• RahnamayBahambary K, Kavian-Nezhad MR, Komrakova A, Fleck BA (2024) A numerical study of bio-inspired wingtip modifications of modern wind turbines. Energy. 292: 130561. READ
  • Singh K, Komrakova A. (2024) Comparison of forcing schemes to sustain homogeneous isotropic turbulence. Phys. Fluids. 36: 015126. READ
  • Kothari Y, Komrakova A. (2024) Free-energy-based lattice Boltzmann model for emulsions with soluble surfactant. Chem. Eng. Sci. 285: 119609. READ
  • Mao K, Toussaint G, Komrakova A, Hogan J. (2024) High-velocity impact failure modeling of Armox 500T steel: model validation and application to structural design. Int. J. Impact Eng. 183: 104790


  • Chen Z, Tsai P, Komrakova A. (2023) Dynamics of surfactant-laden drops in shear flow by lattice Boltzmann method. Phys. Fluids. 35: 122119. READ
  • Safari-Alamuti F, Bhalerao A, Komrakova A, Machado MB, Kresta SK. (2023) Mixing energy as a scaling variable for liquid drawdown in stirred tanks. Chem. Eng. Res. Des. 196: 319-331


  • Chen Z, Huang F, Tsai A, Komrakova A. (2022) Numerical study of microfluidic emulsion dynamics under the influence of heterogeneous surface wettability. Int. J. Multiphase Flow. 147: 103863


  • Razavi F, Komrakova A, Lange CF. (2021) CFD-DEM simulation of sand-retention mechanisms in slurry flow. Energies. 14: 3797 1-23
  • Huang F, Chen Z, Li Z, Gao Z, Derksen JJ, Komrakova A. (2021) Numerical study of drop behavior in a pore space. Chem. Eng. Sci. 233: 116351 1-17


  • Maluta F, Kresta SM, Komrakova A. (2020) Mechanistic model of amine hydrochloride salts precipitation in a confined impinging jet reactor. Ind. Eng. Chem. Res. 59: 20877-20891.
  • Liang W, Wang D, Cai Z, Li Z, Huang X, Gao Z, Derksen J, Komrakova A. (2020) Deformation and breakup of single drop in laminar and transitional jet flows. Chem. Eng. J. 386: 121812-1-13.


  • Zhong C, Komrakova A. (2019) Liquid drop breakup in homogeneous isotropic turbulence. Int. J. Numer. Methods Heat Fluid Flow 29: 2407-2433.
  • Komrakova A. (2019) Single drop breakup in turbulent flow. Can. J. Chem. Eng. 97: 2727-2739.
  • Shi H, Komrakova A, Nikrityuk P. (2019) Fluidized beds modeling: Validation of 2D and 3D simulations against experiments. Powder Technol 343: 479-494.
  • Derksen J, Komrakova A. (2019) Multiscale simulations of sliding droplets. Acta Mech 230: 657-666.


  • Komrakova A, Liu Z, Machado M, Kresta S. (2017) Development of a zone flow model for the confined impeller stirred tank (CIST) based on mean velocity and turbulence measurements. Chem. Eng. Res. Des. 125: 511-522.
  • Maluta F, Eaglesham A, Jones D, Komrakova A, Kresta S. (2017) A novel factorial design search to determine realizable constant sets for a multi-mechanism model of mixing sensitive precipitation. Comput. Chem. Eng. 106: 322-338.


  • Komrakova A, Eskin D, Derksen J. (2015) Numerical study of turbulent liquid-liquid dispersions. AIChE J. 61: 2618-2633.
  • Komrakova A, Shardt O, Eskin D, Derksen J. (2015) Effects of dispersed phase viscosity on drop deformation and breakup in inertial shear flow. Chem. Eng. Sci. 126: 150-159.


  • Komrakova A, Shardt O, Eskin D, Derksen J. (2014) Lattice Boltzmann simulations of drop deformation and breakup in shear flow. Int. J. Multiphase Flow, 59: 24-48.


  • Komrakova A, Eskin D, Derksen J. (2013) Lattice Boltzmann simulations of a single n-butanol drop rising in water. Phys. Fluids 25: 042102, 1-29.


  • Belova O, Baldygin A, Komrakova A, Zhyravlev O, Skibin A, Shishov A. (2011) The application of CFD methods for hydrodynamic characteristics of throttle determination. Bulletin of Bauman Moscow State Technical University. “Mechanical Engineering”. Special edition “Vacuum, compressor technologies and air units”, 167-175.


  • Grishin Y, Kozlov N, Komrakova A. (2009) Numerical simulations of thermo-baric stresses experienced by transiently heated quartz particle. Bulletin of Bauman Moscow State Technical University. October – December. “Mechanical Engineering” 4 (77): 3-18.