References in zbMATH (referenced in 66 articles , 1 standard article )

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  1. Kbiri Alaoui, Mohammed; Alharbi, F. M.; Zaland, Shamsullah: Novel analysis of fuzzy physical models by generalized fractional fuzzy operators (2022)
  2. Balashov, V. A.: Dissipative spatial discretization of a phase field model of multiphase multicomponent isothermal fluid flow (2021)
  3. Balashov, Vladislav: A regularized isothermal phase-field model of two-phase solid-fluid mixture and its spatial dissipative discretization equations (2021)
  4. Balashov, Vladislav; Zlotnik, Alexander: On a new spatial discretization for a regularized 3D compressible isothermal Navier-Stokes-Cahn-Hilliard system of equations with boundary conditions (2021)
  5. Golovin, D. V.: Numerical simulation of sound pressure for calibration system of \textitLStype measurement microphones (2021)
  6. Ivanov, A. V.: Computer complex for modelling of sea currents using regularized shallow water equations (2021)
  7. Lomonosov, T. A.: Application of the homomorphism theorem for rings to linearization of systems of partial differential equations (2021)
  8. Ryazanov, D. A.: About the quasihydrodynamic approach for simulation of internal wave attractors (2021)
  9. Shirokov, I. A.: Mesh construction algorithm based on TetGen for modeling the external flow around an axisymmetric model (2021)
  10. Zlotnik, A. A.; Chetverushkin, B. N.: Spectral stability conditions for an explicit three-level finite-difference scheme for a multidimensional transport equation with perturbations (2021)
  11. Zlotnik, A. A.; Lomonosov, T. A.: (L^2)-dissipativity of finite-difference schemes for 1D regularized barotropic gas dynamics equations at small Mach numbers (2021)
  12. Balashov, V. A.; Savenkov, E. B.: Thermodynamically consistent spatial discretization of the one-dimensional regularized system of the Navier-Stokes-Cahn-Hilliard equations (2020)
  13. Balashov, Vladislav; Zlotnik, Alexander: An energy dissipative semi-discrete finite-difference method on staggered meshes for the 3D compressible isothermal Navier-Stokes-Cahn-Hilliard equations (2020)
  14. Elizarova, T. G.; Ivanov, A. V.: Numerical modeling of passive scalar transport in shallow water based on the quasi-gasdynamic approach (2020)
  15. Golovchenko, E. N.; Yakobovskiĭ, M. V.; Balashov, V. A.; Savenkov, E. B.: Comparison of domain partitioning algorithms in the problem of direct flow simulation within rock samples at pore scale (2020)
  16. Lomonosov, T. A.: (L^2)-dissipativity criteria for linearized explicit finite difference schemes for regularization of one-dimensional gas dynamics equations (2020)
  17. Menshov, I. S.; Zhang, C.: Interface capturing method based on the Cahn-Hilliard equation for two-phase flows (2020)
  18. Zlotnik, A. A.; Lomonosov, T. A.: On (L^2)-dissipativity of a linearized explicit finite-difference scheme with quasi-gasdynamic regularization for the barotropic gas dynamics system of equations (2020)
  19. Zlotnik, Alexander: On enlarged sufficient conditions for (L^2)-dissipativity of linearized explicit schemes with regularization for 1D gas dynamics systems of equations (2020)
  20. Zlotnik, Alexander; Lomonosov, Timofey: (L^2)-dissipativity of the linearized explicit finite-difference scheme with a kinetic regularization for 2D and 3D gas dynamics system of equations (2020)

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