaz J. B. Bell, P. Colella. "Second-Order Projection Method for the Incompressible Navier-Stokes Equations". Journal of Computational Physics. 85. 257. 1989.

[209] H. M. Glaz J. B. Bell, P. Colella. "An Analysis of the Fractional-Step Method". Journal of Computational Physics. 108. 51–58. 1993.

[210] A. Gnanavelu, N. Kapur, A. Neville, J. F. Flores, N. Ghorbani. "A numerical investigation of a geometry independent integrated method to predict erosion rates in slurry erosion”. J. Wear. 271. 712-719. 2011.

[211] P. A. Gnoffo, R. N. Gupta, and J. L. Shinn. "Conservation Equations and Physical Models for Hypersonic Air Flows in Thermal and Chemical Nonequilibrium”. NASA. TP-2867. 1989.

[212] G. Goldin, A. Colclasure, A. Wiedemann, and R. Kee. "Three-dimensional Particle-resolved Models of Li-ion Batteries to Assist the Evaluation of Empirical Parameters in One-Dimensional Models". Electrochemica Acta. 64. 118–129. 2012.

[213] R. G. Gordon. “Error Bounds in Equilibrium Statistical Mechanics”. Journal of Mathematical Physics. 56. 655–633. 1968.

[214] H. Görgün, M. Arcak, and F Barbir. "An algorithm for estimation of membrane water content in PEM fuel cells". Journal of power sources . 157. 1. 389–394. 2006.

[215] A. D. Gosman and E. Ioannides. "Aspects of computer simulation of liquid-fuelled combustors". J. Energy. 7(6). 482–490. 1983.

[216] J. Gottgens, F. Mauss, and N. Peters. "Analytic Approximations of Burning Velocities and Flame Thicknesses of Lean Hydrogen, Methane, Ethylene, Ethane, Acetylene and Propane Flames". In Twenty-Fourth Symposium (Int.) on Combustion, Pittsburgh. 29–135. 1992.

[217] I. R. Gran and B. F. Magnussen. "A numerical study of a bluff-body stabilized diffusion flame. part 2. influence of combustion modeling and finite-rate chemistry". Combustion Science and Technology. 119. 191. 1996.

[218] D. M. Grant, R. J. Pugmire, T. H. Fletcher, and A. R. Kerstein. "Chemical percolation model of coal devolatilization using percolation lattice statistics". Energy and Fuels. 3. 175. 1989.

[219] M. S. Gritskevich, A. V. Garbaruk, J. Schutze, F. R. Menter. "Development of DDES and IDDES Formulations for the k-ω Shear Stress Transport Model”. Flow, Turbulence and Combustion. 88(3). 431–449. 2012.

[220] H. Gu. “Mathematical Analysis of a Zn/NiOOH Cell”. J. Electrochemical Soc.. Princeton, NJ. 1459-1. 464. July 1983.

[221] W. Gumprich, M. Chrigui, M. Braun, A. Sadiki. "Evaluation of collision models applied to varying dense particle jets flows". 7th International Conference on Multiphase Flow. Tampa, FL: May 30 – June 4, 2010.

[222] D. J. Gunn. "Transfer of Heat or Mass to Particles in Fixed and Fluidized Beds". Int. J. Heat Mass Transfer. 21. 467–476. 1978.

[223] G. Gwak, H. Ju. "A rapid start-up strategy for polymer electrolyte fuel cells at subzero temperatures based on control of the operating current density". Int. J. of Hydrogen Energy. 40(35). 11989–11997. 2015.

[224] Hagesaether L., Jakobsen H.A.1, and Svendsen H. F. “A Model for Turbulent Binary Breakup of Dispersed Fluid Particles”. Chemical Engineering Science. 57(16). 3251–3267. 2002.

[225] W. W. Hagerty and J. F. Shea. "A Study of the Stability of Plane Fluid Sheets". Journal of Applied Mechanics. 22. 509. 1955.

[226] A. Haider and O. Levenspiel. "Drag Coefficient and Terminal Velocity of Spherical and Nonspherical Particles". Powder Technology. 58. 63–70. 1989.

[227] B. Hall. "An Experimental Study of Mercury Reactions in Combustion Flue Gases". PhD thesis. Chalmers University of Technology, Sweden. 1991.

[228] R. J. Hall, M. D. Smooke, and M. B. Colket. Physical and Chemical Aspects of Combustion. Gordon and Breach. 1997.

[229] M. P. Halstead, L. J. Kirsch, and C. P. Quinn. "Autoignition of Hydrocarbon Fuels at High Temperatures and Pressures – Fitting of a Mathematical Model". Combustion and Flame. 30. 45–60. 1977.

[230] Z. Han, S. Perrish, P. V. Farrell, and R. D. Reitz. "Modeling Atomization Processes of Pressure-Swirl Hollow-Cone Fuel Sprays". Atomization and Sprays. 7(6). 663–684. Nov.-Dec. 1997.

[231] G. Hand, M. Missaghi, M. Pourkashanian, and A. Williams. "Experimental Studies and Computer Modeling of Nitrogen Oxides in a Cylindrical Furnace". In Proceedings of the Ninth Members Conference. volume 2. IFRF Doc No K21/g/301989.

[232] S. Hänsch, D. Lucas, Höhne, E. Krepper, G. Montoya. "Application of a Multi-Field Concept to the Dambreak Case with an Obstacle". The 15th International Topical Meeting on Nuclear Reactor Thermalhydraulics (NURETH-15). Pisa, Italy. May 2013.

[233] S. Hänsch, D. Lucas, Höhne, E. Krepper, G. Montoya. "Comparative Simulations of Free Surface Flow using VOF-Methods and a New Approach for Multi-Scale Interfacial Structures". ASME 2013 Fluids Engineering Summer Meeting FEDSM2013. Nevada, USA. July 2013.

[234] R. K. Hanson and S. Salimian. "Survey of Rate Constants in H/N/O Systems". In W. C. Gardiner, editorCombustion Chemistry. 361. 1984.

[235] H. O. Hardenburg and F. W. Hase. "An Empirical Formula for Computing the Pressure Rise Delay of a Fuel from its Cetane Number and from the Relevant Parameters of Direct Injection Diesel Engines". SAE Technical Paper 790493. SAE. 1979.

[236] K. Haugen, O. Kvernvold, A. Ronald, and R. Sandberg. "Sand Erosion of Wear-resistant Materials: Erosion in Choke Valves.Wear". 186-187. 179–188. 1995.

[237] A. Hellsten. "New advanced k-w turbulence model for high-lift aerodynamics". AIAA Paper 2004-1120. Reno, Nevada. 2004.

[238] R. A. W. M. Henkes, F. F. van der Flugt, and C. J. Hoogendoorn. "Natural Convection Flow in a Square Cavity Calculated with Low-Reynolds-Number Turbulence Models". Int. J. Heat Mass Transfer. 34. 1543–1557. 1991.

[239] H. Hertz. “On the Evaporation of Liquids, Especially Mercury, in Vacuo”. Annalen der Physik (Leipzig). 17. 177. 1882.

[240] H. Hertz. “Über die Berührung fester elastischer Körper”. Journal für die reine und angewandte Mathematik. 92. 156-171. 1881.

[241] H. Hessenkemper, T. Ziegenhein, R. Rzehak, D. Lucas, and A. Tomiyama. “Lift force coefficient of ellipsoidal single bubbles in water”. International Journal of Multiphase Flows. 138. 2021.

[242] J. B. Heywood. Internal Combustion Engine Fundamentals. McGraw-Hill, New York, rev. edition. 1988.

[243] R. Herweg and R. R. Maly. A Fundamental Model for Flame Kernel Formation in S.I. Engines. SAE 922243. 1947-1976. 1992.

[244] T. Hibiki and M. Ishii. "One-group Interfacial Area Transport of Bubbly Flows in Vertical Round Tubes". International Journal of Heat and Mass Transfer. 43. 2711–2726. 2000.

[245] K. Higashitani, K. Yamauchi, Y. Matsuno, and G. Hosokawa. “Turbulent Coagulation of Particles Dispersed in a Viscous Fluid”. Chemical Engineering Journal Japan. 16(4). 299–304. 1983.

[246] P.G. Hill. “Condensation of Water Vapor During Supersonic Expansion in Nozzles”. Journal of Fluid Mechanics. 25 Part 3. 593–620. 1966.

[247] J. O. Hinze. Turbulence. McGraw-Hill Publishing Co., New York. 1975.

[248] J. O. Hirschfelder, C. F. Curtiss, and R. B. Bird. Molecular Theory of Gases and Liquids. John Wiley & Sons, New York. 1954.

[249] C. W. Hirt and B. D. Nichols. "Volume of Fluid (VOF) Method for the Dynamics of Free Boundaries". J. Comput. Phys. 39. 201–225. 1981.

[250] T. Höhne, Deendarlianto, D. Lucas. "Numerical simulations of counter-current two-phase flow experiments in a PWR hot leg model using an interfacial area density model". Int. J. Heat Fluid Flow. 32. 5. 1047–1056. 2011.

[251] T. Höhne, T. Geissler, A. Bieberle, U. Hampel. "Numerical modeling of a horizontal annular flow experiment using a droplet entrainment model". Annals of Nuclear Energy. 77. 351–360. 2015.

[252] T. Höhne, S. Haensch. "A droplet entrainment model for horizontal segregated flows". Nuclear Eng. and Des.. 286. 18–26. 2015.

[253] T. Höhne, P. Porombka. "Modelling horizontal two-phase flows using generalized models". Annals of Nuclear Energy. 111. 311–316. 2018.

[254] T. Höhne, P. Porombka, and S. Moya Saez. "Validation of AIAD sub-models for advanced numerical modelling of horizontal two-phase flows". Fluids. 5(3). 2020.

[255] D. G. Holmes and S. D. Connell. "Solution of the 2D Navier-Stokes Equations on Unstructured Adaptive Grids". Presented at the AIAA 9th Computational Fluid Dynamics Conference. June 1989.

[256] M. J. Hounslow, R. L. Ryall, and V. R. Marshall. “A Discretized Population Balance for Nucleation, Growth, and Aggregation”. AIChE Journal. 34(11). 1821–1832. 1988.

[257] T. J. Houser, M. Hull, R. Alway, and T. Biftu. Int. Journal of Chem. Kinet. 12. 579. 1980.

[258] S. Hosokawa, A. Tomiyama, S. Misaki, and T. Hamada. "Lateral Migration of Single Bubbles Due to the Presence of Wall". ASME 2002 Joint U.S.-European Fluids Engineering Division Conference, Montreal, QC, Canada. July 14–18, 2002.

[259] M. A. Hsia and L. L. Tavlarides. “Simulation analysis of drop breakage, coalescence and micro-mixing in liquid–liquid stirred tanks”. Chemical Engineering Journal. 26(3). 189–199. 1983.

[260] P. Huang, P. Bradshaw, and T. Coakley. "Skin Friction and Velocity Profile Family for Compressible Turbulent Boundary Layers". AIAA Journal. 31(9). 1600–1604. September 1993.

[261] T. J. R. Hughes. The Finite Element Method: Linear Static and Dynamic Finite Element Analysis. Prentice-Hall, Inc. Englewood Cliffs, NJ. 1987.

[262] G. A. Hughmark. “Mass and heat transfer from rigid spheres”. AICHE Journal. 13. 1219–1221. November 1967.

[263] L. Huilin and D. Gidaspow. "Hydrodynamics of binary fluidization in a riser: CFD simulation using two granular temperatures”. Chemical Engineering Science. 58. 3777–3792. 2003.

[264] S. C. Hunter. "Formation of so3 in gas turbines". Transactions of the ASME. 104. 44–51. 1982.

[265] B. R. Hutchinson and G. D. Raithby. "A Multigrid Method Based on the Additive Correction Strategy". Numerical Heat Transfer. 9. 511–537. 1986.

[266] H. Ibdir and H. Arastoopour. "Modeling of multi-type particle flow using kinetic approach". AICHE Journal. May 2005.

[267] A. Ioilev, M. Samigulin and V. Ustinenko. "Advances in the Modeling of Cladding Heat Transfer and Critical Heat Flux in Boiling Water Reactor Fuel Assemblies". The 12th International Topical Meeting on Nuclear Reactor Thermal Hydraulics (NURETH-12). Pittsburgh, Pennsylvania. 2007.

[268] M. Ihme, H. Pitsch. "Modeling of radiation and nitric oxide formation in turbulent nonpremixed flames using a flamelet/progress variable formulation". Physics of Fluids. 20. 5. 055110. AIP. 2008.

[269] K. Ishazaki, T. Ikohagi, and H. Daiguji. "A High-Resolution Numerical Method for Transonic Non-equilibrium Condensation Flows Through a Steam Turbine Cascade". In Proceedings of the 6th International Symposium on Computational Fluid Dynamics. 1. 479–484. 1995.

[270] M. Ishii. “Two-fluid model for two-phase flow”. 2nd International Workshop on Two-phase Flow Fundamentals. RPI, Troy, NY. 1979.

[271] M. Ishii and M.A. Grolmes. "Inception Criteria for Droplet Entrainment in Two-Phase Concurrent Film Flow". AIChE J.. 21. 2. 308–318. 1975.

[272] M. Ishii and S. Kim. "Micro Four-Sensor Probe Measurement of Interfacial Area Transport for Bubbly Flow in Round Pipes". Nuclear Engineering and Design. 205. 123–131. 2001.

[273] M. Ishii and N. Zuber. "Drag Coefficient and Relative Velocity in Bubbly, Droplet or Particulate Flows". AIChE J.. 25. 843-855. 1979.

[274] R. I. Issa. "Solution of Implicitly Discretized Fluid Flow Equations by Operator Splitting". Journal of Computational Physics. 62. 40–65. 1986.

[275] S. Jain. "Three-Dimensional Simulation of Turbulent Particle Dispersion". PhD thesis. University of Utah, Utah. 1995.

[276] A. Jameson. "Solution of the Euler Equations for Two Dimensional Transonic Flow by a Multigrid Method". MAE Report 1613. Princeton University. June 1983.

[277] A. Jameson, W. Schmidt, and E. Turkel. "Numerical Solution of the Euler Equations by Finite Volume Methods Using Runge-Kutta Time-Stepping Schemes". Technical Report AIAA-81-1259. AIAA 14th Fluid and Plasma Dynamics Conference, Palo Alto, California. June 1981.

[278] J. Janicka, W. Kolbe, and W. Kollmann. "Closure of the transport equation for the pdf of turbulent scalar fields". Journal Non-Equilibrium Thermodynamics. 4. 47. 1978.

[279] J. Janicka and W. Kollmann. "A Two-Variable Formulation for the Treatment of Chemical Reactions in Turbulent -Air Diffusion Flames". In 17th Symp. (Int’l.) on Combustion. The Combustion Institute. 1978.

[280] J. Janicka and W. Kollmann. "A Numerical Study of Oscillating Flow Around a Circular Cylinder". Combustion and Flame. 44. 319–336. 1982.

[281] C. Jayatillaka. "The Influence of Prandtl Number and Surface Roughness on the Resistance of the Laminar Sublayer to Momentum and Heat Transfer". Prog. Heat Mass Transfer. 1. 193–321. 1969.

[282] P. C. Johnson and R. Jackson. "Frictional-Collisional Constitutive Relations for Granular Materials, with Application to Plane Shearing". J. Fluid Mech. 176. 67–93. 1987.

[283] W. P. Jones and J. H. Whitelaw. "Calculation Methods for Reacting Turbulent Flows: A Review". Combustion and Flame. 48. 1–26. 1982.

[284] T. Jongen. "Simulation and Modeling of Turbulent Incompressible Flows". PhD thesis. EPF Lausanne, Lausanne, Switzerland. 1992.

[285] T. Just and S. Kelm. "Die Industry. 38. 76. 1986.

[286] B. Kader. "Temperature and Concentration Profiles in Fully Turbulent Boundary Layers". Int. J. Heat Mass Transfer. 24(9). 1541–1544. 1981.

[287] B. Kakimpa, H. Morvan, S. Hibberd. "The depth-averaged numerical simulation of laminar thin-film flows with capillary waves". Open access Journal Publication. ASME. J. Eng. Gas Turbines Power. 138. 11. 112501–112501-10. DOI: 10.1115/1.4033471. 2016.

[288] B. Kakimpa, H. Morvan, S. Hibberd. "Solution Strategies for Thin Film Rimming Flow Modelling". Conference Paper. ASME. Turbo Expo: Power for Land, Sea, and Air. 5C: Heat Transfer. V05CT15A026. DOI: 10.1115/GT2015-43503. 2015.

[289] N. Kandamby, G. Lazopoulos, F. C. Lockwood, A. Perera, and L. Vigevano. "Mathematical Modeling of NOx Emission Reduction by the Use of Reburn Technology in Utility Boilers". In ASME Int. Joint Power Generation Conference and Exhibition, Houston, Texas. 1996.

[290] K. C. Karki and S. V. Patankar. "Pressure-Based Calculation Procedure for Viscous Flows at All Speeds in Arbitrary Configurations". AIAA Journal. 27. 1167–1174. 1989.

[291] S. Kase and T. Matsuo. “Studies on Melt Spinning. II. Steady-State and Transient Solution of Fundamental Equations Compared with Experimental Results”. Journal of Applied Polymer Science. 11. 251–287. 1967.

[292] I. Kataoka, M. Ishii, and K. Mishima. “Generation and size distribution of droplet in annular two-phase flow”. J. of Fluids Engineering. 105. 230–238. 1983.

[293] M. Kato and B. E. Launder. “The modelling of turbulent flow around stationary and vibrating square cylinders”. Ninth Symposium on "Turbulent Shear Flows". Kyoto, Japan: August 16-18, 1993.

[294] A. Kaufmann, M. Moreau, O. Simonin, J. Helie. “Comparison between Lagrangian and mesoscopic Eulerian modelling approaches for inertial particles suspended in decaying isotropic turbulence”. Journal of Computational Physics. 277. 13. 6448–6472. Academic Press Professional, Inc., San Diego, CA, USA. June, 2008.

[295] W. M. Kays. "Loss coefficients for abrupt changes in flow cross section with low reynolds number flow in single and multiple tube systems". Transactions of the ASME. 72. 1067–1074. January 1950.

[296] W. M. Kays. "Turbulent Prandtl Number - Where Are We?". J. Heat Transfer. 116. 284–295. 1994.

[297] W. M. Kays and A. L. London. Compact Heat Exchangers. McGraw-Hill, New York. 1964.

[298] A. Kazakov, M. Frenklach. "Dynamic Modeling of Soot Particle Coagulation and Aggregation: Implementation With the Method of Moments and Application to High-Pressure Laminar Premixed Flames". Combustion and Flame. 114. 484–501. 1998.

[299] R. J. Kee, M.E. Coltrin, and P. Glarborg. Chemically Reacting Flow: Theory and Practice. Wiley. 2003.

[300] R. J. Kee, F. M. Rupley, J. A. Miller, M. E. Coltrin, J. F. Grcar, E. Meeks, H. K. Moffat, A. E. Lutz, G. Dixon-Lewis, M. D. Smooke, J. Warnatz, G. H. Evans, R. S. Larson, R. E. Mitchell, L. R. Petzold, W. C. Reynolds, M. Caracotsios, W. E. Stewart, P. Glarborg, C. Wang, O. Adigun, W. G. Houf, C. P. Chou, S. F. Miller, P. Ho, and D. J. Young. CHEMKIN v. 4.0Technical Report. Reaction Design, Inc., San Diego, CA. 2004.

[301] I. M. Khan and G. Greeves. "A Method for Calculating the Formation and Combustion of Soot in Diesel Engines". In N. H.Afgan and J. M.Beer, editorsHeat Transfer in Flames. Chapter 25Scripta, Washington DC. 1974.

[302] J. Kim, A. Mallarapu, D. P. Finegan, and S. Santhanagopalan. "Modeling cell venting and gas-phase reactions in 18650 lithium-ion batteries during thermal runaway". Journal of Power Sources. 489. 2021.

[303] J. S. Kim and F. A. Williams. "Extinction of Diffusion Flames with Non-Unity Lewis Number". Eng. Math. 31. 101–118. 1997.

[304] U. S. Kim, C. B. Shin, and C.-S. Kim. “Effect of Electrode Configuration on the Thermal Behavior of a Lithium-Polymer Battery”. Journal of Power Sources. Princeton, NJ. 180. 909–916. 2008.

[305] S. Kim, D. Caraeni, and B. Makarov. "A Multidimensional Linear Reconstruction Scheme for Arbitrary Unstructured Grids". Technical report. AIAA 16th Computational Fluid Dynamics Conference, Orlando,FloridaAmerican Institute of Aeronautics and Astronautics. June 2003.

[306] S. Kim, Q. Wu, and M. Ishii. "One-group Interfacial Area Transport in Vertical Bubbly Flow". International Journal of Heat and Mass Transfer. 41. 1103–1112. 1997.

[307] S.-E. Kim. "Large eddy simulation using unstructured meshes and dynamic subgrid-scale turbulence models". Technical Report AIAA-2004-2548. 34th Fluid Dynamics Conference and ExhibitAmerican Institute of Aeronautics and Astronautics,. June 2004.

[308] S.-E. Kim and D. Choudhury. "A Near-Wall Treatment Using Wall Functions Sensitized to Pressure Gradient". In ASME FED Vol. 217,Separated and Complex Flows. ASME. 1995.

[309] S.-E. Kim, D. Choudhury, and B. Patel. "Computations of Complex Turbulent Flows Using the Commercial Code Ansys Fluent". In Proceedings of the ICASE/LaRC/AFOSR Symposium on Modeling Complex Turbulent Flows. Hampton, Virginia1997.

[310] W.-W. Kim and S. Menon. "Application of the localized dynamic subgrid-scale model to turbulent wall-bounded flows". Technical Report AIAA-97-0210. 35th Aerospace Sciences Meeting, Reno, NVAmerican Institute of Aeronautics and Astronautics. January 1997.

[311] G-H. Kim, A. Pesaran, R. Spotnitz. “A Three-dimensional thermal abuse model for lithium-ion cells”. Journal of Power Sources. 170 (2). 476-489. 2007.

[312] G-H. Kim et al. “Multi-Domain Modeling of Lithium-Ion Batteries Encompassing Multi-Physics in Varied Length Scales”. J. of Electrochemical Soc.. 158 (8). A955-A969. 2011.

[313] U. S. Kim et al. “Modeling the Dependence of the Discharge Behavior of a Lithium-Ion Battery on the Environmental Temperature”. J. of Electrochemical Soc.. 158 (5). A611-A618. 2011.

[314] U. S. Kim et al. “Effect of electrode configuration on the thermal behavior of a lithium-polymer battery”. Journal of Power Sources. 180 (2). 909-916. 2008.

[315] M. Knudsen. “Maximum Rate of Vaporization of Mercury”. Annalen der Physik (Leipzig). 47. 697. 1915.

[316] H. Kobayashi, J. B. Howard, and A. F. Sarofim. "Coal Devolatilization at High Temperatures". In 16th Symp. (Int’l.) on Combustion. The Combustion Institute. 1976.

[317] G. Kocamustafaogullari and M. Ishii. "Interfacial area and nucleation site density in boiling systems". International Journal of Heat and Mass Transfer. 26. 9. 1377–1387. 1983.

[318] G. Kocamustafaogullari and M. Ishii. "Foundation of the Interfacial Area Transport Equation and its Closure Relations". International Journal of Heat and Mass Transfer. 38. 481–493. 1995.

[319] N. I. Kolev. Multiphase Flow Dynamics 2: Thermal and Mechanical Interactions. Springer, Berlin, Germany, 2nd edition. 2005.

[320] S. C. Kong, Z. W. Han, and R. D. Reitz. "The Development and Application of a Diesel Ignition and Combustion Model for Multidimensional Engine Simulations". SAE Paper 950278. SAE. 1995.

[321] M. Kostoglou, S. Dovas, and A. J. Karabelas. “On the Steady-State Size Distribution of Dispersions in Breakage Processes”. Chemical Engineering Science. 52(8). 1285–1299. 1997.

[322] R. Kraichnan. "Diffusion by a Random Velocity Field". Physics of Fluids. 11. 21–31. 1970.

[323] J. C. Kramlich. "The Fate and Behavior of Fuel-Sulfur in Combustion Systems". PhD thesis. Washington State University, Washington, USA. 1980.

[324] D. Kuhnke. "Spray Wall Interaction Modelling by Dimensionless Data Analysis". PhD thesis. Fachbereich Mathematik, Technischen Universität Darmstadt. 2004.

[325] A. A. Kulikovsky, J. Divisek, and A. A. Kornyshev. "Modeling the Cathode Compartment of Polymer Electrolyte Fuel Cells: Dead and Active Reaction Zones". Journal, Electrochemical Society. 146(11). 3981–3991. 1999.

[326] S. Kumar and D. Ramkrishna. “On the Solution of Population Balance Equations by Discretization - I., A Fixed Pivot Technique”. Chemical Engineering Science. 51(8). 1311–1332. 1996.

[327] K. K. Y. Kuo. Principles of Combustion. John Wiley and Sons, New York. 1986.

[328] N. Kurul and M. Z. Podowski. "On the modeling of multidimensional effects in boiling channels". In Proceedings of the 27th National Heat Transfer Conference, Minneapolis, Minnesota, USA. 1991.

[329] S. S. Kutateladze. "Boiling Heat Transfer". International Journal of Heat and Mass Transfer. 4. 31–45. 1961.

[330] K. H. Kwon et al. “A Two-dimensional Modeling of a Lithium-polymer battery”. Journal of Power Sources. 163. 151-157. 2006.

[331] H. Lamb. Hydrodynamics, Sixth Edition. Dover Publications, New York. 1945.

[332] M.J. Lampinen, M. Fomino. "Analysis of free energy and entropy changes for half-cell reactions". J. Electrochem. Soc.. 140(12). 3537-3546. 1993.

[333] G. L. Lane, M. P. Schwarz, and G. M. Evans. Modelling of the Interaction between Gas and Liquid in Stirred Vessels. 10th European Conference on Mixing. 197–204. 2000.

[334] R. B. Langtry, F. R. Menter, S. R. Likki, Y. B. Suzen, P. G. Huang, and S. Volker. "A Correlation-Based Transition Model Using Local Variables: Part II — Test Cases and Industrial Applications". (ASME-GT2004-53454) 2004.

[335] R. B. Langtry and F. R. Menter. "Correlation-Based Transition Modeling for Unstructured Parallelized Computational Fluid Dynamics Codes". AIAA Journal. 47(12). 2894–2906. December 2009.

[336] M. E. Larsen and J. R. Howell. "Least Squares Smoothing of Direct Exchange Areas in Zonal Analysis". J. Heat Transfer. 108. 239–242. 1986.

[337] B. E. Launder. "Second-Moment Closure and Its Use in Modeling Turbulent Industrial Flows". International Journal for Numerical Methods in Fluids. 9. 963–985. 1989.

[338] B. E. Launder. "Second-Moment Closure: Present... and Future?". Inter. J. Heat Fluid Flow. 10(4). 282–300. 1989.

[339] B. E. Launder, G. J. Reece, and W. Rodi. "Progress in the Development of a Reynolds-Stress Turbulence Closure". J. Fluid Mech. 68(3). 537–566. April 1975.

[340] Launder B. E. and Sharma B. I.. (1974): “Application of the Energy-Dissipation Model of Turbulence to the Calculation of Flow near a Spinning Disc”. Letters in Heat and Mass Transfer, 1:131–138..

[341] B. E. Launder and N. Shima. "Second-Moment Closure for the Near-Wall Sublayer: Development and Application". AIAA Journal. 27(10). 1319–1325. 1989.

[342] B. E. Launder and D. B. Spalding. Lectures in Mathematical Models of Turbulence. Academic Press, London, England. 1972.

[343] B. E. Launder and D. B. Spalding. "The Numerical Computation of Turbulent Flows". Computer Methods in Applied Mechanics and Engineering. 3. 269–289. 1974.

[344] N. M. Laurendeau. "Heterogeneous Kinetics of Coal Char Gasification and Combustion". Prog. Energy Comb. Sci. 4. 221–270. 1978.

[345] J. Lavieville, E. Quemerais, S. Mimouni, M. Boucker and N. Mechitoua. "NEPTUNE CFD V1.0 Theory Manual". EDF. 2005.

[346] C. K. Law and H. K. Law . "A d2 – Law for Multicomponent Droplet Vaporization and Combustion". AIAA. Vol. 20. No. 4. 552–527. 1982.

[347] J. L. Lebowitz. "Exact Solution of Generalized Percus-Yevick Equation for a Mixture of Hard Spheres". The Phy. Rev. 133(4A). A895–A899. 1964.

[348] J. Lee, A .Alam, and H. Ju. "Multidimensional and transient modeling of an alkaline water electrolysis cell". International Journal of Hydrogen Energy . 46(26). 13678–13690. 2021.

[349] K. B. Lee, M. W. Thring, and J. M. Beer. "On the Rate of Combustion of Soot in a Laminar Soot Flame". Combustion and Flame. 6. 137–145. 1962.

[350] W. H. Lee. "A Pressure Iteration Scheme for Two-Phase Modeling". Technical Report LA-UR 79-975. Los Alamos Scientific Laboratory, Los Alamos, New Mexico. 1979.

[351] A. H. Lefebvre. Atomization and Sprays. Hemisphere Publishing Corporation. 1989.

[352] D. Legendre and J. Magnaudet. “The Lift Force on a Spherical Bubble in a Viscous Linear Shear Flow”. J. Fluid Mech. 368. 81–126. 1998.

[353] F. Lehr, M. Millies, and D. Mewes. “Bubble-Size Distributions and Flow Fields in Bubble Columns”. AIChE Journal. 8(11). 2426–2443. 2002.

[354] M. Lemmert and L. M. Chawla. Influence of flow velocity on surface boiling heat transfer coefficient in Heat Transfer in Boiling. E. Hahne and U. Grigull, Eds., Academic Press and Hemisphere, New York, NY, USA. 1977.

[355] B. P. Leonard. "The ULTIMATE conservative difference scheme applied to unsteady one-dimensional advection". Comp. Methods Appl. Mech. Eng. 88. 17–74. 1991.

[356] B. P. Leonard and S. Mokhtari. "ULTRA-SHARP Nonoscillatory Convection Schemes for High-Speed Steady Multidimensional Flow". NASATM1-2568 (ICOMP-90-12). NASA Lewis Research Center. 1990.

[357] K. M. Leung and R. P. Lindsted. "Detailed Kinetic Modeling of C1-C3 Alkane Diffusion Flames". Combustion and Flame. 102. 129–160. 1995.

[358] M. Leverett. “Capillary behaviour in porous solids”. Transactions of the AIME. 142. 152–169. 1941.

[359] V. G. Levich. Physicochemical Hydrodynamics. Prentice Hall. 1962.

[360] J. M. Levy, L. K. Chen, A. F. Sarofim, and J. M. Beer. "NO/Char Reactions at Pulverized Coal Flame Conditions". In 18th Symp. (Int’l.) on Combustion. The Combustion Institute. 1981.

[361] M.T. Lewandowski and I.S. Ertesvag. "Analysis of the Eddy Dissipation Concept formulation for MILD combustion modelling". Fuel. 224. 687–700. 2018.

[362] M.T. Lewandowski, Z. Li, A. Parente, and J. Pozorski . "Generalised Eddy Dissipation Concept for MILD combustion regime at low local Reynolds and Damköhler numbers. Part 2: Validation of the model". Fuel. 278. 117743. 2020.

[363] A. Li and G. Ahmadi. "Dispersion and Deposition of Spherical Particles from Point Sources in a Turbulent Channel Flow". Aerosol Science and Technology. 16. 209–226. 1992.

[364] D. Li , S. Venkateswaran, K. Fakhari and C. Merkle. "Convergence Assessment of General Fluid Equations on Unstructured Hybrid Grids". Technical Report AIAA-2001-2557. AIAA 15th Computational Fluid Dynamics Conference, Anaheim, CaliforniaAmerican Institute of Aeronautics and Astronautics. June 2001.

[365] X. Li and R. S. Tankin. "On the Temporal Instability of a Two-Dimensional Viscous Liquid Sheet". Journal of Fluid Mechanics. 226. 425. 1991.

[366] Z. Li, A. Cuoci , A. Parente. "Large Eddy Simulation of MILD combustion using finite rate chemistry: Effect of combustion sub-grid closure, Proceedings of the Combustion Institute ". Proceedings of the Combustion Institute. DOI:10.1016/j.proci.2018.09.033. 2018.

[367] L. Liang, J. G. Stevens, J. T Farrell. "A Dynamic Adaptive Chemistry Scheme for Reactive Flow Computations". Proceedings of the Combustion Institute. 32. 527-534. 2009.

[368] L. Liang, J. G. Stevens, et al.. "The Use of Dynamic Adaptive Chemistry in Combustion Simulation of Gasoline Surrogate Fuels". Combustion and Flame. 156. 7. 1493-1502. 2009.

[369] Y. Liao, R. Rzehak, D. Lucas, E. Krepper. "Baseline closure model for dispersed bubbly flow: Bubble coalescence and breakup". Chem. Eng. Sci.. 122. 27. 336-349. 2015.

[370] A. K. Lichtarowicz, R. K. Duggins, and E. Markland. "Discharge Coefficients for Incompressible Non-Cavitating Flow Through Long Orifices". Journal of Mechanical Engineering Science. 7. 2. 1965.

[371] F. S. Lien and M. A. Leschziner. "Assessment of Turbulent Transport Models Including Non-Linear RNG Eddy-Viscosity Formulation and Second-Moment Closure". Computers and Fluids. 23(8). 983–1004. 1994.

[372] J. H. Lienhard IV and J. H. Lienhard V. A Heat Transfer Textbook. Version 5.10. Phlogiston Press, Cambridge. 784 pages. 2020.

[373] J.H. Lienhard V. "Heat Transfer by Impingement of Circular Free Surface Liquid Jets". 18th National & 7th ISHMT-ASME Heat and Mass Transfer Conference. 2006.

[374] M. J. Lighthill. "On Sound Generated Aerodynamically". Proc. Roy. Soc. London. A211564–587. 1952.

[375] G. M. Lilley. "The radiated noise from isotropic turbulence revisited". NASA Contract Report 93-75. NASA Langley Research Center, Hampton, VA. 1993.

[376] D. K. Lilly. "A Proposed Modification of the Germano Subgrid-Scale Closure Model". Physics of Fluids. 4. 633–635. 1992.

[377] F. Lindemann. Trans. Faraday Soc. 7. 1922.

[378] R. P. Lindstedt. In Proc. IUTAM Conf. on Aerothermo-Chemistry in Combustion. Taipei, Taiwan1991.

[379] R. P. Lindstedt. "Soot Formation in Combustion. Springer-Verlag, Berlin. 1994.

[380] M. S. Liou. "A sequel to AUSM: AUSM+". Journal of Computational Physics. 129. 364–382. 1996.

[381] M. S. Liou and C. J. Steffen, Jr. "A new flux splitting scheme". Journal of Computational Physics. 107(1). 23–39. 1993.

[382] A. N. Lipatnikov and J. Chomiak. "Turbulent Flame Speed and Thickness: Phenomenology, Evaluation and Application in Multi-dimensional Simulations". Progress in Energy& Combustion Science. 28. 1–74. January 2002.

[383] R. J. Litchford and S. M. Jeng. "Efficient Statistical Transport Model for Turbulent Particle Dispersion in Sprays". AIAA Journal. 29. 1443. 1991.

[384] J. D. Litster, D. J. Smit, and M. J. Hounslow. “Adjustable Discretization Population Balance for Growth and Aggregation”. AIChE Journal. 41(3). 591–603. 1995.

[385] A. B. Liu, D. Mather, and R. D. Reitz. "Modeling the Effects of Drop Drag and Breakup on Fuel Sprays". SAE Technical Paper 930072. SAE. 1993.

[386] H. Liu and B. M. Gibbs. "Modeling of NO and Emissions from Biomass-Fired Circulating Fluidized Bed Combustors". Fuel. 81. 271–280. 2002.

[387] F. C. Lockwood and C. A Romo-Millanes. "Mathematical Modelling of Fuel - NO Emissions From PF Burners". J. Int. Energy. 65. 144–152. September 1992.

[388] G. Lodier, L. Vervisch, V. Moureau and P. Domingo. "Composition-Space Premixed Flamelet Solution with Differential Diffusion for In Situ Flamelet-Generated Manifolds". Combustion and Flame. 158. 10. 2009-2016. 2011.

[389] M. Lopez de Bertodano. “Turbulent Bubbly Flow in a Triangular Duct”. Ph.D. Thesis. Rensselaer Polytechnic Institute, Troy, New York. 1991.

[390] M. A. Lopez de Bertodano, C. S. Jan, S. G. Beus. "Annular Flow Entrainment Rate Experiment in a Small Vertical Pipe". Nuclear Engineering and Design. 178. 61-70. 1997.

[391] B. Lu, W. Wang, and J. Li. "Searching for a mesh-independent sub-grid model for CFD simulation of gas–solid riser flows". Chemical Engineering Science. 64. 15. 3437-3447 . 2009.

[392] T. F. Lu and C. K. Law. "A Directed Relation Graph Method for Mechanism Reduction". Proc. Combust. Inst. 30. 1. 1333-1341. 2005.

[393] T. F. Lu and C. K. Law. "On the Applicability of Directed Relation Graph to the Reduction of Reaction Mechanisms". Combust. Flame. 146(3). 472-483. 2006.

[394] T. F. Lu and C. K. Law. "Toward Accommodating Realistic Fuel Chemistry in Large-Scale Computation". Prog. Energy Combust. Sci. 35(1). 192-215. 2009.

[395] N. Lubchenko. “Near-Wall Modeling of Bubbly Flows”. PhD thesis. Massachusetts Institute of Technology. 2015.

[396] D. Lucas, T. Frank, C. Lifante, P. Zwart, and A. Burns . "Extension of the inhomogeneous MUSIG model for bubble condensation". Nuclear Engineering and Design. 241. 11. 4359–4367. 2011.

[397] C. K. K. Lun, S. B. Savage, D. J. Jeffrey, and N. Chepurniy. "Kinetic Theories for Granular Flow: Inelastic Particles in Couette Flow and Slightly Inelastic Particles in a General Flow Field". J. Fluid Mech. 140. 223–256. 1984.

[398] H. Luo. “Coalescence, Breakup and Liquid Circulation in Bubble Column Reactors”. PhD thesis from the Norwegian Institute of Technology. Trondheim,Norway1993.

[399] J. Y. Luo, R. I. Issa, and A. D. Gosman. "Prediction of Impeller-Induced Flows in Mixing Vessels Using Multiple Frames of Reference". In IChemE Symposium Series. 136. 549–556. 1994.

[400] H. Luo and H. F. Svendsen. “Theoretical Model for Drop and Bubble Breakup in Turbulent Dispersions”. AIChE Journal. 42(5). 1225–1233,. 1996.

[401] A. E. Lutz, R. J. Kee, J. F. Grcar, and F. M. Rupley. "OPPDIF: A FORTRAN Program for Computing Opposed-Flow Diffusion Flames". Sandia National Laboratories Report SAND96-8243. 1997.

[402] J. F. Lynn. "Multigrid Solution of the Euler Equations with Local Preconditioning". PhD thesis. University of Michigan. 1995.

[403] R. K. Lyon. "The -NO-O Reaction". Int. Journal of Chem. Kinetics. 8. 315–318. 1976.

[404] D. Ma and G. Ahmadi. "A Thermodynamical Formulation for Dispersed Multiphase Turbulent Flows". Int.J.Multiphase Flow. 16. 323–351. 1990.

[405] J. Ma. "Soot Formation and Soot Secondary Reactions During Coal Pyrolysis". PhD thesis. Brigham Young University, Utah, USA. 1996.

[406] D. D. MacNeil and J. R. Dahn. "Test of Reaction Kinetics Using Both Differential Scanning and Accelerating Rate Calorimetries As Applied to the Reaction of LixCoO2 in Non-aqueous Electrolyte". J. Phys. Chem. A 105. 4430–4439. 2001.

[407] R. K. Madabhushi. "A Model for Numerical Simulation of Breakup of a Liquid Jet in Crossflow". "Atomization and Sprays". 13. 413–424. 2003.

[408] J. I. Madsen, W. A. Rogers, and T. J. OBrien. "Unstructured Multigrid Through Agglomeration In Computational Modelling of Mercury Control by Sorbent Injection". Baltimore, Maryland 2004.

[409] B. F. Magnussen. "On the Structure of Turbulence and a Generalized Eddy Dissipation Concept for Chemical Reaction in Turbulent Flow". Nineteenth AIAA Meeting, St. Louis 1981.

[410] B. F. Magnussen and B. H. Hjertager. "On mathematical models of turbulent combustion with special emphasis on soot formation and combustion". In 16th Symp. (Int’l.) on Combustion. The Combustion Institute. 1976.

[411] M. Manninen, V. Taivassalo, and S. Kallio. "On the mixture model for multiphase flow". VTT Publications 288, Technical Research Centre of Finland. 1996.

[412] D. L. Marchisio and R. O. Fox. "Solution of Population Balance Equations Using the Direct Quadrature Method of Moments". Aerosol Science and Technology. 36. 43–73. 2005.

[413] D. L. Marchisio, R. D. Virgil, and R. O. Fox. “Quadrature Method of Moments for Aggregation-Breakage Processes”. Journal of Colloid and Interface Science. 258. 322–334. 2003.

[414] F. Mathey, D. Cokljat, J. P. Bertoglio, and E. Sergent. "Specification of LES Inlet Boundary Condition Using Vortex Method". In K. Hanjalić, Y. Nagano, and M. Tummers, editors4th International Symposium on Turbulence, Heat and Mass Transfer, Antalya, Turkey. Begell House, Inc. 2003.

[415] S. R. Mathur and J. Y. Murthy. "Coupled ordinates method for multigrid acceleration of radiation calculations". J. of Thermophysics and Heat Transfer. 13(4). 1783-1785. 1999.

[416] C. Martínez-Bazán, J. L. Montañés, J. C. Lasheras. "On the breakup of an air bubble injected into a fully developed turbulent flow. Part 1. Breakup frequency". J. Fluid Mech.. 401. 157-182. 1999.

[417] S. Mayer. "Theory of Liquid Atomization in High Velocity Gas Streams". ARS Journal. 31. 467–473. 1961.

[418] S. Majumdar. "Role of Underrelaxation in Momentum Interpolation for Calculation of Flow With Nonstaggered Grids". Numerical Heat Transfer. 13(1). 125–132. 1988.

[419] S. Mazumder and J. V. Cole . “Rigorous 3-D Mathematical Modeling of PEM Fuel Cells II. Model Predictions with Liquid Water Transport". Journal, Electrochemical Society. 150(11). A1510–1517. 2003.

[420] B. J. McCoy and M. Wang. “Continuous-mixture Fragmentation Kinetics Particle Size Reduction and Molecular Cracking”. Chemical Engineering Science. 49(22). 3773–3785. 1994.

[421] H. A. McGee. Molecular Engineering. McGraw-Hill, New York. 1991.

[422] R. McGraw. “Description of Aerosol Dynamics by the Quadrature Method of Moments”. Aerosol Science and Technology. 27. 255–265. 1997.

[423] B. S. McLaury et al. "Modeling erosion in chokes". Proceeding of ASME Fluids Eng. Summer Meeting. San Diego, California. 1996.

[424] B. S. McLaury, J. Wang, S. A. Shirazi, J. R. Shadley, and E. F. Rybicki. "Solid Particle Erosion in Long Radius Elbows and Straight Pipes". SPE Annual Technical Conference and Exhibition, II Production Operations and Engineering/General, San Antonio, Texas. SPE Paper 38842 October 1997.

[425] R. Mei and J. F. Klausner. “Shear Lift Force on Spherical Bubbles”. J.Fluid Mech. 15. 62–65. 1994.

[426] P. C. Melte and D. T. Pratt. "Measurement of Atomic Oxygen and Nitrogen Oxides in Jet Stirred Combustion". In 15th Symposium (Int’l) on Combustion. The Combustion Institute. 1061–1070. 1974.

[427] C. Meneveau and T. Poinsot. "Stretching and Quenching of Flamelets in Premixed Turbulent Combustion". Combustion and Flame. 86. 311–332. 1991.

[428] F. R. Menter. "Two-Equation Eddy-Viscosity Turbulence Models for Engineering Applications". AIAA Journal. 32(8). 1598–1605. August 1994.

[429] F. R. Menter. "Review of the SST Turbulence Model Experience from an Industrial Perspective". International Journal of Computational Fluid Dynamics. Volume 23, Issue 4. 2009.

[430] F. R. Menter and Y. Egorov. "Re-visiting the Turbulent Scale Equation". Proc. IUTAM Symp. One Hundred Years of Boundary Layer Research, Göttingen. Springer. 2004.

[431] F. Menter and Y. Egorov. The Scale-Adaptive Simulation Method for Unsteady Turbulent Flow Predictions. Part 1: Theory and Model Description. Journal Flow Turbulence and Combustion. 85. 113–138. 2010.

[432] F. R. Menter, M. Kuntz, and R. Langtry. "Ten Years of Experience with the SST Turbulence Model". In K. Hanjalic, Y. Nagano, and M. Tummers, editorsTurbulence, Heat and Mass Transfer. 4. Begell House Inc. 625–632. 2003.

[433] F. R. Menter, R. B. Langtry, S. R. Likki, Y. B. Suzen, P. G. Huang, and S. Volker. "A Correlation-Based Transition Model Using Local Variables: Part I — Model Formulation". (ASME-GT2004-53452) 2004.

[434] F. R. Menter, . M. Kuntz and R. Bender. "A scale-adaptive simulation model for turbulent flow predictions". AIAA Journal. January 2003.

[435] K. V. Meredith, A. Heather, J. de Vries and Y. Xin. "A Numerical Model for Partially-Wetted Flow of Thin Liquid Films". Computational Methods in Multiphase Flow VI. 70. 239–250. WIT Press. 2011.

[436] H. J. Merk. "The Macroscopic Equations for Simultaneous Heat and Mass Transfer in Isotropic, Continuous and Closed Systems". Appl. Sci. Res. 8. 73–99. 1958.

[437] M. Metghalchi and J. C. Keck. "Burning velocities of mixtures of air with methanol, isooctane and indolene at high pressures and temperatures". Combustion and Flame. 48. 191–210. 1982.

[438] C.C. Milioli, F.E. Milioli, W. Holloway, K. Agrawal, S. Sundaresan. "Filtered two-fluid models of fluidized gas‐particle flows: new constitutive relations". AIChE Journal. 59. 9. 3265–3275. 2013.

[439] J. A. Miller and C. T. Bowman. "Mechanism and Modeling of Nitrogen Chemistry in Combustion". Prog. in Energy and Comb. Sci. 15. 287–338. 1989.

[440] J. A. Miller, M. C. Branch, W. J. McLean, D. W. Chandler, M. D. Smooke, and R. J. Kee. In 20th Symp. (Int’l.) on Combustion. The Combustion Institute. 673. 1985.

[441] J. A. Miller and G. A. Fisk. Chemical and Engineering News. 31. 1987.

[442] R. S. Miller, K. Harstad and J. Bellan. "Evaluation of Equilibrium and Non-Equilibrium Evaporation Models for Many Droplet Gas-Liquid Flow Simulations". International Journal of Multiphase Flow. 24. 6. 1025 –1055. 1998.

[443] M. Millies, D. Mewes. “Interfacial area density in bubbly flow”. Chemical Engineering and Processing. 38. 4-6. 307–319. 1999.

[444] M. Missaghi. "Mathematical Modelling of Chemical Sources in Turbulent Combustion". PhD thesis. The University of Leeds, England. 1987.

[445] M. Missaghi, M. Pourkashanian, A. Williams, and L. Yap. In Proceedings of American Flame Days Conference, USA. 1990.

[446] M. F. Modest. "The Weighted-Sum-of-Gray-Gases Model for Arbitrary Solution Methods in Radiative Transfer". J. Heat Transfer. 113. 650–656. 1991.

[447] M. F. Modest. Radiative Heat Transfer. Series in Mechanical EngineeringMcGraw-Hill. 1993.

[448] M. F. Modest. Radiative Heat Transfer 2nd Edition. Academic Press. New York, . 2003.

[449] L. J. Molero de Blas. "Pollutant Formation and Interaction in the Combustion of Heavy Liquid Fuels". PhD thesis. University of London, England. 1998.

[450] J. P. Monat, R. K. Hanson, and C. H. Kruger. In 17th Symp. (Int’l.) on Combustion. The Combustion Institute. 543. 1979.

[451] G. Montante, G. Micale, F. Magelli, and A. Brucato. Experiments and CFD predictions of solid particle distribution in a vessel agitated with four pitched blade turbines. Chemical Engineering Research and Design. 79(8). 1005-1010. 2001.

[452] G. Montoya. "Development and Validation of Advanced Theoretical Modeling for Churn-Turbulent Flows and Subsequent Transitions". PhD Thesis. Technischen Universität Berlin. 2015.

[453] G. Montoya, E. Baglietto, D. Lucas. "Implementation and Validation of a Surface Tension Model for the Multi-Scale Approach GENTOP". 16th International Topical Meeting on nuclear Reactor Thermalhydraulics - NURETH-16. Chicago, USA. September 2015.

[454] G. Montoya, E. Baglietto, D. Lucas, E. Krepper, T. Höhne. "Comparative Analysis of High Void Fraction Regimes Using an Averaging Euler-Euler Multi-field Approach and a Generalized Two-Phase Flow (GENTOP) Concept". 22sd International Conference on Nuclear Engineering (ICONE22). Prague, Czech Republic. July 2014.

[455] G. Montoya, Deendarlianto, D. Lucas, T. Höhne, C. Vallée. "Image-Processing Based Study of the Interfacial Behavior of the Countercurrent Gas-Liquid Two-Phase Flow in a Hot Leg of a PWR". Sci. Tech. Nuclear Int.. Article ID: 209542 . 2012.

[456] G. Montoya, D. Lucas, E. Krepper, S. Hänsch, E. Baglietto. "Analysis and Applications of a Generalized Multi-Field Two-Fluid Approach for Treatment of Multi-Scale Interfacial Structures in High Void Fraction Regimes". 2014 International Congress on Advances in Nuclear Power Plants (ICAPP 2014). Charlotte, North Carolina, USA. April 2014.

[457] M. J. Moore and C. H. Sieverding. "Two-Phase Steam Flow in Turbines and Separator. McGraw-Hill. 1976.

[458] F. J. Moraga, R. T. Bonetto and R. T. Lahey. "Lateral forces on spheres in turbulent uniform shear flow". International Journal of Multiphase Flow. 25. 1321–1372. 1999.

[459] R. Moreau. Magnetohydrodynamics. Kluwer Academic Publishers. 1990.

[460] R. Moreno-Atanasio and M. Ghadiri. “Mechanistic Analysis and Computer Simulation of Impact Breakage of Agglomerates Effect of Surface Energy”. Chemical Engineering Science. 61(8). 2476–2481. 2006.

[461] S. A. Morsi and A. J. Alexander. "An Investigation of Particle Trajectories in Two-Phase Flow Systems". J. Fluid Mech. 55(2). 193–208. September 26 1972.

[462] S. A. Morsi and A. J. Alexander. "An Investigation of Particle Trajectories in Two-Phase Flow Systems". J. Fluid Mech. 55(2). 193–208. September 26 1972.

[463] J. B. Moss, S. A. L. Perera,C. D. Stewart, and M. Makida. "Radiation Heat Transfer in Gas Turbine Combustors". In Proc. 16th (Int’l.) Symp. on Airbreathing Engines, Cleveland, OH. 2003.

[464] C. M. Muller, H. Breitbach, and N. Peters. "Partially Premixed Turbulent Flame Propagation in Jet Flames". In 25th Symposium (Int) on Combustion. The Combustion Institute. 1994.

[465] C. Mundo, M. Sommerfeld, and C. Tropea. "Droplet-Wall Collisions: Experimental Studies of the Deformation and Breakup Process". International Journal of Multiphase Flow. 21(2). 151–173. 1995.

[466] J. Y. Murthy and S. R. Mathur. "A Finite Volume Method For Radiative Heat Transfer Using Unstructured Meshes". AIAA-98-0860. January 1998.

[467] S. Muzaferija, M. Peric, P. Sames, and T. Schellin. "A Two-Fluid Navier-Stokes Solver to Simulate Water Entry". In Proc 22nd Symposium on Naval Hydrodynamics, Washington, DC. 277–289. 1998.

[468] J. D. Naber and R. D. Reitz. "Modeling Engine Spray/Wall Impingement". Technical Report 880107, Society of Automotive Engineers. General Motors Research Laboratories, Warren, MI. 1988.

[469] J. H. Nam and M. Karviany. "Effective Diffusivity and Water-Saturation Distribution in Single- and Two-layer PEMFC Diffusion Medium". Int. Journal Heat Mass Transfer. 2003.

[470] M. Namazian and J. B. Heywood. "Flow in the Piston Cylinder Ring Crevices of a Spark Ignition Engine: Effect on Hydrocarbon Emissions, Efficiency, and Power". SAE Technical Paper 820088. SAE. 1982.

[471] I. Naruse, Y. Yamamoto, Y. Itoh, and K. Ohtake. "Fundamental Study on Formation/Decomposition Characteristics by Means of Low-Temperature Pulverized Coal Combustion". In 26th Symposium (Int’l) on Combustion. The Combustion Institute. 3213–3221. 1996.

[472] P. F. Nelson, A. N. Buckley, and M. D. Kelly. "Functional Forms of Nitrogen in Coals and the Release of Coal Nitrogen as NOx Precursors (HCN and )". In 24th Symposium (Int’l) on Combustion. The Combustion Institute. 1259. 1992.

[473] J. S. Newman. Electrochemical Systems. Prentice Hall. Englewood Cliffs, New Jersey 1973.

[474] J. Newman and K. E. Thomas-Alyea. Electrochemical Systems. 3rd edition. John Wiley & Sons Inc., Hoboken, New Jersey. 2004.

[475] N. M. Newmark. “A Method of Computation for Structural Dynamics”. ASCE Journal of the Engineering Mechanics Division. Volume 85, Issue 3. p.67–94. 1959.

[476] T. V. Nguyen. "Modeling Two-Phase Flow in the Porous Electrodes of Proton Exchange Membrane Fuel Cells Using the Interdigitated Flow Fields". Tutorials in Electrochemical Engineering Mathematical Modeling. 99(14). 222–241. 1999.

[477] P. Nguyen, L. Vervisch, V. Subramanian and P. Domingo. "Multi-Dimensional Flamelet-Generated Manifolds for Partially Premixed Combustion". Combustion and Flame. 157. 43–61. 2010.

[478] F. Nicoud and F. Ducros. "Subgrid-Scale Stress Modelling Based on the Square of the Velocity Gradient Tensor.Flow". Turbulence, and Combustion. 62(3). 183–200. 1999.

[479] L. Nokleberg and T. Sontvedt. "Erosion of Oil and Gas Industry Choke Valves Using Computational Fluid Dynamics and Experiment". International Journal of Heat and Fluid Flow. 636–643. 1998.

[480] P. A. Nooren, H. A. Wouters, T. W. J. Peeters, D. Roekaerts, U. Maas, and D. Schmidt. "Monte carlo pdf modeling of a turbulent natural-gas diffusion flame". Combustion Theory and Modeling. 1. 79–96. 1997.

[481] J. Norman, M. Porkashanian, and A. Williams. "Modelling the Formation and Emission of Environmentally Unfriendly Coal Species in Some Gasification Processes". Fuel. 76(13). 1201–1216. October 1997.

[482] W. H. Nurick. "Orifice Cavitation and Its Effects on Spray Mixing". Journal of Fluids Engineering. 98. 1976.

[483] R. Ocone, S. Sundaresan, and R. Jackson. "Gas-particle flow in a duct of arbitrary inclination with particle-particle interaction". AIChE J. 39. 1261–1271. 1993.

[484] B. Oesterle and T. Bui Dinh. "Experiments on the lift of a spinning sphere in a range of intermediate Reynolds numbers". Exp. Fluids. 25. 16-22. 1998.

[485] S. Ogawa, A. Umemura, and N. Oshima. "On the Equation of Fully Fluidized Granular Materials". J. Appl. Math. Phys. 31. 483. 1980.

[486] Y. I. Oka, T. Yoshida. "Practical Estimation of Erosion Damage Caused by Solid Particle Impact, Part 2: Mechanical Properties of Materials Directly Associated With Erosion Damage". 15th International Conference on Wear of Materials. 259. 102-109. 2005.

[487] Y. Ohzawa, Y. Nagano, and T. Matsuo. “Fundamental Equations of Dry Spinning with an Example Calculation”. Proceedings, 5th Intern. Congress on Rheology. 393–408. Kyoto: 1968.

[488] E. Olsson, G. Kreiss and S. Zahedi. "A Conservative Level Set Method for Two Phase Flow II". J. Comput. Phys. 225. 785–807. 2007.

[489] O. O. Oluwole, H.-W. Wong, R. C. Miake-Lye, and W. H. Green Jr. "Dynamic Spatial and Temporal Allocation of Reduced Chemical Kinetics Models in Combustion Computational Fluid Dynamics Simulations". 46th AIAA/ASME/SAE/ASEE Joint Propulsion Conference. AIAA 2010-6827, 2010.

[490] S. Ookawara, M. Agrawal, D. Street, and K. Ogawa. "Modeling the motion of a sphere falling in a quiescent Newtonian liquid in a cylindrical tube by using the macroscopic particle model". The Seventh World Congress of Chemical Engineering. Glasgow, Scotland: C39-004. 2005.

[491] S. Ookawara, M. Agrawal, D. Street, and K. Ogawa. "Quasi-direct numerical simulation of lift force-induced particle separation in a curved microchannel by use of a macroscopic particle model". Chemical Engineering Science. 62. 9. 2454–2465. 2007.

[492] S.S. Ozarkar, X. Yan, S. Wang, C.C. Milioli, F.E. Milioli, S. Sundaresan. "Validation of filtered two-fluid models for gas–particle flows against experimental data from bubbling fluidized bed". Powder Technology. 284. 159–169. 2015.

[493] P. J. O’Rourke. "Collective Drop Effects on Vaporizing Liquid Sprays". PhD thesis. Princeton University, Princeton, New Jersey. 1981.

[494] P. J. O’Rourke and A. A. Amsden. "The TAB Method for Numerical Calculation of Spray Droplet Breakup". SAE Technical Paper 872089. SAE. 1987.

[495] P. J. O’Rourke and A. A. Amsden. "A Particle Numerical Model for Wall Film Dynamics in Port-Fuel Injected Engines". SAE Paper 961961. 1996.

[496] P. J. O’Rourke and A. A. Amsden. "A Spray/Wall Interaction Submodel for the KIVA-3 Wall Film Model". SAE Paper 2000-01-0271. 2000.

[497] P. J. O'Rourke and F. V. Bracco. "Two Scaling Transformations for the Numerical Computation of Multidimensional Unsteady Laminar Flames". Journal of Computational Physics. 33 (2). 185 –203. 1979.

[498] O. Rybdylova et al.. "A model for multi-component droplet heating and evaporation and its implementation into ANSYS Fluent". Int. Comm. Heat and Mass Transfer . Vol. 90. 29–33. 2018.

[499] S. A. Orszag, V. Yakhot, W. S. Flannery, F. Boysan, D. Choudhury, J. Maruzewski, and B. Patel. "Renormalization Group Modeling and Turbulence Simulations". In International Conference on Near-Wall Turbulent Flows, Tempe, Arizona. 1993.

[500] S. Osher and J. A. Sethian,. "Fronts Propagating with Curvature-dependent Speed: Algorithms Based on Hamilton-Jacobi Formulations". J. Comput. Phys. 79. 12–49. 1988.

[501] M. Ostberg and K. Dam-Johansen. "Empirical Modeling of the Selective Non-Catalytic Reduction of NO Comparison with Large-Scale Experiments and Detailed Kinetic Modeling". Chem. Engineering Science. 49(12). 1897–1904. 1994.

[502] H. Ounis, G. Ahmadi, and J. B. McLaughlin. "Brownian Diffusion of Submicrometer Particles in the Viscous Sublayer". Journal of Colloid and Interface Science. 143(1). 66–277. 1991.

[503] M. N. Ozisik. Radiative Transfer and Interactions with Conduction and Convection". Wiley, New York. 1973.

[504] S. A. Pandya, S. Venkateswaran, and T. H. Pulliam. "Implementation of dual-time procedures in overflow". Technical Report AIAA-2003-0072. American Institute of Aeronautics and Astronautics. 2003.

[505] J. C. Park, M. H. Kim and H. Miyata. "Fully Non-linear Free-surface Simulations By a 3D Viscous Numerical Wave Tank". International Journal for Numerical Methods in Fluids. 29. 685–703. 1999.

[506] U. Pasaogullari and C-Y. Wang. “Two-Phase transport and the role of micro-porous layer in polymer electrolyte fuel cells”. Electrochimica Acta. 49(25). 4359-4369. 2004.

[507] S. V. Patankar. Numerical Heat Transfer and Fluid Flow. Hemisphere, Washington, DC. 1980.

[508] S. V. Patankar. Numerical Heat Transfer and Fluid Flow. McGraw-Hill. Washington, New York, London 1980.

[509] M. A. Patterson and R. D. Reitz. "Modeling the Effects of Fuel Spray Characteristics on Diesel Engine Combustion and Emission". SAE Paper. SAE. 1998.

[510] D. Y. Peng and D. B. Robinson. "A New Two-Constant Equation of State". Industrial and Engineering Chemistry: Fundamentals. 15. 59–64. 1976.

[511] R. H. Perry, D. W. Gree, and J. O. Maloney. Perry’s Chemical Engineers’ Handbook. McGraw-Hill, New York. 6th edition. 1984.

[512] N. Peters. "Laminar Diffusion Flamelet Models in Non Premixed Combustion". Prog. Energy Combust. Sci. 10. 319–339. 1984.

[513] N. Peters. "Laminar Flamelet Concepts in Turbulent Combustion". In 21st Symp. (Int’l.) on Combustion. The Combustion Institute. 1231–1250. 1986.

[514] N. Peters. Turbulent Combustion. Cambridge University Press, Cambridge, England. 2000.

[515] N. Peters and S. Donnerhack. In 18th Symp. (Int’l.) on Combustion. The Combustion Institute. 33. 1981.

[516] N. Peters and B. Rogg. "Reduced Kinetic Mechanisms for Applications in Combustion Systems". In Lecture Notes in Physics. m15. Springer-Verlag. 1992.

[517] M. Pilch and C. A. Erdman. "Discrete Element Method (DEM) Simulation and Processing of Mo/AL2O3 Granules in Fluidizing Bed". Proc. Nat. Sci. Counc. RAOC(A). 24. 5. 394-404. 2000.

[518] M. Pilch and C. A. Erdman. "Use of Breakup Time Data and Velocity History Data to Predict the Maximum Size of Stable Fragments for Acceleration-Induced Breakup of a Liquid Drop". Int. J. Multiphase Flow. 13. 6. 741–757. 1987.

[519] K. K. Pillai. "The Influence of Coal Type on Devolatilization and Combustion in Fluidized Beds". J. Inst. Energy. 142. 1981.

[520] U. Piomelli, P. Moin and J. H. Ferziger. "Model Consistency in Large-Eddy Simulation of Turbulent Channel Flow". Physics of Fluids. 31. 1884–1894. 1988.

[521] H. Pitsch. "A Consistent Level Set Formulation For Large-Eddy Simulation of Premixed Turbulent Combustion". Combustion and Flame. 143. 587–598. 2005.

[522] H. Pitsch, H. Barths, and N. Peters. "Three-Dimensional Modeling of NOx and Soot Formation in DI-Diesel Engines Using Detailed Chemistry Based on the Interactive Flamelet Approach". SAE Paper 962057. SAE. 1996.

[523] H. Pitsch and N. Peters. "A Consistent Flamelet Formulation for Non-Premixed Combustion Considering Differential Diffusion Effects". Combustion and Flame. 114. 26–40. 1998.

[524] T. Poinsot and D. Veynante. Theoretical and Numerical Combustion. McGraw-Hill, New York. 2001.

[525] B. E. Poling, J. M. Prausnitz, and J. P. OConnell. The Properties of Gases and Liquids. McGraw-Hill, New York, 5th edition. 2001.

[526] S. B. Pope. "Computationally efficient implementation of combustion chemistry using in-situ adaptive tabulation". Combustion Theory and Modeling. 1. 41–63. 1997.

[527] S. B. Pope. "Gibbs Function Continuation for the Stable Computation of Chemical Equilibrium". Combustion and Flame. 139. 222–226. 2004.

[528] S. B. Pope. "Pdf methods for turbulent reactive flows". Progress Energy Combustion Science. 11. 119. 1985.

[529] S. B. Pope. “Probability Distributions of Scalars in Turbulent Shear Flow”. Turbulent Shear Flows. volume 2. pages 7–16. 1979.

[530] S. B. Pope. Turbulent Flows. Cambridge University Press, Cambridge, England. 2000.

[531] B. Popoff and M. Braun. "A Lagrangian Approach to Dense Particulate Flows". In International Conference on Multiphase Flow. Leipzig, Germany. 2007.

[532] C. Prakash. “Two phase model for binary liquid-solid phase change: Parts I and II”. Numerical Heat Transfer. 18. 2. 131–167. 1990.

[533] L. Prandtl. "Uber die ausgebildete Turbulenz". ZAMM. 5. 136–139. 1952.

[534] W. H. Press, S. A. Teukolsky, W. T. Vetterling, and B. P. Flannery. Numerical Recipes. Cambridge University Press. Cambridge, England,1992.

[535] M. Prince and H. Blanch. "Bubble Coalescence and Break-Up in Air-Sparged Bubble Columns". AIChE Journal. 36. 10. 1485–1499. 1990.

[536] I. Proudman. "The Generation of Noise by Isotropic Turbulence". Proc. Roy. Soc. A214. 119. 1952.

[537] A. Rabbani and M. Rokni . "Effect of nitrogen crossover on purging strategy in PEM fuel cell systems". Applied Energy. 111. 1061–1070. 2013.

[538] G. D. Raithby and E. H. Chui. "A Finite-Volume Method for Predicting a Radiant Heat Transfer in Enclosures with Participating Media". J. Heat Transfer. 112. 415–423. 1990.

[539] D. Ramkrishna. Population Balances Theory and Applications to Particulate Systems in Engineering. Academic Press. San Diego, CA,2000.

[540] A. D. Randolph and M. A. Larson. Theory of Particulate Processes. Analysis and Techniques of Continuous Crystallization. Academic Press. San Diego, CA1971.

[541] W. E. Ranz. "Some Experiments on Orifice Sprays". Canadian Journal of Chemical Engineering. 175. 1958.

[542] W. E. Ranz and W. R. Marshall, Jr. "Vaporation from Drops, Part I". Chem. Eng. Prog. 48(3). 141–146. March 1952.

[543] W. E. Ranz and W. R. Marshall, Jr. "Evaporation from Drops, Part I and Part II". Chem. Eng. Prog. 48(4). 173–180. April 1952.

[544] A. V. Rao. Dynamics of Particles and Rigid Bodies. A Systematic Approach. Cambridge University Press. Cambridge, England 2006.

[545] R. D. Rauch, J. T. Batira, and N. T. Y. Yang. "Spatial Adaption Procedures on Unstructured Meshes for Accurate Unsteady Aerodynamic Flow Computations". Technical Report AIAA-91-1106. AIAA. 1991.

[546] Reaction Design. http://www.reactiondesign.com . 2012.

[547] R. D. Reitz. "Mechanisms of Atomization Processes in High-Pressure Vaporizing Sprays". Atomization and Spray Technology. 3. 309–337. 1987.

[548] R. D. Reitz and F. V. Bracco. "Mechanism of Atomization of a Liquid Jet". Phys. Fluids. 26(10). 1982.

[549] R. D. Reitz and F. V. Bracco. "Mechanisms of Breakup of Round Liquid Jets". The Encyclopedia of Fluid Mechanics, ed. N. Cheremisnoff. 3. 223–249. 1986.

[550] C. H. Rexroth, H. J. Bauer, and S. Wittig. “DISC—An efficient method for the discretization of convection on unstructured grids”. Aerospace Science and Technology. 6. 1997.

[551] W. C. Reynolds. "Thermodynamic Properties in SI: Graphs, Tables, and Computational Equations for 40 Substances". Department of Mechanical Engineering, Stanford University. 1979.

[552] W. C. Reynolds. "Fundamentals of turbulence for turbulence modeling and simulation". Lecture Notes for Von Karman Institute Agard Report No. 755. 1987.

[553] M. Renksizbulut and M. C. Yuen. "Experimental Study of Droplet Evaporation in a High-Temperature Air Stream". Transactions of the ASME. 105 (2). 384-388. 1983.

[554] C. M. Rhie and W. L. Chow. "Numerical Study of the Turbulent Flow Past an Airfoil with Trailing Edge Separation". AIAA Journal. 21(11). 1525–1532. November 1983.

[555] H. S. Ribner. "The Generation of Sound by turbulent jets". In Advances in Applied Mathematics. Academic, New York. 1964.

[556] S. Richard, O. Colin, O. Vermorel, A. Benkenida, C. Angelberger, and D. Veynante. "Towards Large Eddy Simulation of Combustion in Spark Ignition Engines". Proceedings of the Combustion Institute. 31. 2. 3059–3066. 2007.

[557] J. R. Richardson and W. N. Zaki. "Sedimentation and Fluidization: Part I". Trans. Inst. Chem. Eng. 32. 35–53. 1954.

[558] C. E. Roberts and R. D. Matthews. "Development and Application of an Improved Ring Pack Model for Hydrocarbon Emissions Studies". SAE Technical Paper 961966. SAE. 1996.

[559] P. L. Roe. "Characteristic based schemes for the Euler equations". Annual Review of Fluid Mechanics. 18. 337–365. 1986.

[560] R. Rota, D. Antos, E. F. Zanoelo, and M. Morbidelli. "Experimental and Modeling Analysis of the NOxOUT Process". Chemical Engineering Science. 57. 27–38. 2002.

[561] S. I. Rubinow and J. B. Keller. "The transverse force on a spinning sphere moving in a viscous liquid". J. Fluid Mech.. 11. 447-459. 1961.

[562] P. G. Saffman. "The Lift on a Small Sphere in a Slow Shear Flow". J.Fluid Mech. 22. 385–400. 1965.

[563] P. G. Saffman. Corrigendum to: "The Lift on a Small Sphere in a Slow Shear Flow". J.Fluid Mech. 31. 624. 1968.

[564] P. G. Saffman and J. S. Turner. On the Collision of Droplets in Turbulent Clouds. Journal of Fluid Mechanics,. 1. 16–30. 1956.

[565] A. Sarkar, F. E. Milioli, S. Ozarkar, T. Li, X. Sun, S. Sundaresan. "Filtered sub-grid constitutive models for fluidized gas-particle flows constructed from 3-D simulations". Chemical Engineering Science. 152. 443–456. 2016.

[566] S. Sarkar and L. Balakrishnan. "Application of a Reynolds-Stress Turbulence Model to the Compressible Shear Layer". ICASE Report 90-18NASA CR 182002. 1990.

[567] S. Sarkar and M. Y. Hussaini. "Computation of the sound generated by isotropic turbulence". NASA Contract Report 93-74. NASA Langley Research Center, Hampton, VA. 1993.

[568] M. M. Salama and E. S. Venkatesh. "Evaluation of api rp14e erosional velocity limitations for offshore gas wells". In OTC Conference, Houston, TX. 371–376. May 1983.

[569] R. Sander. Compilation of Henry’s Law Constants for Inorganic and Organic Species of Potential Importance in Environmental Chemistry. http://www.henrys-law.org/:

[570] G.S.R. Sarma. “Physico–chemical Modelling in Hypersonic Flow Simulation”. Progress in Aerospace Sciences. 36. 3-4. 281-349. 2000.

[571] Y. Sato and K. Sekoguchi. “Liquid Velocity Distribution in Two-Phase Bubbly Flow”. Int. J. Multiphase Flow. 2. 79. 1979.

[572] S. S. Sazhin. "An Approximation for the Absorption Coefficient of Soot in a Radiating Gas". Manuscript. Fluent Europe, Ltd. 1994.

[573] S. S. Sazhin. "Advanced Models of Fuel Droplet Heating and Evaporation". Progress in Energy and Combustion Science. Elsevier Science. 32. 162–214. 2006.

[574] L. C. Scalabrin. "Numerical Simulation of Weakly Ionized Hypersonic Flow over Reentry Capsules". PhD thesis. University of Michigan, Ann Arbor, Michigan. 2007.

[575] D. G. Schaeffer. "Instability in the Evolution Equations Describing Incompressible Granular Flow". J. Diff. Eq. 66. 19–50. 1987.

[576] R. W. Schefer, M. Namazian, and J. Kelly. "In Combustion Research Facility News. 3:4. Sandia. 1991.

[577] L. Schiller and Z. Naumann. "Z. Ver. Deutsch. Ing. 77. 318. 1935.

[578] H. Schlichting and K. Gersten. Grenzschicht-Theorie. Springer-Verlag, Berlin, Heidelberg, New York. 1997.

[579] H. Schlichting and K. Gersten. Grenzschicht-Theorie. Springer. Berlin, Heidelberg, New York, London 1997.

[580] R. Schmehl, G. Klose, G. Maier, S. Wittig. "Efficient Numerical Calculation of Evaporating Sprays in Combustion Chamber Flows". In RTO AVTSymposium on Gas Turbine Engine Combustion Emissions and Alternative Fuels, Lisbon, Portugal, 1998. RTO MP-14. 51.1–51.14. 1999.

[581] D. P. Schmidt and M. L. Corradini. "Analytical Prediction of the Exit Flow of Cavitating Orifices". Atomization and Sprays. 7. 6. 1997.

[582] D. P. Schmidt, M. L. Corradini, and C. J. Rutland. "A Two-Dimensional, Non-Equilibrium Model of Flashing Nozzle Flow". In 3rd ASME/JSME Joint Fluids Engineering Conference. 1999.

[583] D. P. Schmidt, I. Nouar, P. K. Senecal, C. J. Rutland, J. K. Martin, and R. D. Reitz. "Pressure-Swirl Atomization in the Near Field". SAE Paper 01-0496. SAE. 1999.

[584] M. Schmoluchowski. Versuch Einen Mathematischen Theorie der Koagulationstechnik Kolloider Lösungen. Zeitschrift für Physikalische Chemie. 92. 129–168. 1917.

[585] G. H. Schnerr and J. Sauer. "Physical and Numerical Modeling of Unsteady Cavitation Dynamics". In Fourth International Conference on Multiphase Flow, New Orleans, USA. 2001.

[586] H. Scholz. "Modellierung und Untersuchung des Wärme- und Stofftransports und von Flutungsphänomenen in Niedertemperatur-PEM-Brennstoffzellen". PhD Thesis. 2015.

[587] P. K. Senecal, D. P. Schmidt, I. Nouar, C. J. Rutland, and R. D. Reitz. "Modeling High Speed Viscous Liquid Sheet Atomization". International Journal of Multiphase Flow. 25(6–7). 1073–1097. 1999.

[588] E. Sergent. "Vers une methodologie de couplage entre la Simulation des Grandes Echelles et les modeles statistiques". PhD thesis. L’Ecole Centrale de Lyon, Lyon, France. 2002.

[589] N. G. Shah. "A New Method of Computation of Radiant Heat Transfer in Combustion Chambers". PhD thesis. Imperial College of Science and Technology, London, England. 1979.

[590] D.R. Shaver, M.Z. Podowski. "Modeling of interfacial forces for bubbly flows in subcooled boiling conditions". Transactions of the American Nuclear Society (Proc. of ANS Winter Meeting). 113(1). 1368–1371. 2015.

[591] T.-H. Shih, W. W. Liou, A. Shabbir, Z. Yang, and J. Zhu. "A New - Eddy-Viscosity Model for High Reynolds Number Turbulent Flows - Model Development and Validation". Computers Fluids. 24(3). 227–238. 1995.

[592] M. L. Shur, P. R. Spalart, M. K. Strelets, and A. K. Travin. "A Hybrid RANS-LES Approach With Delayed-DES and Wall-Modelled LES Capabilities". International Journal of Heat and Fluid Flow. 29:6. December 2008. 1638-1649.

[593] M. Shur, P. R. Spalart, M. Strelets, and A. Travin. "Detached-Eddy Simulation of an Airfoil at High Angle of Attack". In 4th Int. Symposium on Eng. Turb. Modeling and Experiments, Corsica, France. May 1999.

[594] Michael L. Shur, Philippe R. Spalart, Michael K. Strelets, Andrey K. Travin; Synthetic Turbulence Generators for RANS-LES Interfaces in Zonal Simulations of Aerodynamic and Aeroacoustic Problems; Flow Turbulence Combust (2014) 93: 63. .

[595] M. L. Shur, M. K. Strelets, A. K. Travin and P. R. Spalart. "Turbulence Modeling in Rotating and Curved Channels: Assessing the Spalart-Shur Correction". AIAA Journal. 38(5). 2000. 2000.

[596] R. Siegel and J. R. Howell. "Thermal Radiation Heat Transfer. Hemisphere Publishing Corporation, Washington DC. 1992.

[597] R. Siegel and C. M. Spuckler. "Effect of Refractive Index and Diffuse or Specular Boundaries on a Radiating Isothermal Layer". J. Heat Transfer. 116. 787–790. 1994.

[598] O. Simonin and P. L. Viollet. “Modeling of Turbulent Two-Phase Jets Loaded with Discrete Particles”. Phenomena in Multiphase Flows. 259–269. 1990.

[599] O. Simonin and P. L. Viollet. "Predictions of an Oxygen Droplet Pulverization in a Compressible Subsonic Coflowing Hydrogen Flow". Numerical Methods for Multiphase Flows. FED91. 65–82. 1990.

[600] A. K. Singhal, H. Y. Li, M. M. Athavale, and Y. Jiang. "Mathematical Basis and Validation of the Full Cavitation Model". ASME FEDSM’01. New Orleans, Louisiana 2001.

[601] Y. R. Sivathanu and G. M. Faeth. "Generalized State Relationships for Scalar Properties in Non-Premixed Hydrocarbon/AirFlames". Combustion and Flame. 82. 211–230. 1990.

[602] S. Skogestad. Chemical and energy process engineering. Boca Raton, FLCRC Press. 2009.

[603] J. Smagorinsky. "General Circulation Experiments with the Primitive Equations. I. The Basic Experiment". Month. Wea. Rev. 91. 99–164. 1963.

[604] P. E. Smirnov and F. R. Menter. "Sensitization of the SST Turbulence Model to Rotation and Curvature by Applying the Spalart-Shur Correction Term". ASME Paper GT 2008-50480. Berlin, Germany. 2008.

[605] R. Smirnov, S. Shi, and I. Celik. "Random Flow Generation Technique for Large Eddy Simulations and Particle-Dynamics Modeling". Journal of Fluids Engineering. 123. 359–371. 2001.

[606] H. Smith, M. Zöchbauer, and T. Lauer. "Advanced Spray Impingement Modelling for an Improved Prediction Accuracy of the Ammonia Homogenisation in SCR Systems". "SAE Technical Paper 2015-01-1054". doi:10.4271/2015-01-1054. 2015.

[607] I. W. Smith. "Combustion and Flame. 17. 421. 1971.

[608] I. W. Smith. "The Intrinsic Reactivity of Carbons to Oxygen". Fuel. 57. 409–414. 1978.

[609] I. W. Smith. "The Combustion Rates of Coal Chars: A Review". In 19th Symp. (Int’l.) on Combustion. The Combustion Institute. 1045–1065. 1982.

[610] J. M. Smith and H. C. Van Ness. Introduction to Chemical Engineering Thermodynamics". McGraw Hill, New Jersey. 1986.

[611] T. F. Smith, Z. F. Shen, and J. N. Friedman. "Evaluation of Coefficients for the Weighted Sum of Gray Gases Model". J. Heat Transfer. 104. 602–608. 1982.

[612] K. Smith and C. Y. Wang. “Solid-state Diffusion Limitations on Pulse Operation of a Lithium ion Cell for Hybrid Electric Vehicles”. Journal of Power Sources. 161. 628-639. 2006.

[613] L. D. Smoot and P. J. Smith. "NOx Pollutant Formation in a Turbulent Coal System". In Coal Combustion and Gasification. Plenum, Plenum, NY373. 1985.

[614] D. O. Snyder, E. K. Koutsavdis, and J. S. R. Anttonen. "Transonic store separation using unstructured CFD with dynamic meshing". Technical Report AIAA-2003-3913. 33rd AIAA Fluid Dynamics Conference and Exhibit American Institute of Aeronautics and Astronautics. 2003.

[615] A. Sokolichen, G. Eigenberger, and A. Lapin. “Simulation of Buoyancy Driver Bubbly Flow: Established Simplifications and Open Questions”. Journal Review, AIChE Journal. 50:1. 24–45. January 2004.

[616] M. S. Solum, R. J. Pugmire, and D. M. Grant. "Energy and Fuels”. 3. 187. 1989.

[617] M. Sommerfeld, and N. Huber. "Experimental analysis and modeling of particle-wall collisions”. Int. J. Multiphase Flow. 25. 1457—1489. 1999.

[618] C. Soteriou, R. Andrews, and M. Smith. "Direct Injection Diesel Sprays and the Effect of Cavitation and Hydraulic Flip on Atomization". SAE Paper 950080. SAE. 1995.

[619] P. R. Spalart. "Strategies for Turbulence Modelling and Simulations". International Journal of Heat and Fluid Flow. 21. 3. 252–263. 2000.

[620] P. R. Spalart. "Young-person’s guide to detached-eddy simulation grids". NASA NASA/CR-2001-211032. NASA Langley Research Center. 2001.

[621] P. Spalart and S. Allmaras. "A one-equation turbulence model for aerodynamic flows". Technical Report AIAA-92-0439. American Institute of Aeronautics and Astronautics. 1992.

[622] P. R. Spalart, S. Deck, M. L. Shur, K. D. Squires, M. K. Strelets, and A. Travin. "A new version of detached-eddy simulation, resistant to ambiguous grid densities". Theoretical and Computational Fluid Dynamics. 20. 181–195. 2006.

[623] P. R. Spalart and M. L. Shur. "On the Sensitization of Turbulence Models to Rotation and Curvature". Aerospace Sci. Tech. 1(5). 297–302. 1997.

[624] D. B. Spalding. "Mixing and chemical reaction in steady confined turbulent flames". In 13th Symp. (Int’l.) on Combustion. The Combustion Institute. 1970.

[625] C. G. Speziale, S. Sarkar, and T. B. Gatski. "Modelling the Pressure-Strain Correlation of Turbulence: An Invariant Dynamical Systems Approach". J. Fluid Mech. 227. 245–272. 1991.

[626] T. E. Springer, T. A. Zawodzinski, and S. Gottesfeld. "Polymer Electrolyte Fuel Cell Model". J. Electrochemical Soc. 138:8. August 1991.

[627] T. E. Springer, T. A. Zawodzinski, and S. Gottesfeld. "Polymer Electrolyte Fuel Cell Model". Journal, Electrochemical Society. 138. 2334–2342. 1991.

[628] H. B. Squire. "Investigation of the Instability of a Moving Liquid Film". British Journal of Applied Physics. 4. 167. 1953.

[629] D. W. Stanton and C. J. Rutland. "Modeling Fuel Film Formation and Wall Interaction in Diesel Engines". SAE Paper 960628. 1996.

[630] D. W. Stanton and C. J. Rutland. "Multi-Dimentional Modeling of Heat and Mass Transfer of Fuel Films Resulting from Impinging Sprays". SAE 980132. 1998.

[631] D. W. Stanton and C. J. Rutland. "Multi-Dimensional Modeling of Thin Liquid Films and Spray-Wall Interactions Resulting from Impinging Sprays". International Journal of Heat and Mass Transfer. 41. 3037–3054. 1998.

[632] R. C. Steele, P. C. Malte, D. G. Nichol, and J. C. Kramlich. "NOx and in Lean-Premixed Jet-Stirred Flames". Combustion and Flame. 100. 440–449. 1995.

[633] H. Steiner, A. Kobor and L. Gebhard. "A wall heat transfer model for subcooled boiling flow". International Journal of Heat and Mass Transfer. 48. 4161–4173. 2005.

[634] P. H. Steward, C. W. Larson, and D. Golden. "Combustion and Flame. 75. 1989.

[635] S. Subramaniam and S. B. Pope. "A Mixing Model for Turbulent Reactive Flows Based on Euclidean Minimum Spanning Trees". Combustion and Flame. 115. 487–514. 1998.

[636] K. Sutton and P. A. Gnoffo. "Multi-component Diffusion with Application to Computational Aerothermodynamics". AIAA Paper 98-2575. AIAA. 1998.

[637] M. Syamlal. "The Particle-Particle Drag Term in a Multiparticle Model of Fluidization". National Technical Information Service, Springfield, VA. DOE/MC/21353-2373, NTIS/DE87006500, 1987.

[638] M. Syamlal and T. O’Brien. "The Derivation of a Drag Coefficient Formula from Velocity-Voidage Correlations". 1987.

[639] M. Syamlal and T. J. O’Brien. "Computer Simulation of Bubbles in a Fluidized Bed". AIChE Symp. Series. 85. 22–31. 1989.

[640] M. Syamlal, W. Rogers and T. J. O’Brien. MFIX Documentation: Volume1, Theory Guide>. National Technical Information Service, Springfield, VA. DOE/METC-9411004, NTIS/DE9400087, 1993.

[641] D. Tabacco, C. Innarella, and C. Bruno. "Theoretical and Numerical Investigation on Flameless Combustion". Combustion Science and Technology. 2002.

[642] W. Tabakoff and T. Wakeman. "Measured particle rebound characteristics useful for erosion prediction". ASME paper 82-GT-170. 1982.

[643] T. Takamasa and A. Tomiyama. . “Three-Dimensional Gas-Liquid Two-Phase Bubbly Flow in a C-Shaped Tube”. Ninth International Topical Meeting on Nuclear Reactor Thermal Hydraulics (NURETH-9). San Francisco, CA. 1999.

[644] L. Talbot et al. "Thermophoresis of Particles in a Heated Boundary Layer". J. Fluid Mech. 101(4). 737–758. 1980.

[645] I. Tanasawa. "Advances in Condensation Heat Transfer". Advances in Heat Transfer. 21. 55–139. 1991.

[646] L. Tay-Wo-Chong, A. Scarpato, and W. Polifke. "LES Combustion Model With Stretch and Heat Loss Effects for Prediction of Premix Flame Characteristics and Dynamics". Proceedings of ASME Turbo Expo 2017: Turbomachinery Technical Conference and Exposition. Paper No: GT2017-63357. 2017.

[647] G. I. Taylor. "The Shape and Acceleration of a Drop in a High Speed Air Stream, Technical Report". In the Scientific Papers of G. I. Taylor. ed., G. K. Batchelor. 1963.

[648] P. B. Taylor and P. J. Foster. "Some Gray Weighting Coefficients for --Soot Mixtures". Int. J. Heat Transfer. 18. 1331–1332. 1974.

[649] R. Taylor and R. Krishna. Multicomponent Mass Transfer. Wiley, New York. 1993.

[650] A. Tentner, S. Lo and V. Kozlov. "Advances in Computational Fluid Dynamics Modeling of Two-Phase Flow in a Boiling Water Reactor Fuel Assembly". In International Conference on Nuclear Engineering. Miami, Florida. 2006.

[651] A. Teraji, T. Tsuda, T. Noda, M. Kubo, and T. Itoh. "Development of a Novel Flame Propagation Model (UCFM: Universal Coherent Flamelet Model) for SI Engines and Its Application to Knocking Prediction". SAE 2005 World Congress & Exhibition. 2005.

[652] P. A. Tesner, T. D. Snegiriova, and V. G. Knorre. "Kinetics of Dispersed Carbon Formation". Combustion and Flame. 17. 253–260. 1971.

[653] P. Thakre, R. Rawat, R. Clayton and V. Yang. "Mechanical Erosion of Graphite Nozzle in Solid-Propellant Rocket Motor". J. of Propulsion and Power. 29. 593-601. 2013.

[654] Tiedemann and Newman. S.Gross Editor. “Battery Design and Optimization”. Proceedings, Electrochemical Soc. Princeton, NJ. 79-1. 39. 1979.

[655] V. I. Tolubinski and D. M. Kostanchuk. Vapor bubbles growth rate and heat transfer intensity at subcooled water boiling. 4^th International Heat Transfer Conference, Paris, France. 1970.

[656] A. Tomiyama. "Struggle with computational bubble dynamics". Third International Conference on Multiphase Flow, Lyon, France. June 8–12, 1998.

[657] A. Tomiyama, H. Tarnai, I. Zun and S. Hosokama. "Transverse Migration of Single Bubbles in Simple Shear Flow". Chem. Eng. Sci. 57. 1849–1858. 2002.

[658] B. Toole-ONeil, S. J. Tewalt, R. B. Finkleman, and D. J. Akers. "Mercury Concentration in Coal Unravelling the Puzzle". Fuel. 78(1). 47–74,. January 1999.

[659] A. A. Troshko and Y. A. Hassan. "A Two-Equation Turbulence Model of Turbulent Bubbly Flow". International Journal of Multiphase Flow. 22(11). 1965–2000. 2001.

[660] Y. Tsuji, T. Oshima, and Y. Morikawa. "Numerical simulation on pneumatic conveying in horizontal pipe". KONA-Powder Sci. Tech.Japan. 3. 38-51. 1985.

[661] E. Turkel and V. N. Vatsa. "Choice of variables and preconditioning for time dependent problems". Technical Report AIAA-2003-3692. 16th AIAA Computational Fluid Dynamics Conference, Orlando, FloridaAmerican Institute of Aeronautics and Astronautics. June 2003.

[662] O. Ubbink. "Numerical Prediction of Two Fluid Systems With Sharp Interfaces". PhD thesis. Imperial College of Science, Technology and Medicine, London, England. 1997.

[663] Sukkee Um, C. Y. Wang, and K. S. Chen. “Computational Fluid Dynamics Modeling of Proton Exchange Membrane Fuel Cells”. Journal, Electrochemical Society. 147(12). 4485–4493. 2000.

[664] H. C. Unal. "Maximum Bubble Diameter, Maximum Bubble Growth Time and Bubble Growth Rate During Subcooled Nucleate Flow Boiling of Water Up To ". Int. J. Heat Mass Transfer. 19. 643–649. 1976.

[665] B. Van Leer. "Toward the Ultimate Conservative Difference Scheme. IV. A Second Order Sequel to Godunov’s Method". Journal of Computational Physics. 32. 101–136. 1979.

[666] A. van Oijen and L. P. H. de Goey. "Modelling of Premixed Laminar Flames Using Flamelet-Generated Manifolds". Combust. Sci. Tech. 161. 113–137. 2000.

[667] J. P. Vandoormaal and G. D. Raithby. "Enhancements of the SIMPLE Method for Predicting Incompressible Fluid Flows". Numer.Heat Transfer. 7. 147–163. 1984.

[668] S. A. Vasquez and V. A. Ivanov. "A Phase Coupled Method for Solving Multiphase Problems on Unstructured Meshes". In Proceedings of ASME FEDSM’00. ASME 2000 Fluids Engineering Division Summer Meeting, Boston. June 2000.

[669] V. Venkatakrishnan. "On The Accuracy of Limiters and Convergence to Steady State Solutions". Technical Report AIAA-93-0880. American Institute of Aeronautics and Astronautics. January 1993.

[670] S. Venkateswaran, J. M. Weiss, and C. L. Merkle. "Propulsion Related Flowfields Using the Preconditioned Navier-Stokes Equations". Technical Report AIAA-92-3437. AIAA/ASME/SAE/ASEE 28th Joint Propulsion Conference, Nashville, TN. July 1992.

[671] O. Vermorel, S. Richard, O. Colin, C. Angelberger, A. Benkenida, and D. Veynante. "Towards the Understanding of Cyclic Variability in a Spark Ignited Engine Using Multi-Cycle LES". Combustion and Flame. 156. 8. 1525–1541. 2009.

[672] D. Veynante and L. Vervisch. "Turbulent Combustion Modeling". Progress in Energy and Combustion Science. Elsevier Science. 28. 3. 193–266. 2002.

[673] J. R. Viegas, M. W. Rubesin, and C. C. Horstman. "On the Use of Wall Functions as Boundary Conditions for Two-Dimensional Separated Compressible Flows". Technical Report AIAA-85-0180. AIAA 23rd Aerospace Sciences Meeting, Reno, Nevada1985.

[674] R. D. Vigil and R. M. Ziff. On the Stability of Coagulation–Fragmentation Population Balances. Journal of Colloids and Interface Science. 133(1). 257–264. 1989.

[675] K. Viswanathan. "Aeroacoustics of hot jets". Journal of Fluid Mechanics. 516. 39–82. 2004.

[676] V. R. Voller. "Modeling Solidification Processes". Technical report. Mathematical Modeling of Metals Processing Operations Conference, Palm Desert, CAAmerican Metallurgical Society. 1987.

[677] V. R. Voller, A. D. Brent, and C. Prakash. "The Modeling of Heat, Mass and Solute Transport in Solidification Systems". Int. J. Heat Mass Transfer. 32(9). 1719–1731. 1989.

[678] V. R. Voller, A. D. Brent, and K. J. Reid. "A Computational Modeling Framework for the Analysis of Metallurgical Solidification Process and Phenomena". Technical report. Conference for Solidification ProcessingRanmoor House, Sheffield, England. September 1987.

[679] V. R. Voller and C. Prakash. "A Fixed-Grid Numerical Modeling Methodology for Convection-Diffusion Mushy Region Phase-Change Problems". Int. J. Heat Mass Transfer. 30. 1709–1720. 1987.

[680] V. R. Voller and C. R. Swaminathan. "Generalized Source-Based Method for Solidification Phase Change". Numer. Heat Transfer B,. 19(2). 175–189. 1991.

[681] K. S. Vorres. "User’s handbook for the Argonne premium coal sample bank". Argonne National Laboratory, supported by DOE contract W-31-109-ENG-38, September 1989. Also K. S. Vorres, ACS Div. Fuel Chem. preprint 32. 4. 1987.

[682] M. P. Vukalovitch. Thermodynamic Properties of Steam. 6th edition. 1958. (Mashgis, Moscow).

[683] D. Wadnerkar, M. Agrawal, and V. Pareek. "Terminal Velocity of Particles Falling in Non-Newtonian Yield Pseudo-plastic Fluids using a Macroscopic Particle Model". In 7th International Conference on Multiphase FLOW. ICMF 2010Tampa, FL: 2010.

[684] S. Wallin and A. Johansson. "A complete explicit algebraic Reynolds stress model for incompressible and compressible flows". Journal of Fluid Mechanics. 403. 89–132. 2000.

[685] D. Keith Walters and Davor Cokljat. "A three-equation eddy-viscosity model for reynolds-averaged navier-stokes simulations of transitional flows". Journal of Fluids Engineering. 130. December 2008.

[686] D. K. Walters and N. M. Wolgemuth. "A new interface-capturing discretization for numerical solution of the volume fraction equation in two-phase flows". International Journal for Numerical Methods in Fluids. 60. 893-918. 2009.

[687] G. Wang, M. Boileau, and D. Veynante. "Implementation of a dynamic thickened flame model for large eddy simulations of turbulent premixed combustion". Combustion and Flame. 158. 11. 2199–2213. 2011.

[688] L. P. Wang. "On the Dispersion of Heavy Particles by Turbulent Motion". PhD thesis. Washington State University. 1990.

[689] T. Wang, J. Wang, Y. Jin. "Theoretical prediction of flow regime transition in bubble columns by the population balance model". Che. Eng. Sci.. 60. 22. 6199–6209. 2005.

[690] W. Wang and J. Li. “Simulation of gas-solid two-phase flow by a multi-scale CFD approach - Extension of the EMMS model to the sub-grid level”. Chemical Engineering Science. 62. 208–231. 2007.

[691] Yun Wang and C. Y. Wang. “Transient analysis of polymer electrolyte fuel cells”. Electrochimica Acta. 50. 1307-1315. 2005.

[692] Z. J. Wang. "A Fast Nested Multi-grid Viscous Flow Solver for Adaptive Cartesian/Quad Grids". International Journal for Numerical Methods in Fluids. 33. 657–680. 2000.

[693] J. Warnatz. "NOx Formation in High Temperature Processes". PhD thesis. University of Stuttgart, Stuttgart, Germany. 2001.

[694] G. P. Warren, W. K. Anderson, J. L. Thomas, and S. L. Krist. "Grid convergence for adaptive methods". Technical Report AIAA-91-1592. AIAA10th Computational Fluid Dynamics Conference, Honolulu, HawaiiAmerican Institute of Aeronautics and Astronautics. June 1991.

[695] C. Weber. "Zum Zerfall eines Flüssigkeitsstrahles". ZAMM. 11. 136–154. 1931.

[696] J. M. Weiss, J. P. Maruszewski, and W. A. Smith. "Implicit Solution of the Navier-Stokes Equations on Unstructured Meshes". Technical Report AIAA-97-2103. 13th AIAA CFD Conference, Snowmass, COJuly 1997.

[697] J. M. Weiss, J. P. Maruszewski, and W. A. Smith. "Implicit Solution of Preconditioned Navier-Stokes Equations Using Algebraic Multigrid". AIAA Journal. 37(1). 29–36. 1999.

[698] J. M. Weiss and W. A. Smith. "Preconditioning Applied to Variable and Constant Density Flows". AIAA Journal. 33(11). 2050–2057. November 1995.

[699] R. M. Wellek, A. K. Agrawal, and A. H. P. Skelland. "Shape of liquid drops moving in liquid media". AIChE J.. 12(5). 854–862. September 1966.

[700] C.-Y. Wen and Y. H. Yu. "Mechanics of Fluidization". Chem. Eng. Prog. Symp. Series. 62. 100–111. 1966.

[701] Z. Wen, S. Yun, M. J. Thomson, and M. F. Lightstone. "Modeling Soot Formation in Turbulent Kerosene/Air Jet Diffusion Flames". Combustion and Flame. 135. 323–340. 2003.

[702] H. Werner and H. Wengle. "Large-Eddy Simulation of Turbulent Flow Over and Around a Cube in a Plate Channel". In Eighth Symposium on Turbulent Shear Flows, Munich, Germany. 1991.

[703] C. Westbrook and F. Dryer. "Chemical Kinetic Modelling of Hydrocarbon Combustion". Prog. Energy Comb. Sci. 1. 1984.

[704] A. A. Westenberg. "Comb. Sci. Tech". 4. 59. 1971.

[705] J.C. Wheeler. "Modified moments and Gaussian quadratures". Rocky Mount. J. 4 (2). 287–296. 1974.

[706] F. White and G. Christoph. "A Simple New Analysis of Compressible Turbulent Skin Friction Under Arbitrary Conditions". Technical Report AFFDL-TR-70-133. February 1971.

[707] W. G. Whitman. Chem. Met. Eng. 29. 146. 1923.

[708] D. C. Wilcox. Turbulence Modeling for CFD. DCW Industries, Inc. La Canada, California. 1998.

[709] D. C. Wilcox. "Formulation of the k–ω turbulence model revisited". 45th AIAA Aerospace Sciences Meeting. Reno, NV, USA. AIAA Paper 2007–1408. 2007.

[710] J. Wilcox. "On the Path to Elucidating the Speciation of Mercury in the Flue Gases of Coal Combustion". PhD thesis. Dept. of Chemical and Environmental Engineering. The University of Arizona, Arizona, U.S.A. January 2004.

[711] J. Wilcox. "A Kinetic Investigation of High-Temperature Mercury Oxidation by Chlorine". Journal of Physical Chemistry A,. 113(24). 6633–6639. 2009.

[712] J. Wilcox, D. C. J. Marsden, and P. Blowers. "Evaluation of Basis Sets and Theoretical Methods for Estimating Rate Constants of Mercury Oxidation Reactions Involving Chlorine". Fuel Processing Technology. 85(5). 391–400. 2004.

[713] J. Wilcox, J. Robles, D. C. J. Marsden, and P. Blowers. "Theoretically Predicted Rate Constants for Mercury Oxidation by Hydrogen Chloride in Coal Combustion Flue Gases". Environmental Science and Technology. 37(18). 4199–4204. September 2003.

[714] F. A. Williams. Turbulent Mixing in Nonreactive and Reactive Flows. Plenum Press, New York. 1975.

[715] F. Winter, C. Wartha, G. Loffler, and H. Hofbauer. "The NO and Formation Mechanism During Devolatilization and Char Combustion Under Fluidized Bed Conditions". In 26th Symposium (Int’l) on Combustion. The Combustion Institute. 3325–3334. 1996.

[716] M. Wolfshtein. "The Velocity and Temperature Distribution of One-Dimensional Flow with Turbulence Augmentation and Pressure Gradient". Int. J. Heat Mass Transfer. 12. 301–318. 1969.

[717] M. J. Wright, D. Bose, G. E. Palmer, and E. Levin. "Recommended collision integrals for transport property computations, Part 1: Air species.". AIAA Journal. 43. 12. 2558–2564. 2005.

[718] H. Wu, X. Li and P. Berg. “On the modeling of water transport in polymer electrolyte membrane fuel cells”. Electrochimica Acta. 54(27). 6913-6927. 2009.

[719] P.-K. Wu, L.-K. Tseng, and G. M. Faeth. "Primary Breakup in Gas/Liquid Mixing Layers for Turbulent Liquids". Atomization and Sprays. 2. 295–317. 1995.

[720] W. Wu, Y. Piao, Q. Xie, and Z. Ren . "Flame Diagnostics with a Conservative Representation of Chemical Explosive Mode Analysis". AIAA Journal. 57(4). 295–317. 2019.

[721] V. Yakhot and S. A. Orszag. "Renormalization Group Analysis of Turbulence I Basic Theory". Journal of Scientific Computing. 1(1). 1–51. 1986.

[722] W. Yao and C. Morel. "Volumetric Interfacial Area Prediction in Upward Bubbly Two-Phase Flow". International Journal of Heat and Mass Transfer. 47. 307-328. 2004.

[723] X. G. Yang, Y. Leng, G. Zhang, S. Ge, and C. Y. Wang . "Modeling of lithium plating induced aging of lithium-ion batteries: Transition from linear to nonlinear aging". Journal of Power Sources. 360. 28-40. 2017.

[724] A. L. Yarin, and D. A. Weiss. "Impact of Drops on Solid Surfaces: Self-similar Capillary Waves, and Splashing as a New Type of Kinematic Discontinuity". J. Fluid Mech.. 283. 141-173. 1995.

[725] J. B. Young. "The Spontaneous Condensation of Steam in Supersonic Nozzles". Physico Chemical Hydrodynamics. 3(2). 57–82. July 1982.

[726] J. B. Young. "An Equation of State for Steam for Turbomachinery and Other Flow Calculations". Journal of Engineering for Gas Turbines and Power. 110. 1–7. January 1988.

[727] J. B. Young. "Two-Dimensional Nonequilibrium, Wet-Steam Calculations for Nozzles and Turbine Cascades". Journal of Turbomachinery. 114. 569–579. July 1992.

[728] D. L. Youngs. "Time-Dependent Multi-Material Flow with Large Fluid Distortion". Numerical Methods for Fluid Dynamics. K. W. Morton and M. J. Baines, editors. Academic Press. 1982.

[729] X. Zhang, S. Chumakov, X. Li, et al. "An Electro-chemo-thermo-mechanical Coupled Three-dimensional Computational Framework for Lithium-ion Batteries". Journal of The Electrochemical Society. 167 (16). 2020.

[730] X. Zhang, M. Klinsmann, S. Chumakov, et al. "A modified electrochemical model to account for mechanical effects due to lithium intercalation and external pressure". Journal of The Electrochemical Society . 168 (2). 2021.

[731] Q. Zhou and M. A. Leschziner. "Technical report". 8th Turbulent Shear Flows Symp, Munich. 1991.

[732] O. C. Zienkiewicz. The Finite Element Method. McGraw-Hill Company. London. 1977.

[733] T. Ziegenhein and D. Lucas. "Observations on bubble shapes in bubble columns under different flow conditions". Exp. Therm. Fluid Sci.. 85. 248–256. 2017.

[734] T. Ziegenhein, A. Tomiyama, and D. Lucas. "A new measuring concept to determine the lift force for distorted bubbles in low Morton number system: Results for air/water". International Journal of Multiphase Flow. 108. 11–24. 2018.

[735] V. Zimont. "Gas Premixed Combustion at High Turbulence. Turbulent Flame Closure Model Combustion Model". Experimental Thermal and Fluid Science. 21. 179–186. 2000.

[736] V. Zimont, W. Polifke, M. Bettelini, and W. Weisenstein. "An Efficient Computational Model for Premixed Turbulent Combustion at High Reynolds Numbers Based on a Turbulent Flame Speed Closure". J. of Gas Turbines Power. 120. 526–532. 1998.

[737] V. L. Zimont, F. Biagioli, and K. J. Syed. "Modelling Turbulent Premixed Combustion in the Intermediate Steady Propagation Regime". Progress in Computational Fluid Dynamics. 1(1). 14–28. 2001.

[738] V. L. Zimont and A. N. Lipatnikov. "A Numerical Model of Premixed Turbulent Combustion of Gases". Chem. Phys. Report. 14(7). 993–1025. 1995.

[739] G. Zschaeck, T. Frank, A. D. Burnsb. "CFD modelling and validation of wall condensation in the presence of non-condensable gases". Nuclear Engineering and Design. 279. 137–146. 2014.

[740] P. J. Zwart. "Numerical Modelling of Free Surface and Cavitating Flows". VKI Lecture Series. 2005.

[741] P. J. Zwart, A. G. Gerber, and T. Belamri. "A Two-Phase Flow Model for Predicting Cavitation Dynamics". In Fifth International Conference on Multiphase Flow, Yokohama, Japan. 2004.

[742] P. J. Zwart, P. G. Godin, J. Penrose, S. H. Rhee. "Ship Hull Simulations with a Coupled Solution Algorithm". In Y. Nagano K. Hanjalic and M. J. Tummers, editors Proceedings of the 10th International Symposium on Practical Designs of Ships and Other Floating Structures. Houston, TX. 2007.

[743] A. Arefmanesh, S. G. Advani, and E. E. Michaelides. A Numerical Study of Bubble Growth During Low Pressure Structural Foam Molding Process. Polym. Eng. Sci.. 30. 1330–13337. 1990.

[744] H. A. Barnes, J. F. Hutton, and K. Walters. An Introduction to Rheology. Elsevier. 1989.

[745] R. B. Bird, R. C. Armstrong, and O. Hassager. Dynamics of Polymeric Liquids. John Wiley. 1987.

[746] R. B. Bird, P. J. Dotson, and N. L. Johnson. J Non-Newtonian Fluid Mech. 7:213. 1980.

[747] R. B. Bird, W. E. Stewart, and E. N. Lightfoot. Transport Phenomena. John Wiley & Sons. 1960.

[748] R. S. Chambers. Numerical Integration of the Hereditary Integrals in a Viscoelastic Model for Glass. J Am Ceram Soc. 75(8). 2213–2218. 1992.

[749] N. Clemeur, R. P. G. Rutgers, and B. Debbaut. On the evaluation of some differential formulations for the pom-pom constitutive model. Rheol Acta. 42(1). 217–231. 2003.

[750] P. Coussot, A. I. Leonov, and J. M. Piau. Rheology of concentrated dispersed systems in a low molecular weight matrix. J Non-Newtonian Fluid Mech. 46. 179–217. 1993.

[751] A. R. Davies. Reentrant corner singularities in non-Newtonian flow. Part I: theory. J Non-Newtonian Fluid Mech. 29. 269–293. 1988.

[752] B. Debbaut and M. J. Crochet. Extensional effects in complex flows. J Non-Newtonian Fluid Mech. 30. 169–184. 1988.

[753] B. Debbaut and M. J. Crochet. Further results on the flow of a viscoelastic fluid through an abrupt contraction. J Non-Newtonian Fluid Mech. 20. 173–185. 1986.

[754] A. K. Doufas, A. J. McHugh, and C. Miller. Simulation of melt spinning including flow-induced crystallization Part I: model development and predictions. J Non-Newtonian Fluid Mech. 92. 27–66. 2000.

[755] M. Fortin. Old and New Finite Elements for Incompressible Flows. Int Numerical Methods Fluids. 1. 347–364. 1987.

[756] G. S. Fulcher. Analysis of Recent Measurements of the Viscosity of Glasses. J Am Ceram Soc. 8(6). 339–355. 1925.

[757] M. Goldstein and J. R. Howell. Boundary Conditions for the Diffusion Solution of Coupled Conduction-Radiation Problems. Technical Report NASA-TN-D-4618. NASA Lewis Research Center. 1968.

[758] A. Goublomme, B. Draily, and M. J. Crochet. Numerical Prediction of Extrudate Swell of a High-Density Polyethylene. J Non-Newtonian Fluid Mech,. 44. 171–195. 1992.

[759] R. Guénette and M. Fortin. A new mixed finite element method for computing viscoelastic flow. J Non-Newtonian Fluid Mech. 60(1). 27–52. 1995.

[760] J. R. Howell and M. Goldstein. Effective Slip Coefficients for Conduction-Radiation Problems. J Heat Transfer. 91(1). 165–169. 1969.

[761] N. J. Inkson, T. C. B. McLeish, O. G. Harlen, and D. J. Groves. Predicting low density polyethylene melt rheology in elongational and shear flows with "pom-pom" constitutive equations. J Rheol. 43(4). 873–896. 1999.

[762] C. Johnson. Numerical Solutions of Partial Differential Equations by the Finite Element Method. Cambridge Univ Press. 1987.

[763] R. Keunings. On the high Weissenberg number problem. J Non-Newtonian Fluid Mech. 20. 209–226. 1986.