Bodryakov Vladimir Yur'evich

Publications in Math-Net.Ru

1. Pursuit problem with an arbitrary initial aiming angle
   
   Mat. Model., 35:11 (2023),  35–46
2. Isolation of the magnetic contribution to the thermal expansion of nickel at ferromagnetic transformation on the base of analysis of $\beta(C_p)$ correlation dependence
   
   TVT, 58:2 (2020),  232–237
3. Improved pixel estimates of measures of plane sets as methodological approach to introducing the concept of «area of a figure» in geometry course. Part 1
   
   Math. Ed., 2019, no. 4(92),  17–29
4. Joint study of temperature dependences of thermal expansion and heat capacity of solid beryllium
   
   TVT, 56:2 (2018),  185–192
5. Correlation between temperature dependences of thermal expansivity and heat capacity up to the melting point of tantalum
   
   TVT, 54:3 (2016),  336–342
6. Correlation analysis of the heat capacity and thermal expansion of solid mercury
   
   Fizika Tverdogo Tela, 57:6 (2015),  1240–1244
7. Correlation between the thermal expansion coefficient and heat capacity of an inert-gas single crystal: Krypton
   
   Zhurnal Tekhnicheskoi Fiziki, 85:3 (2015),  65–68
8. Correlation of temperature dependences of thermal expansion and the heat capacity of refractory metal up to the melting point: Tungsten
   
   TVT, 53:5 (2015),  676–682
9. On the correlation between thermal expansion coefficient and heat capacity of argon cryocrystals
   
   Fizika Tverdogo Tela, 56:11 (2014),  2279–2285
10. Correlation of temperature dependencies of the thermal expansion and heat capacity of refractory metal up to the melting point: Molybdenum
    
    TVT, 52:6 (2014),  863–869
11. Heat capacity and thermal expansion of cryocystalline xenon at elevated temperatures
    
    Zhurnal Tekhnicheskoi Fiziki, 83:5 (2013),  101–108
12. Heat capacity of solid tantalum: Self-consistent calculation
    
    TVT, 51:2 (2013),  233–242
13. The part played by magnetoelastic interaction in the forming of thermodynamic functions of ferromagnets: Second thermodynamic derivatives of thermodynamic potential
    
    TVT, 47:1 (2009),  37–48
14. The part played by magnetoelastic interaction in the forming of thermodynamic functions of ferromagnets: Thermodynamic potential and its first thermodynamic derivatives
    
    TVT, 46:4 (2008),  522–532
15. The Effect of Phonon Anharmonicity on the Thermodynamic Properties of Nonmetallic Solid
    
    TVT, 43:6 (2005),  860–869
16. The Magnetic Dependence of the Debye Temperature of a Ferromagnet
    
    TVT, 43:3 (2005),  396–400
17. Self-consistent thermodynamic description of a nonmetallic nonferromagnetic solid (using silicon as an example)
    
    TVT, 42:4 (2004),  563–571
18. Analysis of thermodynamic functions of silicon at high temperatures
    
    TVT, 38:5 (2000),  724–730
19. The mechanism of melting of polycomponent aluminum alloys
    
    TVT, 37:5 (1999),  720–724
20. Computation of thermodynamic functions during calorimetric investigations (Using aluminum as an example)
    
    TVT, 36:3 (1998),  519–521
21. Magnetoelastic properties and intemal friction of high purity gadolinium in the $4.2$–$350$ K range
    
    Fizika Tverdogo Tela, 33:7 (1991),  2233–2236


22. Improved pixel estimates of measures of plane sets as a approach to introducing the concept of «Area of a figure» in geometry course. Part 2
    
    Math. Ed., 2020, no. 1(93),  15–23
23. The history of hyperbolic functions research and some applications, finished
    
    Math. Ed., 2019, no. 1(89),  22–31
24. The history of hyperbolic functions research and some applications
    
    Math. Ed., 2018, no. 4(88),  18–29