Bazhenova Tat'yana Valerianovna

Publications in Math-Net.Ru

1. Effect of a granulated-material screen on the multiple reflection of a plane shock wave inside a closed volume
   
   TVT, 58:1 (2020),  144–147
2. Multiple shock wave reflections at an explosion in a closed volume with shielded walls
   
   TVT, 55:2 (2017),  324–326
3. Impact on blockage of an airflow containing solid particles
   
   TVT, 55:1 (2017),  158–160
4. Protecting shield influence on pressure decrease at shock wave interaction with the wall
   
   TVT, 54:6 (2016),  963–964
5. Effect of the expansion velocity of material of a sand protective screen on the attenuation of a shock wave reflected from this screen
   
   TVT, 54:5 (2016),  761–766
6. Shock wave effect on protective sand screens of different thicknesses
   
   TVT, 53:1 (2015),  145–147
7. Study of an interaction of a blast wave with a destructible screen made of a granular material
   
   TVT, 52:5 (2014),  739–745
8. Liquid drop ejection from a membrane driven by gas detonation products
   
   Pisma v Zhurnal Tekhnicheskoi Fiziki, 39:3 (2013),  49–55
9. Using of hydrogen-air mixture detonation in needle-free injection devices
   
   TVT, 51:1 (2013),  147–150
10. Attenuation of impact of the reflected shock wave upon an explosion inside a vessel with granular material walls
    
    TVT, 50:3 (2012),  476–479
11. The shock-wave mechanism of spontaneous ignition of hydrogen under conditions of sudden efflux from reservoir at high pressure
    
    TVT, 45:5 (2007),  733–740
12. An investigation of surface energy input to gas during initiation of a nanosecond distributed surface discharge
    
    TVT, 45:4 (2007),  580–587
13. Increasing the force with which a shock discharged from the acts on an obstacle by way of converting a normal pressure shock to a system of oblique shocks
    
    TVT, 42:6 (2004),  900–907
14. Use of gas detonation in a controlled frequency mode (review)
    
    Fizika Goreniya i Vzryva, 39:4 (2003),  3–21
15. Three-Dimensional Effects and the Interaction between an Obstacle and a Shock Wave Discharged from a Channel
    
    TVT, 40:2 (2002),  250–255
16. Flow expansion behind a shock wave discharged from a channel
    
    TVT, 39:1 (2001),  123–127
17. Investigation of the detonation of HN$_3$ near limits
    
    Fizika Goreniya i Vzryva, 21:1 (1985),  120–124
18. Calculating the electron-energy distribution relaxation in an expanding gas-flow
    
    TVT, 21:4 (1983),  666–672
19. Determination of Effective Colllsion Cross Sections of $\mathrm{H}_2\mathrm{O}$ Molecules with Electrons In a Plasma behind a Shock Front
    
    TVT, 18:5 (1980),  906–910
20. Влияние зависимости сечений соударений от скорости электронов на взаимодействие радиоволн с воздушной плазмой
    
    TVT, 17:5 (1979),  922–927
21. Изменение интенсивности ударной волны при огибании выпуклого угла (№ 859-76 Деп. от 22 III 1976)
    
    TVT, 14:2 (1976),  436
22. Течение релаксирующего газа, возникающее при выходе ударной волны в расширяющийся канал
    
    TVT, 11:6 (1973),  1203–1212
23. Исследование ионизационной релаксации за фронтом отраженной ударной волны в аргоне
    
    TVT, 9:4 (1971),  849–851
24. Flow parameters behind shock waves in carbon dioxide, nitrogen, and mixtures of these
    
    TVT, 9:3 (1971),  550–556
25. On the rate of the physico-chemical transformations of $\mathrm{CO}_2$ molecules behind a shock wave at 200–4000$^\circ$ К
    
    Dokl. Akad. Nauk SSSR, 154:2 (1964),  401–403
26. Measurement of the time in which the equilibrium concentration of electrons is established behind a shock wave in the air
    
    Dokl. Akad. Nauk SSSR, 151:3 (1963),  519–521
27. Evaluation of the relaxation time in the dissociation of carbon dioxide from experiments in a shock tube
    
    Dokl. Akad. Nauk SSSR, 146:3 (1962),  554–556


28. Shock wave diffraction from a square channel
    
    TVT, 35:2 (1997),  352