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Rudyak Valerii Yakovlevich

Publications in Math-Net.Ru

  1. Rheology of nanofluids containing single-walled carbon nanotubes

    Prikl. Mekh. Tekh. Fiz., 66:5 (2025),  92–104
  2. Molecular dynamics study of nanofluids viscosity with carbon tubes

    Nanosystems: Physics, Chemistry, Mathematics, 15:1 (2024),  37–45
  3. A computational study of cuttings transport in a horizontal well with an oil-based drilling fluid modified by multiwalled carbon nanotubes

    Sib. Zh. Ind. Mat., 27:3 (2024),  57–73
  4. Stochastic modeling the transport coefficients of liquids

    Dokl. RAN. Math. Inf. Proc. Upr., 512 (2023),  27–32
  5. Modeling the rarefied gas thermal conductivity in nanochannels

    Nanosystems: Physics, Chemistry, Mathematics, 14:2 (2023),  186–194
  6. Molecular dynamics modeling rheology of nanofluids

    Pisma v Zhurnal Tekhnicheskoi Fiziki, 49:19 (2023),  3–6
  7. Viscoelastic properties of nanofluids with carbon tubes

    Pisma v Zhurnal Tekhnicheskoi Fiziki, 48:14 (2022),  3–6
  8. Measurement of the thermal conductivity and heat transfer coefficient of nanofluids with single-walled nanotubes

    TVT, 60:5 (2022),  692–700
  9. On the anisotropy of gas transfer processes in nano- and microchannels

    Vestnik of Saint Petersburg University. Mathematics. Mechanics. Astronomy, 9:1 (2022),  152–163
  10. Mechanism of gas molecule transport through erythrocytes' membranes by kinks-solitons

    Nanosystems: Physics, Chemistry, Mathematics, 12:1 (2021),  22–31
  11. Experimental study of the influence of nanoparticles on evaporation of fluids

    Zhurnal Tekhnicheskoi Fiziki, 90:1 (2020),  33–41
  12. Stochastic molecular modeling the transport coefficients of rarefied gas and gas nanosuspensions

    Nanosystems: Physics, Chemistry, Mathematics, 11:3 (2020),  285–293
  13. Viscosity of gases in nanochannels

    Pisma v Zhurnal Tekhnicheskoi Fiziki, 46:20 (2020),  51–54
  14. The electric conductivity of nanofluids with metal particles

    Pisma v Zhurnal Tekhnicheskoi Fiziki, 45:9 (2019),  36–39
  15. Simulation modeling of the transport coefficients for rarefied gases and gas nanosuspensions

    Vestn. Tomsk. Gos. Univ. Mat. Mekh., 2019, no. 59,  105–117
  16. Molecular dynamics simulation of fluid viscosity in nanochannels

    Nanosystems: Physics, Chemistry, Mathematics, 9:3 (2018),  349–355
  17. Simulation of the thermal conductivity of a nanofluid with small particles by molecular dynamics methods

    Zhurnal Tekhnicheskoi Fiziki, 87:10 (2017),  1450–1458
  18. Stochastic simulation of rarefied gas transport coefficients

    Mat. Model., 29:3 (2017),  113–122
  19. On stability of plane and cylindrical Poiseuille flows of nanofluids

    Prikl. Mekh. Tekh. Fiz., 58:6 (2017),  69–77
  20. Thermal properties of nanofluids and their similarity criteria

    Pisma v Zhurnal Tekhnicheskoi Fiziki, 42:24 (2016),  9–16
  21. Simulation of the nanofluid viscosity coefficient by the molecular dynamics method

    Zhurnal Tekhnicheskoi Fiziki, 85:6 (2015),  9–16
  22. Statistical mechanics of transport processes of fluids under confined conditions

    Nanosystems: Physics, Chemistry, Mathematics, 6:3 (2015),  366–377
  23. The influence of the size and material of nanoparticles and the heater size on the critical heat flux density in boiling nanofluids

    Pisma v Zhurnal Tekhnicheskoi Fiziki, 41:18 (2015),  53–59
  24. Measurement of the heat transfer coefficient of a nanofluid based on water and copper oxide particles in a cylindrical channel

    TVT, 53:2 (2015),  256–263
  25. A model of averaged molecular viscosity for turbulent flow of non-Newtonian fluids

    J. Sib. Fed. Univ. Math. Phys., 7:1 (2014),  46–57
  26. Measuring of critical density of heat flow during boiling of nanoliquids on a cylindrical heater

    Pisma v Zhurnal Tekhnicheskoi Fiziki, 40:13 (2014),  44–51
  27. Measuring the heat-transfer coefficient of nanofluid based on copper oxide in a cylindrical channel

    Pisma v Zhurnal Tekhnicheskoi Fiziki, 40:5 (2014),  34–42
  28. Molecular dynamics modeling of nano-fluid separation in nanomembranes

    Vestn. Tomsk. Gos. Univ. Mat. Mekh., 2014, no. 4(30),  88–94
  29. On the dependence of the viscosity coefficient of nanofluids on particle size and temperature

    Pisma v Zhurnal Tekhnicheskoi Fiziki, 39:17 (2013),  53–60
  30. An algorithm for joint modeling of filtration and geomechanical processes in the well bore zone

    Sib. Zh. Ind. Mat., 15:1 (2012),  53–65
  31. Self-diffusion of fluid molecules in nanochannels

    Vestn. Tomsk. Gos. Univ. Mat. Mekh., 2012, no. 2(18),  63–66
  32. Simulation of flows in nanochannels by the molecular dynamics method

    Nanosystems: Physics, Chemistry, Mathematics, 2:4 (2011),  100–112
  33. On optimization of mixing process of liquids in microchannels

    J. Sib. Fed. Univ. Math. Phys., 3:2 (2010),  146–156
  34. On thermal diffusion of nanoparticles in gases

    Zhurnal Tekhnicheskoi Fiziki, 80:8 (2010),  49–52
  35. Modeling of transition coefficients of nanofluids

    Nanosystems: Physics, Chemistry, Mathematics, 1:1 (2010),  156–177
  36. On the thermal conductivity of nanofluids

    Pisma v Zhurnal Tekhnicheskoi Fiziki, 36:14 (2010),  49–54
  37. A numerical algorithm for modeling laminar flows in an annular channel with eccentricity

    Sib. Zh. Ind. Mat., 13:4 (2010),  3–14
  38. Numerical Simulation of Working Process of Viscosity Turning Fork Sensor

    J. Sib. Fed. Univ. Math. Phys., 2:4 (2009),  456–468
  39. The simulation of transport processes using the method of molecular dynamics. Self-diffusion coefficient

    TVT, 46:1 (2008),  35–44
  40. Kinetic theory in modern aerohydrodynamics

    Sib. Zh. Ind. Mat., 8:3 (2005),  120–148
  41. The theory of equilibrium fluctuations of thermodynamic quantities in open systems with a small number of particles

    TVT, 41:2 (2003),  237–246
  42. Simulation of instability of a swirling flooded spout induced by a vortex flow

    Sib. Zh. Ind. Mat., 5:4 (2002),  139–149
  43. Equations of the multifluid hydrodynamics for heterogeneous systems with rotatory degrees of freedom

    Sib. Zh. Ind. Mat., 5:1 (2002),  145–156
  44. Diffusion of nanoparticles and macromolecules in dense gases and liquids

    TVT, 39:2 (2001),  283–291
  45. On a kinetic-hydrodynamical model for describing gas mixtures and suspensions

    Sib. Zh. Ind. Mat., 2:2 (1999),  168–175
  46. Nonlocal constitutive relations, hydrodynamic fluctuations, and classical models of hydrodynamics

    Sib. Zh. Ind. Mat., 1:1 (1998),  164–173
  47. Equations of the multifluid hydrodynamics

    Mat. Model., 8:6 (1996),  33–37
  48. The stability of Poiseuille fluid of a two-phase fluid with a nonuniform particle distribution

    Prikl. Mekh. Tekh. Fiz., 37:1 (1996),  95–105
  49. The basic kinetic equation and the method of direct statistical modelling

    Mat. Model., 1:7 (1989),  93–99
  50. Transport-coefficients for a nonideal gas

    TVT, 27:4 (1989),  697–701
  51. On the development of the method of vortex particles as applied to the description of detached flows

    Zh. Vychisl. Mat. Mat. Fiz., 29:6 (1989),  878–887
  52. KINETIC-EQUATIONS OF THE IMPERFECT GAS WITH REAL INTERACTION POTENTIALS

    Zhurnal Tekhnicheskoi Fiziki, 57:8 (1987),  1466–1475
  53. Construction of discrete vortex models of flows of an ideal incompressible fluid

    Zh. Vychisl. Mat. Mat. Fiz., 26:1 (1986),  103–113
  54. Allowance for intermolecular forces of attraction in the derivation of kinetic equations

    TMF, 64:2 (1985),  277–286
  55. Derivation of a kinetic-equation of the Enskog type for a dense gas

    TVT, 23:2 (1985),  268–272
  56. Kinetic equation of a moderately dense gas

    Dokl. Akad. Nauk SSSR, 264:6 (1982),  1336–1339
  57. On a hyperbolic modification of the Burgers equation

    Dokl. Akad. Nauk SSSR, 255:4 (1980),  801–804
  58. Derivation of equations of motion of a slightly rarefied gas around highly heated bodies from Boltzmann's equation

    Prikl. Mekh. Tekh. Fiz., 14:5 (1973),  52–56

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