Andrei Lipatnikov
Date of birth: May 02, 1961
Citezenship: SWEDEN
- MS degree in Chemical Physics from the Department of Molecular and Chemical Physics of Moscow Institute of Physics and Technology (MIPT), Russia, 1984
- Ph. Doctor in Chemical Physics from the Department of Molecular and Chemical Physics of MIPT, 1987
- 1987-1988: Research Associate, MIPT, Russia
- 1988-1992: Research Scientist, MIPT, Russia
- 1992-1996: Senior Research Scientist, MIPT, Russia
- 1996-1998: Guest Scientist, Chalmers University of Technology, SWEDEN
- 1998-2017: Senior Researcher, Chalmers University of Technology, SWEDEN
- 2017-present Research Professor Chalmers University of Technology, SWEDEN
Numerical simulations and theoretical investigations of combustion with the emphasis being placed on:
- Premixed turbulent flames
- Laminar flames
- Pollutant formation
- Gas mixture autoignition
about 320 scientific contributions including 147 journal papers
- Lipatnikov, A.N., Lee, H.C., Wu, B., Dai, P., Wan, M., and Sabelnikov, V.A.,
"Transition from turbulence-dominated to instability-dominated combustion regime in lean hydrogen-air flames,"
Combustion and Flame, 259: 113170, 2024.
- Lee, H.C., Wu, B., Dai, P., Wan, M., and Lipatnikov, A.N.,
"Turbulent burning velocity and thermodiffusive instability of premixed flames,"
Physical Review E, 108: 035101, 2023.
- Lipatnikov, A.N. and Sabelnikov, V.A.,
"Influence of small-scale turbulence on internal flamelet structure,"
Physics of Fluids, 35: 055128, 2023.
- Lee, H.C., Dai, P., Wan, M., and Lipatnikov, A.N.,
"Displacement speed, flame surface density, and burning rate in highly turbulent premixed flames characterized by low Lewis numbers,"
Journal of Fluid Mechanics, 961: A21, 2023.
- Sabelnikov, V.A., Lipatnikov, A.N., Nikitin, N., Hernandez-Perez, F.E., and Im, H.G.,
"Backscatter of scalar variance in turbulent premixed flames,"
Journal of Fluid Mechanics, 960: R2, 2023.
- Chomiak, J. and Lipatnikov, A.N., "Simple criterion of importance of laminar flame instabilities in premixed turbulent combustion of mixtures characterized by low Lewis numbers," Physical Review E, 107, 015102, 2023.
- Lipatnikov, A.N., Yi-Rong Chen, Y.-R., and Shy, S., "An experimental study of the influence of Lewis number on turbulent flame speed at different pressures," Proceedings of the Combustion Institute, 39, 2339-2347, 2023.
- Mousavi, S.M. and Lipatnikov, A.N.,
"Are differential diffusion effects of importance when burning hydrogen under elevated pressures and temperatures?"
International Journal of Hydrogen Energy, 49(B), 1048-1058, 2024.
- Lipatnikov, A.N., "A priori test of perfectly stirred reactor approach to evaluating mean fuel consumption and heat release rates in highly turbulent premixed flames," International Journal of Engine Research, 24, 4034-4043, 2023.
- Sabelnikov, V.A., Lipatnikov, A.N., Nikitin, N., Hernandez-Perez, F.E., and Im, H.G., "Effects of thermal expansion on moderately intense turbulence in premixed flames," Physics of Fluids, 34, 115127, 2022.
- Lipatnikov, A.N. and Sabelnikov, V.A., "Karlovitz numbers and premixed turbulent combustion regimes for complex-chemistry flames," Energies, 15, 5840, 2022.
- Sabelnikov, V.A., Lipatnikov, A.N., Nikitin, N., Hernandez-Perez, F.E., and Im, H.G., "Conditioned structure functions in turbulent hydrogen/air flames," Physics of Fluids, 34, 085103, 2022.
- Lee, H.C., Abdelsamie, A., Dai, P., Wan, M., and Lipatnikov, A.N., "Influence of equivalence ratio on turbulent burning velocity and extreme fuel consumption rate in lean hydrogen-air turbulent flames," Fuel, 327: 124969, 2022.
- Lee, H.C., Dai, P., Wan, M., and Lipatnikov, A.N., "A numerical support of leading point concept," International Journal of Hydrogen Energy, 47: pp. 23444-23461, 2022.
- Lipatnikov, A.N. and Sabelnikov, V.A., "Flame folding and conditioned concentration profiles in moderately intense turbulence," Physics of Fluids, 34: 065119, 2022.
- Lee, H.C., Dai, P., Wan, M., and Lipatnikov, A.N., "Lewis number and preferential diffusion effects in lean hydrogen–air highly turbulent flames," Physics of Fluids, 34: 035131, 2022.
- Lee, H.C., Dai, P., Wan, M., and Lipatnikov, A.N., "A DNS study of extreme and leading points in lean hydrogen-air turbulent flames - part I: Local thermochemical structure and reaction rates," Combustion and Flame, 235, 111716, 2022.
- Lee, H.C., Dai, P., Wan, M., and Lipatnikov, A.N., "A DNS study of extreme and le
ading points in lean hydrogen-air turbulent flames - part II: Local velocity field and flame topology," Combustion and Flame, 235, 111712, 2022.
- Huang, C., Bloching, M., and Lipatnikov, A.N., "A vented corn starch dust explosion in an 11.5 m3 vessel: Experimental and numerical study," Journal of Loss Prevention in the Process Industries, 75, 104707, 2022.
- Lee, H.C., Dai, P., Wan, M., and Lipatnikov, A.N., "Influence of molecular transport on burning rate and conditioned species concentrations in highly turbulent premixed flames," Journal of Fluid Mechanics, 298, A5, 2021.
- Sabelnikov, V.A. and Lipatnikov, A.N., "Scaling of reaction progress variable variance in ighly turbulent reaction waves," Physics of Fluids, 33, 085103, 2021.
- Sabelnikov, V.A., Lipatnikov, A.N., and Troshin, A-I., "Smallest scale of wrinkles of Huygens front in extremely strong turbulence," Physical Review E, 104, 045101, 2021.
- Lipatnikov, A.N., Nilsson, T., Yu, R., Bai, X.-S., and Sabelnikov, V.A., "Assessment of a flamelet approach to evaluating mean species mass fractions in moderately and highly turbulent premixed flames," Physics of Fluids, 33, 045121, 2021.
- Sabelnikov, V.A., Lipatnikov, A.N., Nishiki, S., Dave, H.L., Hernandez-Perez, F.E., Song, W., and Im, H.G., "Dissipation and dilatation rates in premixed turbulent flames," Physics of Fluids, 33, 035112, 2021.
- Yu, R., Nilsson, T., Fureby, C., and Lipatnikov, A.N., "Evolution equations for the decomposed components of displacement speed in a reactive scalar field," Journal of Fluid Mechanics, 911: A38, 2021.
- Verma, S., Monnier, F., and Lipatnikov, A.N., "Validation of leading point concept in RANS simulations of highly turbulent lean syngas-air flames with well-pronounced diffusional-thermal effects," International Journal of Hydrogen Energy, 46, 2021.
- Lipatnikov, A.N., Sabelnikov, V.A., Hernandez-Perez, F.E., Song, W., and Im, H.G, "Prediction of mean radical concentrations in lean hydrogen-air turbulent flames at different Karlovitz numbers adopting a newly extended flamelet-based presumed PDF," Combustion and Flame, 226: pp. 248-259, 2021.
- Lipatnikov, A.N. and Sabelnikov, V.A., "An extended flamelet-based presumed probability density function for predicting mean concentrations of various species in premixed turbulent flames," International Journal of Hydrogen Energy, 45: pp. 31162-31178, 2020.
- Sabelnikov, V.A., Lipatnikov, A.N., Nikitin, N., Nishiki, S., and Hasegawa, T., "Solenoidal and potential velocity fields in weakly turbulent premixed flames,"Proceedings of the Combustion Institute, 38: pp. 3087-3095, 2021.
- Sabelnikov, V.A., Lipatnikov, A.N., Nikitin, N., Nishiki, S., and Hasegawa, T., "Application of Helmholtz-Hodge decomposition and conditioned structure functions to exploring influence of premixed combustion on turbulence upstream of the flame,"Proceedings of the Combustion Institute, 38: pp. 3077-3085, 2021.
- Lipatnikov, A.N. and Sabelnikov, V.A., "Evaluation of mean species mass fractions in premixed turbulent flames: A DNS study," Proceedings of the Combustion Institute, 38: pp. 6413-6420, 2021.
- Sabelnikov, V.A. and Lipatnikov, A.N., "Passive front propagation in intense turbulence: early transient and late statistically stationary stages of the front area evolution," Energies, 14: 5102, 2021.
- Lipatnikov, A.N., Sabelnikov, V.A., Hernandez-Perez, F.E., Song, W., and Im, H.G, "A priori DNS study of applicability of flamelet concept to predicting mean concentrations of species in turbulent premixed flames at various Karlovitz numbers," Combustion and Flame, 222: pp. 370-382, 2020.
- Lipatnikov, A.N., Sabelnikov, V.A., Nikitin, N., Nishiki, S., and Hasegawa, T., "Influence of thermal expansion on potential and rotational components of turbulent velocity field within and upstream of premixed flame brush," Flow, Turbulence and Combustion, 106: pp. 1111-1124, 2021.
- Yu, R., Nilsson, T., Brethouwer, G., Chakraborty, N., and Lipatnikov, A., "Assessment of an evolution equation for the displacement speed of a constant-density reactive scalar field," Flow, Turbulence and Combustion, 106: pp. 1091-1110, 2021.
- Lipatnikov, A.N. and Sabelnikov, V.A., "Bifractal nature of turbulent reaction waves at high Damköhler and Karlovitz numbersBifractal nature of turbulent reaction waves at high Damköhler and Karlovitz numbers," Physics of Fluids, 32: 095118, 2020.
- Huang, C., Lipatnikov, A.N., and Nessvi, K., Unsteady 3-D RANS simulations of dust explosion in a fan stirred explosion vessel using an open source code," Journal of Loss Prevention in the Process Industries, 67: 104237, 2020.
- Sabelnikov, V.A. and Lipatnikov, A.N., "A new mathematical framework for describing thin-reaction-zone regime of turbulent reacting flows at low Damköhler number," Fluids, 5:109, 2020,
- Brearley, P., Ahmed, U., Chakraborty, N., and Lipatnikov, A., "Statistical behaviors of conditioned two-point second-order structure functions in turbulent premixed flames in different combustion regimes," Physics of Fluids, 31: 115109, 2019.
- Sabelnikov, V.A., Yu, R., and Lipatnikov, A.N., "Thin reaction zones in constant-density turbulent flows at low Damköhler numbers: Theory and simulations," Physics of Fluids, 31: 055104, 2019.
- Lipatnikov, A.N., Sabelnikov, V.A., Nishiki, S., and Hasegawa, T., "A direct numerical simulation study of the influence of flame-generated vorticity on reaction-zone-surface area in weakly turbulent premixed combustion," Physics of Fluids, 31: 055101, 2019.
- Yu, R., Nillson, T., Bai, X-S., and Lipatnikov, A.N., "Evolution of averaged local premixed flame thickness in a turbulent flow," Combustion and Flame, 207: pp. 232-249, 2019.
- Yu, R. and Lipatnikov, A.N., "Surface-averaged quantities in turbulent reacting flows and relevant evolution equations," ,Physical Review E, 100: 013107, 2019.
- Sabelnikov, V.A., Lipatnikov, A.N., Nishiki, S., and Hasegawa, T., "Investigation of the influence of combustion-induced thermal expansion on two-point turbulence statistics using conditioned structure functions," Journal of Fluid Mechanics, 867: pp. 45-76, 2019.
- Sabelnikov, V.A., Lipatnikov, A.N., Nishiki, S., and Hasegawa, T., "Application of conditioned structure functions to exploring influence of premixed combustion on two-point turbulence statistics," Proceedings of the Combustion Institute, 37: pp. 2433-2441, 2019.
- Yu, R. and Lipatnikov, A.N., "Statistics conditioned to iso-scalar surfaces in highly turbulent premixed reacting systems," Computers & Fluids, 187: pp. 69-82, 2019.
- Lipatnikov, A.N., Nishiki, S., and Hasegawa, T., "A DNS assessment of linear relations between filtered reaction rate, flame surface density, and scalar dissipation rate in a weakly turbulent premixed flame,"Combustion Theory and Modelling, 23: pp. 245-260, 2019.
- Yu, R. and Lipatnikov, A.N., "A DNS study of sensitivity of scaling exponents for premixed turbulent consumption velocity to transient effects," Flow, Turbulence and Combustion, 102: pp. 679-698, 2019.
- Lipatnikov, A.N., Sabelnikov, V.A., and Poludnenko, A.Y., "Assessment of a transport equation for mean reaction rate using DNS data obtained from highly unsteady premixed turbulent flames," International Journal of Heat and Mass Transfer, 134: pp. 398-404, 2019.
- Sabelnikov, V.A., Yu, R., and Lipatnikov, A.N., "Thin reaction zones in highly turbulent medium," International Journal of Heat and Mass Transfer, 128: pp. 1201-1205, 2019.
- Lipatnikov, A.N., Nishiki, S., and Hasegawa, T., "Closure relations for fluxes of flame surface density and scalar dissipation rate in turbulent premixed flames," Fluids, 4: 43, 2019.
- Yu, R. and Lipatnikov, A.N., "DNS study of the bending effect due to smoothing mechanism," Fluids, 4: 31, 2019.
- Lipatnikov, A.N., Chakraborty, N., and Sabelnikov, V.A., "Transport equations for reaction rate in laminar and turbulent premixed flames characterized by non-unity Lewis number," International Journal of Hydrogen Energy, 43: pp. 21060-21069, 2018.
- Lipatnikov, A.N., Sabelnikov, V.A., Nishiki, S., and Hasegawa, T., "Does flame-generated vorticity increase turbulent burning velocity?," Physics of Fluids, 30: 081702, 2018.
- Lipatnikov, A.N., Sabelnikov, V.A., Nishiki, S., and Hasegawa, T., "Combustion-induced local shear layers within premixed flamelets in weakly turbulent flows," Physics of Fluids, 30: 085101, 2018
- Lipatnikov, A.N., Chomiak, J., Sabelnikov, V.A., Nishiki, S., and Hasegawa, T., "A DNS study of the physical mechanisms associated with density ratio influence on turbulent burning velocity in premixed flames," Combustion Theory and Modelling, 22: pp. 131-155, 2018.
- Lipatnikov, A.N., Sabelnikov, V.A., Chakraborty, N., Nishiki, S., and Hasegawa, T., "A DNS study of closure relations for convection flux term in transport equation for mean reaction rate in turbulent flow," Flow, Turbulence and Combustion, 100: pp. 75-92, 2018.
- Kaltashov I.A., Pawlowski J.W., Yang W., Muneeruddin K., Yao H., Bobst C.E., and Lipatnikov A.N., "LC/MS at the whole protein level: Studies of biomolecular structure and interactions using native LC/MS and cross-path reactive chromatography (XP-RC) MS," Methods, 144: pp. 14-26, 2018.
- Lipatnikov, A.N., "Stratified turbulent flames: Recent advances in understanding the influence of mixture inhomogeneities on premixed combustion and modeling challenges," Progress in Energy and Combustion Science, 62: pp.87-132, 2017.
- Sabelnikov, V.A. and Lipatnikov, A.N., "Recent advances in understanding of thermal expansion effects in premixed turbulent flames," Annual Review of Fluid Mechanics, 49: pp. 91-117, 2017.
- Yu, R. and Lipatnikov, A.N., "DNS study of dependence of bulk consumption velocity in a constant-density reacting flow on turbulence and mixture characteristics," Physics of Fluids 29: 065116, 2017.
- Sabelnikov, V.A., Lipatnikov, A.N., Chakraborty, N., Nishiki, S., and Hasegawa, T. "A balance equation for the mean rate of product creation in premixed turbulent flames," Proceedings of the Combustion Institute, 36: 1893-1901, 2017.
- Elperin, T., Kleeorin, N., Liberman, M., Lipatnikov, A.N., Rogachevskii, I., and R. Yu, R., "Turbulent diffusion of chemically reacting flows: Theory and numerical simulations," Physical Review E, 96: 053111, 2017.
- Yu, R., Lipatnikov, A.N., "Direct numerical simulation study of statistically stationary propagation of a reaction wave in homogeneous turbulence," Physical Review E 95: 063101, 2017.
- Lipatnikov, A.N., Sabelnikov, V.A., Nishiki, S., and Hasegawa, T., "Flamelet perturbations and flame surface density transport in weakly turbulent premixed combustion," Combustion Theory and Modelling, 21: pp. 205-227, 2017.
- Lipatnikov, A.N., Li, W.Y., Jiang, L.J., and Shy, S.S., "Does density ratio significantly affect turbulent flame speed?" Flow, Turbulence and Combustion, 98: pp.1153-1172, 2017.
- Lai, J., Chakraborty, N., and Lipatnikov, A.N., "Statistical behaviour of vorticity and enstrophy transport in head-on quenching of turbulent premixed flames,"
European Journal of Mechanics - B/Fluids, 65: pp. 384-397, 2017.
- Sabelnikov, V.A., Lipatnikov, A.N., Chakraborty, N., Nishiki, S., and Hasegawa, T. "A transport equation for reaction rate in turbulent flows," Physics of Fluids, 28: 081701, 2016.
- Verma, S. and Lipatnikov, A.N. "Does sensitivity of measured scaling exponents for turbulent burning velocity to flame configuration prove lack of generality of notion of turbulent burning velocity?
Combustion and Flame, 173: pp. 77-88, 2016.
- Sabelnikov, V.A., Petrova, N.N., and Lipatnikov, A.N. "Analytical and numerical study of travelling waves using the Maxwell-Cattaneo relaxation model extended to reaction-advection-diffusion systems,"
Physical Review E 94: 042218, 2016.
- Chakraborty, N., Konstantinou, I., and Lipatnikov, A.N. "Effects of Lewis number on
vorticity and enstrophy transport in turbulent premixed flames,"
Physics of Fluids 28: 015109, 2016.
- Huang, C., Yasari, E., Johansen, L.C.R., Hemdal, S., and Lipatnikov, A.N.
"Application of Flame Speed Closure Model to RANS Simulations of Stratified Turbulent Combustion in a Gasoline Direct-Injection Spark-Ignition Engine,"
Combustion Science and Technology, 188(1): pp. 98-131, 2016.
- Lipatnikov, A.N. "A balance equation for modeling conditioned enthalpies in premixed turbulent flames,"Combustion and Flame, 162: pp. 3691-3703, 2015.
- Yu, R., Bai, X.-S., and Lipatnikov, A.N. "A direct numerical simulation study of interface propagation in homogeneous turbulence,"
Journal of Fluid Mechanics, 772; pp. 127-164, 2015.
- Sabelnikov, V.A. and Lipatnikov, A.N. "Transition from pulled to pushed fronts in premixed turbulent combustion: theoretical and numerical study," Combustion and Flame, 162: pp. 2893-2903, 2015.
- Lipatnikov, A.N., Shy, S.S., and Li, W.-y. "Experimental assessment of various methods of determination of laminar flame speed in experiments with expanding spherical flames with positive Markstein lengths." Combustion and Flame, 162: pp. 2840¿2854, 2015.
- Lipatnikov, A.N., Sabelnikov, V.A., Nishiki, S., Hasegawa, T., and Chakraborty, N. "DNS assessment of a simple model for evaluating velocity conditioned to unburned gas in premixed turbulent flame," Flow, Turbulence and Combustion, 94: pp. 513-526, 2015.
- Lipatnikov, A.N., Chomiak, J., Sabelnikov, V.A., Nishiki, S., and Hasegawa, T. "Unburned mixture fingers in premixed turbulent flames"
Proceedings of the Combustion Institute, 35, pp. 1401-1408, 2015.
- Shy, S.S., Liu, C.C., Lin, J.Y., Chen, L.L., Lipatnikov, A.N., and Yang, S.I.
"Correlations of high-pressure lean methane and syngas turbulent burning velocities: Effects of turbulent Reynolds, Damkohler, and Karlovitz numbers"
Proceedings of the Combustion Institute, 35, pp. 1509-1516, 2015.
- Lipatnikov, A.N., Nishiki, S., and Hasegawa, T. "DNS assessment of relation between mean reaction and scalar dissipation rates in the flamelet regime of premixed turbulent combustion," Combustion Theory and Modelling, 19: pp. 309-328, 2015,
- Yasari, E., Verma, S., and Lipatnikov, A.N. "RANS simulations of statistically stationary premixed turbulent combustion using Flame Speed Closure model," Flow, Turbulence and Combustion, 94: pp. 381-414, 2015.
- Lipatnikov, A.N. and Huang, C.
"Modelling of the influence of mixture fraction fluctuations on burning rate in partially premixed turbulent flames"
Combustion Science and Technology, 187, pp. 594-626, 2015.
- Lipatnikov, A.N., Nishiki, N., and Hasegawa, T. "A direct numerical simulation study of vorticity transformation in weakly turbulent premixed flames"
Physics of Fluids, 26, 105104, 2014.
- Sabelnikov, V.A. and Lipatnikov, A.N. "Speed selection for traveling-wave solutions to the diffusion-reaction equation with cubic reaction term
and Burgers nonlinear convection" Physical Review E, 90, 033004, 2014.
- Yu, R., Lipatnikov, A.N., and Bai, X.S. "Three-dimensional direct numerical simulation study of conditioned moments
associated with front propagation in turbulent flows" Physics of Fluids, 26, 085104, 2014.
- Sabelnikov, V.A. and Lipatnikov, A.N. "Transition from pulled to pushed premixed turbulent flames due to
countergradient transport" Combustion Theory and Modelling, 17, pp. 1154–1175, 2013.
- Lipatnikov, A.N. and Sabelnikov, V.A. "Transition from countergradient to gradient scalar transport in
developing premixed turbulent flames", Flow, Turbulence, and Combustion, 90, pp. 401-418, 2013.
- Sabelnikov, V.A. and Lipatnikov, A.N. "Towards an Extension of TFC Model of Premixed Turbulent Combustion",
Flow, Turbulence, and Combustion, 90, pp. 387-400, 2013.
- Chakraborty, N. and Lipatnikov, A.N. "Effects of Lewis Number on Conditional Fluid Velocity Statistics in Low
Damkohler Number Turbulent Premixed Combustion: A Direct Numerical Simulation Analysis", Physics of Fluids, 25, 045101, 2013.
- Chakraborty, N. and Lipatnikov, A.N. "Conditional velocity statistics for high and low Damkohler number
turbulent premixed combustion in the context of Reynolds Averaged Navier Stokes simulations", Proceedings of the Combustion Institute, 34, pp. 1333-1345,
2013.
- Huang, C. and Lipatnikov, A.N. "Comparison of presumed PDF models of turbulent flames,"
Journal of Combustion, Article ID 564621, 15 pages, 2012.
- Lipatnikov, A.N. "Transient behavior of turbulent scalar transport in
premixed flames," Flow, Turbulence, and Combustion, 86, pp. 609-637, 2011.
- Sabel'nikov, V.A. and Lipatnikov, A.N.
"A simple model for evaluating conditioned velocities in premixed turbulent flames,"
Combustion Science and Technology, 183, pp. 588-613, 2011.
- Lipatnikov, A.N. "Conditioned moments in premixed turbulent reacting flows,"
Proceedings of the Combustion Institute, 33, pp. 1489-1496 2011.
- Lipatnikov, A.N. "A test of conditioned balance equation approach,"
Proceedings of the Combustion Institute, 33, pp. 1497-1504, 2011.
- Lipatnikov, A.N. "Burning rate in impinging jet flames,"
Journal of Combustion, Article ID 737914, 11 pages, 2011.
- Chakraborty, N. and Lipatnikov, A.N. "Statistics of conditional fluid velocity in the corrugated
flamelets regime of turbulent premixed combustion: A direct numerical simulation study,"
Journal of Combustion. Article ID 628208, 13 pages. 2011.
- Lipatnikov, A.N. "Reply to comments by Zimont," Combustion and Flame, 158,
pp.2073-2074, 2011.
- Sabel'nikov, V.A. and Lipatnikov, A.N. "Rigorous derivation of an unclosed
mean G-equation for statistically 1D premixed turbulent flames,"
International Journal of Spray and Combustion Dynamics, 2, pp.301-324, 2010.
- Lipatnikov, A.N.
"Simulations of scalar transport in developing turbulent flames solving a conditioned balance equation,"
Combustion Science and Technology, 182, pp. 405-421, 2010.
- Lipatnikov, A.N. and Chomiak, J. "Effects of premixed flames on turbulence
and turbulent scalar transport," Progress in Energy and Combustion Science,
36, pp. 1-102, 2010.
- Lipatnikov, A.N. "Can we characterize turbulence in premixed flames?"
Combustion and Flame, 156, pp. 1242-1247, 2009.
- Lipatnikov, A.N. "Testing Premixed Turbulent Combustion Models by Studying Flame Dynamics",
International Journal of Spray and Combustion Dynamics, 1/1, pp. 39-66, 2009.
- Lipatnikov, A.N. and Sabel'nikov, V.A. "Some Basic Issues of the Averaged G-Equation
Approach to Premixed Turbulent Combustion Modeling," The Open Thermodynamics Journal, 2, pp.53-58, 2008.
- Lipatnikov, A.N. "Conditionally Averaged Balance Equations for Modeling
Premixed Turbulent Combustion in Flamelet Regime", Combustion and Flame,
152/4, pp. 529-547, 2008.
- Lipatnikov, A.N. and Chomiak, J. "Global Stretch Effects in Premixed Turbulent Combustion",
Proceedings of the Combustion Institute, 31, pp. 1361-1368, 2007.
- Sathiah, P. and Lipatnikov, A.N. "Effects of Flame Development on Stationary Premixed Turbulent Combustion",
Proceedings of the Combustion Institute, 31, pp. 3115-3122, 2007.
- Sathiah, P. and Lipatnikov, A.N. "Effects of Turbulent Flame Speed Development and Axial Convective Waves on
Oscillations of a Long Ducted Flame," Combustion Science and Technology,
179, pp. 1433-1449, 2007.
- Lipatnikov, A.N. "Scalar Transport in Self-Similar, Developing, Premixed, Turbulent Flames",
Combustion Science and Technology, 179, pp. 91-115, 2007.
- Lipatnikov, A.N. and Sathiah, P. "Effects of Turbulent Flame Development on Thermoacoustic Oscillations,"
Combustion and Flame, 142, pp. 130-139, 2005.
- Lipatnikov, A.N. and Chomiak, J. "Numerical Tests of a Measurement Method for Turbulent Burning Velocity
in Stagnation Flames", Combustion Science and Technology, 178, pp. 1117-1151, 2006.
- Lipatnikov, A.N. and Chomiak, J. "Molecular transport effects on turbulent flame propagation and structure",
Progress in Energy and Combustion Science, 31, pp. 1-73, 2005.
- Lipatnikov, A.N. and Chomiak, J. "Self-similarly developing, premixed, turbulent flames:
a theoretical study," Physics of Fluids, 17, 065105, 2005.
- Lipatnikov, A.N. and Chomiak, J. "A theoretical study of premixed turbulent flame development,"
Proceedings of the Combustion Institute, 30, pp. 843-850, 2005.
- Lipatnikov, A.N. and Chomiak, J. "Effects of turbulent flame development on thermoacoustic oscillations,"
Combustion and Flame, 142, pp. 130-139, 2005.
- Lipatnikov, A.N. and Chomiak, J. "A study of the effects of pressure-driven transport
on developing turbulent flame structure and propagation", Combustion Theory and Modelling, 8, pp.211-225, 2004.
- Lipatnikov, A.N. and Chomiak, J. "Application of the Markstein Number Concept to Curved Turbulent Flames",
Combustion Science and Technology, 176, pp.331-358, 2004.
- Lipatnikov, A.N. and Chomiak, J. "Comment on "Turbulent burning velocity, burned gas distribution, and associated flame
surface definition" D. Bradley, M.Z. Haq, R.A. Hicks, T. Kitagawa, M. Lawes, C.G.W. Sheppard, R. Woolley,
Combust. Flame 133 (2003) 415" Combustion and Flame, 137, pp. 261-263, 2004.
- Lipatnikov, A.N. and Chomiak, J. "Turbulent Flame Speed and Thickness:Phenomenology, Evaluation, and Application
in Multi-Dimensional Simulations", Progress in Energy and Combustion Science, 28, No. 1, pp. 1-73, 2002.
- Lipatnikov, A.N. and Chomiak, J. "Turbulent Burning Velocity and Speed
of Developing, Curved, and Strained Flames", Proceedings of the Combustion Institute, 29, pp. 2113-2121, 2002.
- Wallesten, J., Lipatnikov, A.N., and Chomiak, J.
"Modeling of stratified combustion in a DI SI engine using detailed chemistry pre-processing",
Proceedings of the Combustion Institute, 29, pp. 707-709, 2002.
- Lipatnikov, A.N. Comments on the paper "Premixed Flames in Stagnating Turbulence Part V -- Evaluation of Models for
the Chemical Source Term" by Bray, K.N.C., Champion, M., and Libby, P.A., Combustion and Flame, 131, pp.219-221, 2002.
- Lipatnikov, A.N. and Chomiak, J. "Are Premixed Turbulent Stagnation Flames Equivalent to Fully Developed Ones?
A Computational Study", Combustion Science and Technology, 174, pp.3-26, 2002.
- Lipatnikov, A.N. and Chomiak, J. "Dependence of Heat Release on the Progress Variable in Premixed Turbulent
Combustion", Proceedings of the Combustion Institute, 28, pp.227-234, 2000.
- Lipatnikov, A.N. and Chomiak, J. "Developing Premixed Turbulent Flames: Part I. A Self-Similar Regime of
Flame Propagation", Combustion Science and Technology, 162, pp. 85-112, 2001.
- Lipatnikov, A.N. and Chomiak, J. "Developing Premixed Turbulent Flames: Part II. Pressure-Driven Transport
and Turbulent Diffusion", Combustion Science and Technology, 165, pp. 175-195, 2001.
- Lipatnikov, A.N. and Chomiak, J. "Transient and Geometrical Effects in Expanding Turbulent Flames",
Combustion Science and Technology, 154, pp. 75-117, 2000.
- Lipatnikov, A.N. and Chomiak, J. "Modeling of Pressure and Non-Stationary Effects
in Spark Ignition Engine Combustion: A Comparison of Different Approaches",
SAE Transactions, Vol. 109, Section 3, Journal of Engines, 2000 (SAE Paper 2000-01-2034).
- Lipatnikov, A.N. and Chomiak, J. "Lewis Number Effects in Premixed Turbulent Combustion and
Highly Perturbed Laminar Flames", Combust. Sci. and Tech., 137, pp. 277-298, 1998.
- Lipatnikov, A.N. and Chomiak, J. "Randomness of Flame Kernel Development in Turbulent Gas Mixture",
SAE Transactions, Vol. 107, Section 3, Journal of Engines, 1998 (SAE Paper 982617).
- Wallesten, J., Lipatnikov, A.N., and J. Nisbet "Turbulent Flame Speed Closure Model: Further Development and
Implementation for 3-D Simulation of Combustion in SI Engine",
SAE Transactions, Vol. 107, Section 3, Journal of Engines, 1998 (SAE Paper 982613).
- Lipatnikov, A.N. and Chomiak, J. "A Simple Model of Unsteady Turbulent Flame Propagation",
SAE Transactions, Vol. 106, Section 3, Journal of Engines, pp. 2441-2452, 1997 (SAE Paper 972993).
- Karpov, V.P., Lipatnikov A.N., and Wolanskii P. "Finding the Markstein Number Using the Measurements
of Expanding Spherical Laminar Flames", Combustion and Flame, 109, N3, pp.436-448, 1997.
- Karpov, V.P and Lipatnikov A.N. "Numerical Simulations of Thermodiffusional Phenomena in
Highly Curved Unsteady Laminar Flames", Chemical Physics Reports, 16, N12, pp. 82-96, 1997.
- Karpov, V.P., Lipatnikov A.N., and Zimont, V.L. "A Test of an Engineering
Model of Premixed Turbulent Combustion", Proceedings of the Combustion Institute, 26, pp. 249-257, 1996.
- Karpov, V.P., Lipatnikov A.N., and Zimont, V.L. "Flame Curvature as a Determinant of Preferential
Diffusion Effects in Premixed Turbulent Combustion",
{\em Advances in Combustion Science: In Honor Ya.B.Zel'dovich} (Eds. by W.A. Sirignano,
A.G. Merzhanov, and L. De Luca),
{\em Progress in Astronautics and Aeronautics,}
Vol. 173, Chapter 14, pp. 235-250, 1996
- Lipatnikov A.N. "Some Issues of Using Markstein Number for
Modeling Premixed Turbulent Combustion", Combust. Sci. and Tech.,
119, N1-6, pp. 131-154, 1996
- Betev, A.S., Karpov V.P., Lipatnikov A.N., and Vardosanidze Z.P.
"Hydrogen Combustion in Engines and Preferential Diffusion Effects
in Laminar and Turbulent Flames", Archivum Combustionis, 15,
N3-4, pp. 199-227, 1995
- Zimont V.L. and Lipatnikov A.N. "A Numerical Model of Premixed
Turbulent Combustion of Gases", Chemical Physics Reports, 14, N7, pp. 993-1025, 1995
- Karpov V.P. and Lipatnikov A.N. "An Effect of Molecular Thermal Conductivity and
Diffusion on Premixed Combustion", Doklady Physical Chemistry,
341, N4-6, pp. 484-486, 1995
- Karpov V.P., Lipatnikov A.N., and Zimont V.L. "A model of
premixed turbulent combustion and its validation", Archivum
Combustionis, 14, pp. 125-141, 1994.
- Zimont V.L. and Lipatnikov A.N. "To computations of the heat release rate in turbulent flames",
Doklady Physical Chemistry, 332, pp. 592-594, 1993.
- Lipatnikov A.N. "Numerical Modelling of Nitric Oxide Formation
in Premixed Turbulent Flames", Combust., Explosions and Shock Waves, 1993, 29, N3
- Lipatnikov A.N. "Gas Mixture Autoignition before Flame Front
at Various Turbulence Intensities in Combustion Chamber",
Khimicheskaya Fizika, 11, pp. 1665-1676, 1992 (in Russian)
- Frolov S.M., Gelfand B.E., and Lipatnikov A.N. "Knock onset in
internal combustion engines", Archivum combustionis, 11,
pp. 183-194, 1991.
- Lipatnikov A.N. "Acceleration of gas mixture autoignition as
affected by turbulent diffusion", Khimicheskaya Fizika,
10, pp. 989-995, 1991 (in Russian).
- Lipatnikov A.N., Nazarov I.P., and Prostov V.N. "Taking
account of heat losses in modeling the turbulent combustion of a prelimiarily mixed mixture",
Combustion, Explosions, and Shock Waves, 24, pp. 290-292, 1988.
- Lipatnikov A.N., Nazarov I.P., and Prostov V.N. "Nitrogen oxide
formation in a flame at slight deviations from equilibrium",
Combustion, Explosions, and Shock Waves, 24, pp. 407-409, 1988.
Email: lipatn@chalmers.se Dept. of Thermo & Fluid Dynamics
Phone: +46-31-772 1386 (w) Chalmers University of Technology
S-412 96 Gothenburg, SWEDEN
Fax: +46-31-180 976