Publikationen

Hier finden Sie aus dem TRR 150 entstandene sowie weitere themenrelevante Publikationen und Konferenzbeiträge seiner Wissenschaftler*innen.

  • Schweigert, D., Damson, B., Lüders, H., Stephan, P., Deutschmann, O.: The effect of wetting characteristics, thermophysical properties, and roughness on spray-wall heat transfer in selective catalytic reduction systems. International Journal of Heat and Mass Transfer 152, 119554, doi.org/10.1016/j.ijheatmasstransfer.2020.119554, (2020).
  • Bender, A., Hänichen, P., Gambaryan-Roisman, T., Stephan, P.: Modeling crystallization and heat transfer in an evaporating urea water drop. Proc. Int. Heat Transfer Conference, Kyoto, Japan, August 10-15 (2018) (accepted).
  • Hänichen, P., van Eyk, M., Stephan, P.: Experimental investigations of fuel film evaporation with de-posit formation. Int. J. Heat Fluid Flow 70, 125–130 (2018).
  • Hänichen, P., Stephan, P.: Experimental Investigations of Film Evaporation of Methylnaphthalene with Deposit Formation. 9th World Conference on Experimental Heat Transfer, Fluid Mechanics and Thermodynamics (2017).
  • Burzynski, D. A., Roisman, I. V., Bansmer, S. E.: On the splashing of high-speed drops impacting a dry surface. J. Fluid Mech. 892, 296, doi.org/10.1017/jfm.2020.168, (2020).
  • Kittel, H.M., Alam, E., Roisman, I.V., Tropea, C., Gambaryan-Roisman, T.: Splashing of a Newtonian drop impacted onto a solid substrate coated by a thin soft layer. Colloids and Surfaces A, 553, 89-96 (2018).
  • Schmidt, A., Kühnreich, B., Kittel, H., Tropea, C., Roisman, I.V., Dreizler, A. and Wagner, S.: Laser Based Measurement of Water Film Thickness for the Application in Exhaust After-treatment Processes. Int. J. Heat Fluid Flow 71, 288-294 (2018).
  • Kubach, H., Weidenlener, A., Pfeil, J., Koch, T., Kittel, H., Roisman, I.V., Tropea, C.: Investigations on the Influence of Fuel Oil Film Interaction on Pre-ignition Events in Highly Boosted DI Gasoline Engines, in: WCX World Congress Experience (2018). SAE Technical Paper: 2018-01-1454.
  • Kittel, H.M., Roisman, I.V., Tropea, C.: Drop Impact onto an Inclined Falling Film of Different Liquids. 9th World Conference on Experimental Heat Transfer, Iguazu Falls, Brazil, June 12-15 (2017).
  • Kittel, H.M., Roisman, I.V. and Tropea, C.: Splash of a drop impacting onto a solid substrate wetted by a thin film of another liquid. Physical Review Fluids (2017) (accepted).
  • Kittel, H.M., Roisman, I.V., Tropea, C.: Splashing of a very viscous liquid drop impacting onto a solid wall wetted by another liquid. In: Proceedings ILASS–Europe 2017 – 28th Conference on Liquid Atomization and Spray Systems, Valencia, Spain, September 6-8 (2017).
  • Kittel, H.M., Roisman, I.V., Tropea, C.: Drops make a splash. in: T.G. Etoh, H. Shiraga (eds.), 31st International Congress on High-Speed Imaging and Photonics, Osaka, Japan, November 7 (2017).
  • Kittel, H.M., Roisman, I.V., Tropea, C.: Splash of a Liquid Drop Impacting onto a Wall Film of Different Liquid. In: 9th International Conference on Multiphase Flow ICMF-2016, Firenze, Italy, May 22-27 (2016).
  • Kittel, H.M., Roisman, I.V., Tropea, C.: Outcome of Drop Impact onto a Liquid Film of Different Viscosities. Proceedings ILASS – Europe 2016 – 27th Annual Conference on Liquid Film of Different Viscocities, Brighton, UK, September 4-7 (2016).
  • Häber, T., Suntz, R.: Effect of different wall materials and thermal-barrier coatings on the flame-wall interaction of laminar premixed methane and propane flames. Int. J. Heat Fluid Flow 69, 95–105 (2018).
  • Kosaka, H., Zentgraf, F., Scholtissek, A., Bischoff, L., Häber, T., Suntz, R., Albert, B., Hasse, C., Dreizler, A.: Wall heat fluxes and CO formation/oxidation during laminar and turbulent side-wall quenching of methane and DME flames. Int. J. Heat Fluid Flow 70, 181–192 (2018).
  • Häber, T., Suntz, R., Bockhorn, H.: Flame-Wall Interaction of premixed Methane and Propane Flames. 8th European Combustion Meeting, Dubrovnik, Croatia, April 18–21 (2017).
  • Steinhausen, M., Luo, Y., Popp, S., Strassacker, C., Zirwes, T., Kosaka, H., Zentgraf, F., Maas, U., Sadiki, A., Dreizler, A., Hasse, C.: Numerical Investigation of Local Heat -Release Rates and Thermo-Chemical States in Side-Wall Quenching of Laminar Methane and Dimethyl Ether Flames. Flow Turbulence Combust 38 (1), 83, doi.org/10.1007/s10494-020-00146-w, (2020)
  • Kosaka, H., Zentgraf, F., Scholtissek, A., Hasse, C., Dreizler, A.: Effect of Flame-Wall Interaction on Local Heat Release of Methane and DME Combustion in a Side-Wall Quenching Geometry. Flow Turbulence Combust 104 (4), 1029–1046, doi.org/10.1007/s10494-019-00090-4, (2020)
  • Zirwes, T., Häber, T., Zhang, F., Kosaka, H., Dreizler, A., Steinhausen, M., Hasse, C., Stagni, A., Trimis, D., Suntz, R., Bockhorn, H.: Numerical Study of Quenching Distances for Side-Wall Quenching Using Detailed Diffusion and Chemistry. Flow Turbulence Combust 25 (3), 253, doi.org/10.1007/s10494-020-00215-0, (2020).
  • Jainski, C., Rißmann, M., Jakirlic, S., Böhm, B., Dreizler, A.: Quenching of premixed flames at cold walls. Effects on the local flow field. Flow Turb. Combust. 100(1), 177–196 (2018).
  • Kosaka, H., Zentgraf, F., Scholtissek, A., Bischoff, L., Häber, T., Suntz, R., Albert, B., Hasse, C., Dreizler, A.: Wall heat fluxes and CO formation/oxidation during laminar and turbulent side-wall quenching of methane and DME flames. Int. J. Heat Fluid Flow 70, 181–192 (2018).
  • Jainski, C., Rißmann, M., Böhm, B., Janicka, J., Dreizler, A.: Sidewall quenching of atmospheric laminar premixed flames studied by laser-based diagnostics. Combust. Flame 183, 271–282 (2017).
  • Rißmann, M., Jainski, C., Mann, M., Dreizler, A.: Flame-flow interaction in premixed turbulent flames during transient head-on quenching. Flow Turb. Combust. 98(4), 1025–1038 (2017).
  • Jainski, C., Rißmann, M., Böhm, B., Dreizler, A.: Experimental investigation of flame surface density and mean reaction rate during flame–wall interaction. Proc. Combust. Inst. 36, 1827–1834 (2017).
  • Bohlin, A., Jainski, C., Patterson, B.D., Dreizler, A., Kliewer, C.J.: Multiparameter spatio-thermochemical probing of flame–wall interactions advanced with coherent Raman imaging. Proc. Combust. Inst. 36, 4557–4564 (2017).
  • Ma, P.C., Ewan, T., Jainski, C., Lu, L., Dreizler, A., Sick, V., Ihme, M.: Development and analysis of wall models for internal combustion engine simulations using high-speed micro-PIV measurements. Flow Turb. Combust. 98, 283–309 (2017).
  • Ganter, S., Heinrich, A., Meier, T., Kuenne, G., Jainski, C., Rißmann, M., Dreizler, A., Janicka, J.: Numerical analysis of laminar methane-air side-wall-quenching. Combust. Flame 186, 299–310 (2017).
  • Schmidt, A., van der Kley, S., Wagner, S.: Optically accessible generic exhaust gas test bench for the investigation of fundamental SCR-relevant processes. Appl Opt 59 (23), 6953–6958, doi.org/10.1364/AO.397574, (2020).
  • van der Kley, S., Emmert, J., Schmidt, A., Dreizler, A., Wagner, S.: Tomographic spectrometer for the temporally-resolved 2D reconstruction of gas phase parameters within a generic SCR test rig. Proceedings of the Combustion Institute 12 (1), 63, doi.org/10.1016/j.proci.2020.09.009, (2020).
  • Emmert, J., Blume, N. G., Dreizler, A., Wagner, S.: Data analysis and uncertainty estimation in supercontinuum laser absorption spectroscopy. Sci Rep 8 (1), 10312, doi.org/10.1038/s41598-018-28705-2, (2018).
  • Bürkle, S., Biondo, L., Ding, C.-P., Honza, R., Ebert, V., Böhm, B., Wagner, S.: In-Cylinder Temperature Measurements in a Motored IC Engine using TDLAS. Flow Turb. Combust. 101(1), 139–159 (2018).
  • Schmidt, A., Kühnreich, B., Kittel, H., Tropea, C., Roisman, I.V., Dreizler, A., Wagner, S.: Laser Based Measurement of Water Film Thickness for the Application in Exhaust After-treatment Processes, Int. J. Heat Fluid Flow 71, 288–294 (2018).
  • Diemel, O., Honza, R., Ding, C., Böhm, B., Wagner, S., In situ sensor for cycle-resolved measurement of temperature and mole fractions in IC engine exhaust gases, accepted for the 37th Symposium on Combustion (2018).
  • Bürkle, S., Walter, N., and Wagner S., Laser-based measurements of pressure broadening and pressure shifts coefficients of combustion relevant absorption lines in the near infrared region, Appl. Phys. B 124, 121 (2018).
  • Häber, T., Bockhorn, H., Suntz, R.: Two-Dimensional Tomographic Simultaneous Multi-Species Visualization-Part I: Experimental Methodology and Application to Laminar and Turbulent Flames. Energies 13 (9), 2335, doi.org/10.3390/en13092335, (2020).
  • Häber, T., Suntz, R., Bockhorn, H.: Two-Dimensional Tomographic Simultaneous Multispecies Visualization-Part II: Reconstruction Accuracy. Energies 13 (9), 2368, doi.org/10.3390/en13092368, (2020).
  • Zirwes, T., Häber, T., Zhang, F., Kosaka, H., Dreizler, A., Steinhausen, M., Hasse, C., Stagni, A., Trimis, D., Suntz, R., Bockhorn, H.: Numerical Study of Quenching Distances for Side-Wall Quenching Using Detailed Diffusion and Chemistry. Flow Turbulence Combust 25 (3), 253, doi.org/10.1007/s10494-020-00215-0, (2020).
  • Zhang, F., Zirwes, T., Häber, T., Bockhorn, H., Trimis, D., Suntz, R.: Near Wall Dynamics of Premixed Flames. Proceedings of the Combustion Institute, doi.org/10.1016/j.proci.2020.06.058, (2020).
  • Bender, A., Stephan, P., Gambaryan-Roisman, T. 2020, A fully coupled numerical model for deposit formation from evaporating urea-water drops, Int. J. Heat Mass Transf., vol. 159, 120069, doi: 10.1016/j.ijheatmasstransfer.2020.120069.
  • Bender, A., Stroh, A., Frohnapfel, B., Stephan, P., Gambaryan-Roisman, T.: Combined direct numerical simulation and long-wave simulation of a liquid film sheared by a turbulent gas flow in a channel. Physics of Fluids 31 (2), 22103, doi.org/10.1063/1.5064423, (2019).
  • Bender, A., Stephan, P., Gambaryan-Roisman, T.: Numerical investigation of the evolution and breakup of an evaporating liquid film on a structured wall. Int. J. Heat Fluid Flow 70, 104–113 (2018).
  • Bender, A., Hänichen, P., Gambaryan-Roisman, T., Stephan, P.: Modeling crystallization and heat transfer in an evaporating urea water drop. Proc. Int. Heat Transfer Conference, Kyoto, Japan, August 10-15, (2018) (accepted).
  • Bender, A., Stephan, P., Gambaryan-Roisman, T.: Thin liquid films with time-dependent chemical reactions sheared by an ambient gas flow. Phys. Rev. Fluids 2(8), 084002-1 (2017).
  • Wörner, M., Samkhaniani, N., Cai, X., Wu, Y., Majumdar, A., Marschall, H., Frohnapfel, B., Deutschmann, O.: Spreading and rebound dynamics of sub-millimetre urea-water-solution droplets impinging on substrates of varying wettability. Applied Mathematical Modelling 66, 395, doi.org/10.1016/j.apm.2021.01.038, (2021).
  • Chedevergne, F., Forooghi, P.: On the importance of the drag coefficient modelling in the double averaged Navier-Stokes equations for prediction of the roughness effects. Journal of Turbulence 137 (2), 1–20, doi.org/10.1080/14685248.2020.1817465, (2020).
  • Stroh, A., Schäfer, K., Frohnapfel, B., Forooghi, P.: Rearrangement of secondary flow over spanwise heterogeneous roughness. J. Fluid Mech. 885, V003T01A042, doi.org/10.1017/jfm.2019.1030, (2020).
  • Schäfer, K., Forooghi, P., Straub, S., Frohnapfel, B., Stroh, A.: Direct Numerical Simulations of a Turbulent Flow over Wall-Mounted Obstacles—A Comparison of Different Numerical Approaches. In: García-Villalba, M., Kuerten, H. and Salvetti, M. V. (Eds.): Direct and Large Eddy Simulation XII, Bd. 27. Cham: Springer International Publishing (ERCOFTAC Series), 91–96, (2020).
  • Bender, A., Stroh, A., Frohnapfel, B., Stephan, P., Gambaryan-Roisman, T.: Combined direct numerical simulation and long-wave simulation of a liquid film sheared by a turbulent gas flow in a channel. Physics of Fluids 31 (2), 22103, doi.org/10.1063/1.5064423, (2019).
  • Forooghi, P., Frohnapfel, B., Magagnato, F., Busse, A.: A modified parametric forcing approach for modeling of roughness. Int. J. Heat Fluid Flow 71, 200-209 (2018).
  • Forooghi, P., Stroh, A., Schlatter, P., Frohnapfel, B.: Direct Numerical Simulation of flow over dissimilar, randomly distributed roughness elements – a systematic study on the effect of surface morphology on turbulence. Phys. Rev. Fluids 3, 044605 (2018).
  • Forooghi, P., Weidenlener, A., Magagnato, F., Böhm, B., Kubach, H., Koch, T., Frohnapfel, B.: DNS of momentum and heat transfer over rough surfaces based on realistic combustion chamber deposit geometries. Int. J. Heat Fluid Flow 69, 83–94 (2018).
  • Luan, Y., Olzmann, M., Magagnato, F.: Simulation of a shock tube with a small exit nozzle. J. Therm. Sci. 27(1), 34–38 (2018).
  • Forooghi, P., Flory, M., Bertsche, D., Wetzel, T., Frohnapfel, B.: Heat transfer enhancement on the liquid side of an industrially designed flat-tube heat exchanger with passive inserts – Numerical investigation. Appl. Therm. Eng. 123, 573–583 (2017).
  • Forooghi, P., Stroh, A., Magagnato, F., Jakirlic, S., Frohnapfel, B.: Toward a Universal Roughness Correlation. J. Fluids Eng. 139(12), 121201 (2017).
  • Krumbein, B., Forooghi, P., Jakirlić, S., Magagnato, F., Frohnapfel, B.: VLES Modeling of Flow Over Walls with Variably-shaped Roughness by Reference to Complementary DNS. Flow Turb. Combust. 99(3-4), 685–703 (2017).
  • Forooghi, P., Frohnapfel, B., Magagnato, F.: Simulation of a gaseous jet impinging on a convex heated surface – effect of inlet condition. Appl. Therm. Eng. 105, 1076–1084 (2016).
  • Stroh, A., Hasegawa, Y., Kriegseis, J., Frohnapfel, B.: Secondary vortices over surfaces with spanwise varying drag. J. Turbul. 17(12), 1142–1158 (2016).
  • Stroh, A., Forooghi, P., Kriegseis, J., Frohnapfel, B.: Secondary vortices over spanwise heterogeneous roughness. 24th International Congress of Theoretical and Applied Mechanics (ICTAM 2016), Montreal, Canada, Aug. 21-26 (2016).
  • Li, Y., Ries, F., Leudesdorff, W., Nishad, K., Pati, A., Hasse, C., Janicka, J., Jakirlić, S., Sadiki, A.: Non-equilibrium wall functions for large Eddy simulations of complex turbulent flows and heat transfer. International Journal of Heat and Fluid Flow 88 (1), 108758,doi.org/10.1016/j.ijheatfluidflow.2020.108758, (2021).
  • Ullrich, M., Krumbein, B., Maduta, R., Jakirlić, S.: Turbulent flow in a square cross-sectioned bubble column computed by a scale-resolving Reynolds-stress model. Chemical Engineering Science 230 (1–3), 116201, doi.org/10.1016/j.ces.2020.116201, (2021).
  • Krumbein, B., Maduta, R., Jakirlić, S., Tropea, C.: A Scale-Resolving Elliptic-Relaxation-Based Eddy-Viscosity Model: Development and Validation. In: Dillmann, A., Heller, G., Krämer, E., Wagner, C., Tropea, C. and Jakirlić, S. (Eds.): New Results in Numerical and Experimental Fluid Mechanics XII, Bd. 142. Cham: Springer International Publishing (Notes on Numerical Fluid Mechanics and Multidisciplinary Design), 90–100, (2020).
  • Krumbein, B., Termini, V., Jakirlić, S., Tropea, C.: Flow and heat transfer in cross-stream type T-junctions. Int. J. Heat Fluid Flow 71, 179–188 (2018).
  • Renaud, A., Ding, C.-P., Jakirlic, S., Dreizler, A., Böhm, B.: Experimental characterization of the velocity boundary layer in a motored IC engine. Int. J. Heat Fluid Flow 71, 366–377 (2018).
  • Jainski, C., Rißmann, M., Jakirlic, S., Böhm, B., Dreizler, A.: Quenching of Premixed Flames at Cold Walls. Flow Turb. Combust. 100(1), 177–196 (2018).
  • Krumbein, B., Jakirlić, S., Tropea, C.: VLES study of a jet impinging onto a heated wall. Int. J. Heat Fluid Flow 68, 290–297 (2017).
  • Krumbein, B., Forooghi, P., Jakirlić, S., Magagnato, F., Frohnapfel, B.: VLES Modeling of Flow Over Walls with Variably-shaped Roughness by Reference to Complementary DNS. Flow Turb. Combust. 99(3-4), 685–703 (2017).
  • Forooghi, P., Stroh, A., Magagnato, F., Jakirlic, S., Frohnapfel, B.: Toward a Universal Roughness Correlation. J. Fluids Eng. 139(12), 121201-12 (2017).
  • Jakirlic, S., Kutej, L., Unterlechner, P., Tropea, C.: Critical Assessment of Some Popular Scale-Resolving Turbulence Models for Vehicle Aerodynamics. SAE Int. J. Passeng. Cars – Mech. Syst. 10(1), 235–250 (2017).
  • Bertótiné Abai, A., Zengel, D., Janzer, C., Maier, L., Grunwaldt, J.-D., Olzmann, M., Deutschmann, O.: Effect of NO 2 on Gas-Phase Reactions in Lean NO x /NH 3 /O 2 /H 2 O Mixtures at Conditions Relevant for Exhaust Gas Aftertreatment. In: SAE Technical Paper Series, JAN. 01, 2021, (2021).
  • Golka, L., Gratzfeld, D., Weber, I., Olzmann, M.: Temperature- and pressure-dependent kinetics of the competing C-O bond fission reactions of dimethoxymethane. Phys Chem Chem Phys 22 (10), 5523–5530, doi.org/10.1039/d0cp00136h, (2020).
  • Whelan, C. A., Eble, J., Mir, Z. S., Blitz, M. A., Seakins, P. W., Olzmann, M., Stone, D.: Kinetics of the Reactions of Hydroxyl Radicals with Furan and Its Alkylated Derivatives 2-Methyl Furan and 2,5-Dimethyl Furan. J Phys Chem A 124 (37), 7416–7426, doi.org/10.1021/acs.jpca.0c06321, (2020).
  • Gratzfeld, D., Heitkämper, J., Debailleul, J., Olzmann, M.: On the influence of water on urea condensation reactions: a theoretical study. Zeitschrift für Physikalische Chemie 234 (7-9), 1311–1327, doi.org/10.1515/zpch-2020-1658, (2020).
  • Weber, I., Olzmann, M.: Thermal decomposition of CH 3 I revisited: Consistent calibration of I‐atom concentrations behind shock waves with dual I‐/H‐ARAS. Int. J. Chem. Kinet. 51 (5), 367–376, doi.org/10.1002/kin.21260, (2019).
  • Bänsch, C., Olzmann, M.: Reaction of dimethoxymethane with hydroxyl radicals: An experimental kinetic study at temperatures above 296 K and pressures of 2, 5, and 10 bar. Chemical Physics Letters 720, 19–24, doi.org/10.1016/j.cplett.2019.01.053, (2019).
  • Golka, L., Weber, I., Olzmann, M.: Pyrolysis of dimethoxymethane and the reaction of dimethoxymethane with H atoms: A shock-tube/ARAS/TOF-MS and modeling study. Proceedings of the Combustion Institute 37 (1), 179–187, doi.org/10.1016/j.proci.2018.05.036, (2019).
  • Weiser, L., Weber, I., Olzmann, M.: Pyrolysis of Furan and Its Methylated Derivatives: A Shock-Tube/TOF-MS and Modeling Study. J Phys Chem A 123 (46), 9893–9904, doi.org/10.1021/acs.jpca.9b06967, (2019).
  • Golka, L., Weber, I., Olzmann, M.: Pyrolysis of dimethoxymethane and the reaction of dimethoxymethane with H atoms: A shock-tube/ARAS/TOF-MS and modeling study. Accepted for the 37th Symposium on Combustion (2018).
  • Luan, Y., Olzmann, M., Magagnato, F.: Simulation of a shock tube with a small exit nozzle. J. Therm. Sci. 27(1), 34–38 (2018).
  • Stein, M., Bykov, V., Bertótiné Abai, A., Janzer, C., Maas, U., Deutschmann, O., Olzmann, M.: A reduced model for the evaporation and decomposition of urea–water solution droplets. Int. J. Heat Fluid Flow 70, 216–225 (2018).
  • Koksharov, A., Yu, C., Bykov, V., Maas, U., Pfeifle, M., Olzmann, M.: Quasi-Spectral Method for the Solution of the Master Equation for Unimolecular Reaction Systems. Int. J. Chem. Kinet. 50(5), 357–369 (2018).
  • Gratzfeld, D., Olzmann, M.: Gas-phase standard enthalpies of formation of urea-derived compounds. Chem. Phys. Lett. 679, 219–224 (2017).
  • Wörner, M., Samkhaniani, N., Cai, X., Wu, Y., Majumdar, A., Marschall, H., Frohnapfel, B., Deutschmann, O.: Spreading and rebound dynamics of sub-millimetre urea-water-solution droplets impinging on substrates of varying wettability. Applied Mathematical Modelling 66, 395, doi.org/10.1016/j.apm.2021.01.038, (2021).
  • Bertótiné Abai, A., Zengel, D., Janzer, C., Maier, L., Grunwaldt, J.-D., Olzmann, M., Deutschmann, O.: Effect of NO 2 on Gas-Phase Reactions in Lean NO x /NH 3 /O 2 /H 2 O Mixtures at Conditions Relevant for Exhaust Gas Aftertreatment. In: SAE Technical Paper Series, JAN. 01, 2021, (2021).
  • Börnhorst, M., Kuntz, C., Tischer, S., Deutschmann, O.: Urea derived deposits in diesel exhaust gas after-treatment: Integration of urea decomposition kinetics into a CFD simulation. Chemical Engineering Science 211, 115319, doi.org/10.1016/j.ces.2019.115319, (2020).
  • Tischer, S., Börnhorst, M., Amsler, J., Schoch, G., Deutschmann, O.: Thermodynamics and reaction mechanism of urea decomposition. Phys Chem Chem Phys 21 (30), 16785–16797, doi.org/10.1039/c9cp01529a, (2019).
  • Nishad, K., Stein, M., Ries, F., Bykov, V., Maas, U., Deutschmann, O., Janicka, J., Sadiki, A.: Thermal Decomposition of a Single AdBlue® Droplet Including Wall–Film Formation in Turbulent Cross-Flow in an SCR System. Energies 12 (13), 2600, doi.org/10.3390/en12132600, (2019).
  • Jamshidi, F., Heimel, H., Hasert, M., Cai, X., Deutschmann, O., Marschall, H., Wörner, M.: On suitability of phase-field and algebraic volume-of-fluid OpenFOAM® solvers for gas–liquid microfluidic applications. Computer Physics Communications 236, 72–85, doi.org/10.1016/j.cpc.2018.10.015, (2019).
  • Stein, M., Bykov, V., Bertótiné Abai, A., Janzer, C., Maas, U., Deutschmann, O., Olzmann, M.: A reduced model for the evaporation and decomposition of urea–water solution droplets. Int. J. Heat Fluid Flow 70, 216–225 (2018).
  • Cai, X., Wörner, M., Marschall, H., Deutschmann, O.: CFD Simulation of Liquid Back Suction and Gas Bubble Formation in a Circular Tube with Sudden or Gradual Expansion. Emiss. Control Sci. Technol. 3(4), 289–301 (2017).
  • Günter, T., Pesek, J., Schäfer, K., Bertótiné Abai, A., Casapu, M., Deutschmann, O., Grunwaldt, J.-D.: Cu-SSZ-13 as pre-turbine NOx-removal-catalyst. Appl. Catal., B 198, 548–557 (2016).
  • Brack, W., Heine, B., Birkhold, F., Kruse, M., Deutschmann, O.: Formation of Urea-Based Deposits in an Exhaust System. Emiss. Control Sci. Technol. 2(3), 115–123 (2016).
  • Steinhausen, M., Luo, Y., Popp, S., Strassacker, C., Zirwes, T., Kosaka, H., Zentgraf, F., Maas, U., Sadiki, A., Dreizler, A., Hasse, C.: Numerical Investigation of Local Heat -Release Rates and Thermo-Chemical States in Side-Wall Quenching of Laminar Methane and Dimethyl Ether Flames. Flow Turbulence Combust 38 (1), 83, doi.org/10.1007/s10494-020-00146-w, (2020)
  • Luo, Y., Strassacker, C., Wen, X., Sun, Z., Maas, U., Hasse, C.: Strain Rate Effects on Head-on Quenching of Laminar Premixed Methane-air flames. Flow Turbulence Combust 120 (4), 549, doi.org/10.1007/s10494-020-00179-1, (2020).
  • Minuzzi, F. C., Yu, C., Maas, U.: Numerical Simulation of Laminar and Turbulent Methane/Air Flames Based on a DRG-Derived Skeletal Mechanism. Eurasian Chem. Tech. J. 22 (2), 69, doi.org/10.18321/ectj953, (2020).
  • Yu, C., Bykov, V., Maas, U.: Coupling of simplified chemistry with mixing processes in PDF simulations of turbulent flames. Proceedings of the Combustion Institute 37 (2), 2183–2190, doi.org/10.1016/j.proci.2018.05.126, (2019).
  • Minuzzi, F., Yu, C., Maas, U.: Simulation of methane/air non-premixed turbulent flames based on REDIM simplified chemistry. Flow Turbulence Combust 103 (4), 963–984, doi.org/10.1007/s10494-019-00059-3, (2019).
  • Golda, P., Blattmann, A., Neagos, A., Bykov, V., Maas, U.: Implementation problems of manifolds-based model reduction and their generic solution. Combustion Theory and Modelling 191 (2), 1–30, doi.org/10.1080/13647830.2019.1682198, (2019).
  • Strassacker, C., Bykov, V., Maas, U.: REDIM reduced modeling of flame quenching at a cold wall – The influence of detailed transport models and detailed mechanisms. Combust. Sci. Technol., 1–15 (2018).
  • Strassacker, C., Bykov, V., Maas, U.: REDIM reduced modeling of quenching at a cold wall including heterogeneous wall reactions. Int. J. Heat Fluid Flow 69, 185–193 (2018).
  • Strassacker, C., Bykov, V., Maas, U.: Parametrization strategies for manifold based reduced kinetic models. accepted for the 37th Symposium on Combustion (2018).
  • Ganter, S., Straßacker, C., Kuenne, G., Meier, T., Heinrich, A., Maas, U., Janicka, J.: Laminar near-wall combustion. Int. J. Heat Fluid Flow 70, 259–270 (2018).
  • Steinhilber, G., Bykov, V., Maas, U.: REDIM reduced modeling of flame-wall-interactions: Quenching of a premixed methane/air flame at a cold inert wall. Proc. Combust. Inst. 36(1), 655–661 (2017).
  • Gubernov, V.V., Bykov, V., Maas, U.: Hydrogen/air burner-stabilized flames at elevated pressures. Combust. Flame 185, 44–52 (2017).
  • Schießl, R., Bykov, V., Maas, U., Abdelsamie, A., Thévenin, D.: Implementing multi-directional molecular diffusion terms into Reaction Diffusion Manifolds (REDIMs). Proc. Combust. Inst. 36(1), 673–679 (2017).
  • Neagos, A., Bykov, V., Maas, U.: Adaptive hierarchical construction of Reaction–Diffusion Manifolds for simplified chemical kinetics. Proc. Combust. Inst. 36(1), 663–672 (2017).
  • Strassacker, C., Bykov, V., Maas, U.: REDIM reduced modeling of quenching at a cold inert wall with detailed transport and different mechanisms. 26th ICDERS, Boston, USA, July 30 – August 4 (2017).
  • Stein, M., Bykov, V., Maas, U.: Reduced simulation of the evaporation and decomposition of droplets and films of urea-water solution in exhaust gas environment. Proceedings of the Combustion Institute, doi.org/10.1016/j.proci.2020.06.032, (2020).
  • Golda, P., Blattmann, A., Neagos, A., Bykov, V., Maas, U.: Implementation problems of manifolds-based model reduction and their generic solution. Combustion Theory and Modelling 191 (2), 1–30, doi.org/10.1080/13647830.2019.1682198, (2019).
  • Nishad, K., Stein, M., Ries, F., Bykov, V., Maas, U., Deutschmann, O., Janicka, J., Sadiki, A.: Thermal Decomposition of a Single AdBlue® Droplet Including Wall–Film Formation in Turbulent Cross-Flow in an SCR System. Energies 12 (13), 2600, doi.org/10.3390/en12132600, (2019).
  • Yu, C., Bykov, V., Maas, U.: Global quasi-linearization (GQL) versus QSSA for a hydrogen-air auto-ignition problem. Phys. Chem. Chem. Phys. 20, 10770-10779 (2018).
  • Stein, M., Bykov, V., Bertótiné Abai, A., Janzer, C., Maas, U., Deutschmann, O., Olzmann, M.: A reduced model for the evaporation and decomposition of urea–water solution droplets. Int. J. Heat Fluid Flow 70, 216–225 (2018).
  • Koksharov, A., Yu, C., Bykov, V., Maas, U., Pfeifle, M., Olzmann, M.: Quasi-Spectral Method for the Solution of the Master Equation for Unimolecular Reaction Systems. Int. J. Chem. Kinet. 50(5), 357–369 (2018).
  • Stein, M., Bykov, V., Maas, U.: The Effect of Evaporation Models on Urea Decomposition from Urea-Water-Solution Droplets in SCR Conditions. Emiss. Control Sci. Technol. 3(4), 263–274 (2017).
  • Gubernov, V.V., Bykov, V., Maas, U.: Hydrogen/air burner-stabilized flames at elevated pressures. Combust. Flame 185, 44–52 (2017).
  • Gubernov, V.V., Kolobov, A.V., Bykov, V., Maas, U.: Investigation of rich hydrogen–air deflagrations in models with detailed and reduced kinetic mechanisms. Combust. Flame 168, 32–38 (2016).
  • Korsakova, A.I., Gubernov, V.V., Bykov, V., Maas, U.: The effect of Soret diffusion on stability of rich premixed hydrogen–air flames. Int. J. Hydrogen Energy 41(39), 17670–17675 (2016).
  • Dadvand, A., Bagheri, M., Samkhaniani, N., Marschall, H., Wörner, M.: Advected phase-field method for bounded solution of the Cahn–Hilliard Navier–Stokes equations. Physics of Fluids 33 (5), 53311, doi.org/10.1063/5.0048614, 2021.
  • Wörner, M., Samkhaniani, N., Cai, X., Wu, Y., Majumdar, A., Marschall, H., Frohnapfel, B., Deutschmann, O.: Spreading and rebound dynamics of sub-millimetre urea-water-solution droplets impinging on substrates of varying wettability. Applied Mathematical Modelling 66, 395, doi.org/10.1016/j.apm.2021.01.038, (2021).
  • Jamshidi, F., Heimel, H., Hasert, M., Cai, X., Deutschmann, O., Marschall, H., Wörner, M.: On suitability of phase-field and algebraic volume-of-fluid OpenFOAM® solvers for gas–liquid microfluidic applications. Computer Physics Communications 236, 72–85, doi.org/10.1016/j.cpc.2018.10.015, (2019).
  • Börnhorst, M., Cai, X., Wörner, M., Deutschmann, O.: Maximum Spreading of Urea Water Solution during Drop Impingement. Chem. Eng. Technol. 42 (11), 2419–2427, doi.org/10.1002/ceat.201800755, (2019).
  • Schmidt, M., Ding, C.-P., Peterson, B., Dreizler, A., Böhm, B.: Near-Wall Flame and Flow Measurements in an Optically Accessible SI Engine. Flow Turbulence Combust 49 (4), 949, doi.org/10.1007/s10494-020-00147-9, (2020).
  • Geschwindner, C., Kranz, P., Welch, C., Schmidt, M., Böhm, B., Kaiser, S. A., La Morena, J. de: Analysis of the interaction of Spray G and in-cylinder flow in two optical engines for late gasoline direct injection. International Journal of Engine Research 21 (1), 169–184, doi.org/10.1177/1468087419881535, (2020).
  • Ding, C.-P., Vuilleumier, D., Kim, N., Reuss, D. L., Sjöberg, M., Böhm, B.: Effect of engine conditions and injection timing on piston-top fuel films for stratified direct-injection spark-ignition operation using E30. International Journal of Engine Research 21 (2), 302–318, doi.org/10.1177/1468087419869785, (2020).
  • Haussmann, M., Ries, F., Jeppener-Haltenhoff, J. B., Li, Y., Schmidt, M., Welch, C., Illmann, L., Böhm, B., Nirschl, H., Krause, M. J., Sadiki, A.: Evaluation of a Near-Wall-Modeled Large Eddy Lattice Boltzmann Method for the Analysis of Complex Flows Relevant to IC Engines. Computation 8 (2), 43, doi.org/10.3390/computation8020043, (2020).
  • Hill, H., Ding, C.-P., Baum, E., Böhm, B., Dreizler, A., Peterson, B.: An application of tomographic PIV to investigate the spray-induced turbulence in a direct-injection engine. International Journal of Multiphase Flow 121, 103116, doi.org/10.1016/j.ijmultiphaseflow.2019.103116, (2019).
  • Peterson, B., Baum, E., Dreizler, A., Böhm, B.: An experimental study of the detailed flame transport in a SI engine using simultaneous dual-plane OH-LIF and stereoscopic PIV. Combustion and Flame 202, 16–32, doi.org/10.1016/j.combustflame.2018.12.024, (2019).
  • Ding, C.-P., Sjöberg, M., Vuilleumier, D., Reuss, D.L., He, X., Böhm, B.: Fuel film thickness measurements using refractive index matching in a stratified-charge SI engine operated on E30 and alkylate fuels. Exp. Fluids 59(3), 133 (2018).
  • Bürkle, S., Biondo, L., Ding, C.-P., Honza, R., Ebert, V., Böhm, B., Wagner, S.: In-Cylinder Temperature Measurements in a Motored IC Engine using TDLAS. Flow Turb. Combust. 101(1), 139–159 (2018).
  • Renaud, A., Ding, C.-P., Jakirlic, S., Dreizler, A., Böhm, B.: Experimental characterization of the velocity boundary layer in a motored IC engine. Int. J. Heat Fluid Flow 71, 366-377 (2018).
  • Jainski, C., Rißmann, M., Jakirlic, S., Böhm, B., Dreizler, A.: Quenching of Premixed Flames at Cold Walls. Flow Turb. Combust. 100(1), 177–196 (2018).
  • Forooghi, P., Weidenlener, A., Magagnato, F., Böhm, B., Kubach, H., Koch, T., Frohnapfel, B.: DNS of momentum and heat transfer over rough surfaces based on realistic combustion chamber deposit geometries. Int. J. Heat Fluid Flow 69, 83–94 (2018).
  • Peterson, B., Baum, E., Ding, C.-P., Michaelis, D., Dreizler, A., Böhm, B.: Assessment and application of tomographic PIV for the spray-induced flow in an IC engine. Proc. Combust. Inst. 36(3), 3467–3475 (2017).
  • Honza, R., Ding, C.-P., Dreizler, A., Böhm, B.: Flame imaging using planar laser induced fluorescence of sulfur dioxide. Appl. Phys. B 123(9), 1-6 (2017).
  • He, C., Kuenne, G., Yildar, E., van Oijen, J., Di Mare, F., Sadiki, A., Ding, C.-P., Baum, E., Peterson, B., Böhm, B., Janicka, J.: Evaluation of the flame propagation within an SI engine using flame imaging and LES. Combust. Theor. Model., 1–34 (2017).
  • Bode, J., Schorr, J., Krüger, C., Dreizler, A., Böhm, B.: Influence of three-dimensional in-cylinder flows on cycle-to-cycle variations in a fired stratified DISI engine measured by time-resolved dual-plane PIV. Proc. Comb. Inst. 36(3), 3477–3485 (2017).
  • Jainski, C., Rißmann, M., Böhm, B., Dreizler, A.: Experimental investigation of flame surface density and mean reaction rate during flame–wall interaction. Proc. Combust. Inst. 36(2), 1827–1834 (2017).
  • Jainski, C., Rißmann, M., Böhm, B., Janicka, J., Dreizler, A.: Sidewall quenching of atmospheric lam-inar premixed flames studied by laser-based diagnostics. Combust. Flame 183, 271–282 (2017).
  • Stiehl, R., Bode, J., Schorr, J., Krüger, C., Dreizler, A., Böhm, B.: Influence of intake geometry variations on in-cylinder flow and flow–spray interactions in a stratified direct-injection spark-ignition engine captured by time-resolved particle image velocimetry. Int. J. Engine Res. 17(9), 983–997 (2016).
  • Zentgraf, F., Baum, E., Böhm, B., Dreizler, A., Peterson, B.: On the turbulent flow in piston engines. Phys. Fluids 28(4), 045108 (2016).
  • Kubach, H., Weidenlener, A., Pfeil, J., Koch, T., Kittel, H., Roisman, I.V., Tropea, C.: Investigations on the Influence of Fuel Oil Film Interaction on Pre-ignition Events in Highly Boosted DI Gasoline Engines. SAE 2018-01-1454 (2018).
  • Weidenlener, A., Kubach, H., Pfeil, J., Koch, T.: The Influence of Operating Conditions on Combustion Chamber Deposit Surface Structure, Deposit Thickness and Thermal Properties. Automotive and Engine Technology (2018) (accepted).
  • Forooghi, P., Weidenlener, A., Magagnato, F., Böhm, B., Kubach, H., Koch, T., Frohnapfel, B.: DNS of momentum and heat transfer over rough surfaces based on realistic combustion chamber deposit geometries. Int. J. Heat Fluid Flow 69, 83–94 (2018).
  • Weidenlener, A., Kubach, H., Pfeil, J., Koch, T.: The Influence of Operating Conditions on Combustion Chamber Deposit Surface Structure. COMODIA 2017, Okayama, Japan, July 25-28 (2017).
  • Ganter, S., Straßacker, C., Kuenne, G., Meier, T., Heinrich, A., Maas, U., Janicka, J.: Laminar near-wall combustion. Int. J. Heat Fluid Flow 70, 259–270 (2018).
  • Heinrich, A., Ganter, S., Kuenne, G., Jainski, C., Dreizler, A., Janicka, J.: 3D Numerical Simulation of a Laminar Experimental SWQ Burner with Tabulated Chemistry. Flow Turb. Combust. 100(2), 535–559 (2018).
  • Heinrich, A., Ries, F., Kuenne, G., Ganter, S., Hasse, C., Sadiki, A., Janicka, J.: Large Eddy Simulation with tabulated chemistry of an experimental sidewall quenching burner. Int. J. Heat Fluid Flow 71, 95–110 (2018).
  • Nishad, K., Ries, F., Li, Y., Sadiki, A., Janicka, J., Large eddy simulation of intake flow in DISI engine using near wall modeling, 12th international ERCOFTAC Symposium on Engineering Turbulence Modeling and Measurements (ETMM 12), Montpellier, France, September 26-28, (2018). (accepted)
  • He, C., Kuenne, G., Yildar, E., van Oijen, J., Di Mare, F., Sadiki, A., Ding, C.-P., Baum, E., Peterson, B., Böhm, B., Janicka, J.: Evaluation of the flame propagation within an SI engine using flame imaging and LES. Combust. Theor. Model., 1–34 (2017).
  • He, C., Leudesdorff, W., Di Mare, F., Sadiki, A., Janicka, J.: Analysis of In-cylinder Flow Field Anisotropy in IC Engine using Large Eddy Simulation. Flow Turb. Combust. 99(2), 353-383 (2017).
  • Ganter, S., Heinrich, A., Meier, T., Kuenne, G., Jainski, C., C. Rißmann, M., Dreizler, A., Janicka, J.: Numerical analysis of laminar methane–air side-wall-quenching. Combust. Flame 186, 299–310 (2017).
  • Jainski, C., Rißmann, M., Böhm, B., Janicka, J., Dreizler, A.: Sidewall quenching of atmospheric laminar premixed flames studied by laser-based diagnostics. Combust. Flame 183, 271–282 (2017).
  • Ganter, S., Meier, T., Heinrich, A., Kuenne, G., Janicka, J.: Simulation of near-wall Combustion: Suitability of simple Chemistry Tabulation and Analysis by means of a detailed Kinetics. 28. Deutscher Flammentag: Verbrennung und Feuerung (2017).
  • Sadiki, A., Di Mare, F., Nishad, K., Keller, P., Buhl, S., Hartmann, F., Hasse, C.: Internal combustion engine, in: ERCOFTAC BPG book series: Computational Fluid Dynamics of Turbulent Combustion, 203-290 (2016).
  • Steinhausen, M., Luo, Y., Popp, S., Strassacker, C., Zirwes, T., Kosaka, H., Zentgraf, F., Maas, U., Sadiki, A., Dreizler, A., Hasse, C.: Numerical Investigation of Local Heat -Release Rates and Thermo-Chemical States in Side-Wall Quenching of Laminar Methane and Dimethyl Ether Flames. Flow Turbulence Combust 38 (1), 83, doi.org/10.1007/s10494-020-00146-w, (2020)
  • Kosaka, H., Zentgraf, F., Scholtissek, A., Hasse, C., Dreizler, A.: Effect of Flame-Wall Interaction on Local Heat Release of Methane and DME Combustion in a Side-Wall Quenching Geometry. Flow Turbulence Combust 104 (4), 1029–1046, doi.org/10.1007/s10494-019-00090-4, (2020)
  • Zirwes, T., Häber, T., Zhang, F., Kosaka, H., Dreizler, A., Steinhausen, M., Hasse, C., Stagni, A., Trimis, D., Suntz, R., Bockhorn, H.: Numerical Study of Quenching Distances for Side-Wall Quenching Using Detailed Diffusion and Chemistry. Flow Turbulence Combust 25 (3), 253, doi.org/10.1007/s10494-020-00215-0, (2020)
  • Luo, Y., Strassacker, C., Wen, X., Sun, Z., Maas, U., Hasse, C.: Strain Rate Effects on Head-on Quenching of Laminar Premixed Methane-air flames. Flow Turbulence Combust 120 (4), 549, doi.org/10.1007/s10494-020-00179-1, (2020).
  • Popp, S., Kuenne, G., Janicka, J., Hasse, C.: An extended artificial thickening approach for strained premixed flames. Combustion and Flame 206, 252–265, doi.org/10.1016/j.combustflame.2019.04.047, (2019).
  • Li, Y., Ries, F., Leudesdorff, W., Nishad, K., Pati, A., Hasse, C., Janicka, J., Jakirlić, S., Sadiki, A.: Non-equilibrium wall functions for large Eddy simulations of complex turbulent flows and heat transfer. International Journal of Heat and Fluid Flow 88 (1), 108758,doi.org/10.1016/j.ijheatfluidflow.2020.108758, (2021).
  • Haussmann, M., Ries, F., Jeppener-Haltenhoff, J. B., Li, Y., Schmidt, M., Welch, C., Illmann, L., Böhm, B., Nirschl, H., Krause, M. J., Sadiki, A.: Evaluation of a Near-Wall-Modeled Large Eddy Lattice Boltzmann Method for the Analysis of Complex Flows Relevant to IC Engines. Computation 8 (2), 43, doi.org/10.3390/computation8020043, (2020).
  • Pati, A., Paredi, D., Lucchini, T., Hasse, C.: CFD Modeling of Gas-Fuel Interaction and Mixture Formation in a Gasoline Direct-Injection Engine Coupled With the ECN Spray G Injector. In: SAE Technical Paper Series, APR. 21, 2020, (2020).
  • Ates, C., Börnhorst, M., Koch, R., Eck, M., Deutschmann, O., Bauer, H. -J.: Morphological characterization of urea derived deposits in SCR systems. Chemical Engineering Journal 409 (September 2018), 128230, doi.org/10.1016/j.cej.2020.128230, (2021).
  • Börnhorst, M., Kuntz, C., Tischer, S., Deutschmann, O.: Urea derived deposits in diesel exhaust gas after-treatment: Integration of urea decomposition kinetics into a CFD simulation. Chemical Engineering Science 211, 115319, doi.org/10.1016/j.ces.2019.115319, (2020).
  • Schweigert, D., Damson, B., Lüders, H., Stephan, P., Deutschmann, O.: The effect of wetting characteristics, thermophysical properties, and roughness on spray-wall heat transfer in selective catalytic reduction systems. International Journal of Heat and Mass Transfer 152, 119554, doi.org/10.1016/j.ijheatmasstransfer.2020.119554, (2020).
  • Wan, S., Guo, Y., Häber, T., Suntz, R., Deutschmann, O.: Spatially and Temporally Resolved Measurements of NO Adsorption/Desorption over NOx-Storage Catalyst. Chemphyschem 21 (23), 2497–2501, doi.org/10.1002/cphc.202000765, (2020).
  • Wan, S., Torkashvand, B., Häber, T., Suntz, R., Deutschmann, O.: Investigation of HCHO Catalytic Oxidation over Platinum using Planar Laser-Induced Fluorescence. Applied Catalysis B: Environmental 264 (16), 118473, doi.org/10.1016/j.apcatb.2019.118473, (2020).
  • Tischer, S., Börnhorst, M., Amsler, J., Schoch, G., Deutschmann, O.: Thermodynamics and reaction mechanism of urea decomposition. Phys Chem Chem Phys 21 (30), 16785–16797, doi.org/10.1039/c9cp01529a, (2019).
  • Schweigert, D., Damson, B., Lüders, H., Börnhorst, M., Deutschmann, O.: Heat transfer during spray/wall interaction with urea water solution: An experimental parameter study. International Journal of Heat and Fluid Flow 78, 108432, doi.org/10.1016/j.ijheatfluidflow.2019.108432, (2019).
  • Börnhorst, M., Langheck, S., Weickenmeier, H., Dem, C., Suntz, R., Deutschmann, O.: Characterization of solid deposits from urea water solution injected into a hot gas test rig. Chemical Engineering Journal 377, 119855, doi.org/10.1016/j.cej.2018.09.016, (2019).
  • Börnhorst, M., Cai, X., Wörner, M., Deutschmann, O.: Maximum Spreading of Urea Water Solution during Drop Impingement. Chem. Eng. Technol. 42 (11), 2419–2427, doi.org/10.1002/ceat.201800755, (2019).
  • Börnhorst, M., Deutschmann, O.: Single droplet impingement of urea water solution on a heated substrate. Int. J. Heat Fluid Flow 69, 55–61 (2018).
  • Günter, T., Pesek, J., Schäfer, K., Bertótiné Abai, A., Casapu, M., Deutschmann, O., Grunwaldt, J.-D.: Cu-SSZ-13 as pre-turbine NOx-removal-catalyst. Appl. Catal., B 198, 548–557 (2016).
  • Ries, F., Li, Y., Nishad, K., Dressler, L., Ziefuss, M., Mehdizadeh, A., Hasse, C., Sadiki, A.: A Wall-Adapted Anisotropic Heat Flux Model for Large Eddy Simulations of Complex Turbulent Thermal Flows. Flow Turbulence Combust 106 (2), 733–752, doi.org/10.1007/s10494-020-00201-6, (2021).
  • Li, Y., Ries, F., Leudesdorff, W., Nishad, K., Pati, A., Hasse, C., Janicka, J., Jakirlić, S., Sadiki, A.: Non-equilibrium wall functions for large Eddy simulations of complex turbulent flows and heat transfer. International Journal of Heat and Fluid Flow 88 (1), 108758,doi.org/10.1016/j.ijheatfluidflow.2020.108758, (2021).
  • Dressler, L., Sacomano Filho, F. L., Sadiki, A., Janicka, J.: Influence of Thickening Factor Treatment on Predictions of Spray Flame Properties Using the ATF Model and Tabulated Chemistry. Flow Turbulence Combust 32 (9), 1605, doi.org/10.1007/s10494-020-00149-7, (2020).
  • Nishad, K., Stein, M., Ries, F., Bykov, V., Maas, U., Deutschmann, O., Janicka, J., Sadiki, A.: Thermal Decomposition of a Single AdBlue® Droplet Including Wall–Film Formation in Turbulent Cross-Flow in an SCR System. Energies 12 (13), 2600, doi.org/10.3390/en12132600, (2019).
  • Ries, F., Li, Y., Nishad, K., Janicka, J., Sadiki, A.: Entropy Generation Analysis and Thermodynamic Optimization of Jet Impingement Cooling Using Large Eddy Simulation. Entropy 21 (2), 129, doi.org/10.3390/e21020129, (2019).
  • Mahmoud, R., Jangi, M., Ries, F., Fiorina, B., Janicka, J., Sadiki, A.: Combustion Characteristics of a Non-Premixed Oxy-Flame Applying a Hybrid Filtered Eulerian Stochastic Field/Flamelet Progress Variable Approach. Applied Sciences 9 (7), 1320, doi.org/10.3390/app9071320, (2019).
  • Nishad, K., Ries, F., Li, Y., Sadiki, A.: Numerical Investigation of Flow through a Valve during Charge Intake in a DISI -Engine Using Large Eddy Simulation. Energies 12 (13), 2620, doi.org/10.3390/en12132620, (2019).
  • Ries, F., Li, Y., Rißmann, M., Klingenberg, D., Nishad, K., Böhm, B., Dreizler, A., Janicka, J., Sadiki, A.: Database of Near-Wall Turbulent Flow Properties of a Jet Impinging on a Solid Surface under Different Inclination Angles. Fluids 3(1), 5 (2018).
  • Ries, F., Li, Y., Klingenberg, D., Nishad, K., Janicka, J., Sadiki, A.: Near-Wall Thermal Processes in an Inclined Impinging Jet: Heat Transport and Entropy Generation Mechanisms. Energies 11(6), 1354 (2018).
  • Nishad, K., Sadiki, A., Janicka, J.: Numerical Investigation of AdBlue Droplet Evaporation and Thermal Decomposition in the Context of NOx-SCR Using a Multi-Component Evaporation Model. Energies 11(1), 222–244 (2018).
  • Nishad, K., Ries, F., Janicka, J., Sadiki, A.: Analysis of spray dynamics of urea–water-solution jets in a SCR-DeNOx system: An LES study. Int. J. Heat Fluid Flow 70, 247–258 (2018).
  • Sacomano Filho, F.L., Kadavelil, J., Staufer, M., Sadiki, A., Janicka, J.: Analysis of LES-based combustion models applied to an acetone turbulent spray flame. Combust. Sci. Technol. 140(3), 1–14 (2018).
  • Sacomano Filho, F. L., Speelman, N., van Oijen, J. A., de Goey, L. H. P., Sadiki, A., Janicka, J.: Numerical analyses of laminar flames propagating in droplets mists using detailed and tabulated chemistry. Combust. Theory Modell., 1-35 (2018) (accepted).
  • Ries, F., Li, Y., Sadiki, A.: Entropy production in near-wall turbulent flow inside a generic air-to-air plate heat exchanger. 6th European Conference on Computational Mechanics (ECMM), Glasgow, UK, 11-15 June (2018).
  • Ries, F., Li, Y., Nishad, K., Janicka, J., Sadiki, A.: Study of non-equilibrium boundary layers in a generic DEF-injection system using DNS. 12th International Symposium on Engineering Turbulence Modelling and Measurements (ETMM12), Montpellier, France, September 26-28 (2018)
  • Li, Y., Ries, F., Nishad, K., Sadiki, A.: Near-wall modeling of LES for non-equilibrium turbulent flows in an inclined impinging jet with moderate Re-number. 6th European Conference on Computational Mechanics (ECMM), Glasgow, UK, 11-15 June (2018)
  • Sacomano Filho, F.L., Kuenne, G., Chrigui, M., Sadiki, A., Janicka, J.: A consistent Artificially Thickened Flame approach for spray combustion using LES and the FGM chemistry reduction method. Combust. Flame 184, 68–89 (2017).