Savvatimskiy Aleksandr Ivanovich

Publications in Math-Net.Ru

1. Влияние повышенного давления на электросопротивление диборида циркония в твердой и жидкой фазах
   
   TVT, 63:1 (2025),  47–51
2. Электросопротивление жидкого гафния при температурах до $5000$ К при низких и повышенных давлениях
   
   TVT, 62:3 (2024),  358–362
3. Study of the properties of the ultra-high-temperature ceramic $\rm HfC_{0.51}\rm N_{0.32}$ in the temperature range $2500$–$5500$ K
   
   TVT, 62:2 (2024),  207–214
4. Thermodynamic properties of zirconium nitride in the condensed state
   
   UFN, 194:10 (2024),  1082–1094
5. Electrical resistance of liquid carbon $($up to $9000$ K$)$ and liquid gadolinium $($up to $6000$ K$)$ at elevated pressure and high temperatures
   
   TVT, 61:5 (2023),  685–692
6. Thermophysical properties of high-entropy carbide $(\rm HfTaTiNbZr)\rm C$ at temperatures of $2500$–$5500$ K
   
   TVT, 60:5 (2022),  672–675
7. Physical properties of refractory carbides of metals of groups IV and V of the Mendeleev periodic table during rapid heating by an electric current pulse
   
   UFN, 192:6 (2022),  642–662
8. Specific heat and electrical resistance of metals $\rm Ta$ and $\rm W$ from the melting point to $7000$ K under pulsed current heating
   
   TVT, 59:5 (2021),  686–692
9. Resistivity of refractory carbides $(\rm ZrC$, $\rm HfC$, and $\rm TaC + \rm HfC)$ in the solid and liquid states
   
   TVT, 58:6 (2020),  865–871
10. Specific heat of liquid zirconium carbide $\rm ZrC_{0.95}$ at temperatures up to $5000$ K
    
    TVT, 58:5 (2020),  749–757
11. Electrical resistivity of liquid gadolinium $($with carbon content of $29$ at $\%)$ at temperatures of $2000$–$4250$ K
    
    TVT, 58:1 (2020),  148–151
12. Investigation of the physical properties of carbon under high temperatures (experimental studies)
    
    UFN, 190:10 (2020),  1085–1108
13. Electrical resistance of the most refractory carbide $\rm Ta_{0.8}\rm Hf_{0.2}\rm C$ in the solid and liquid states $(2000$–$5000$ K$)$
    
    TVT, 57:1 (2019),  140–142
14. Specific heat of liquid iron from the melting point to the boiling point
    
    TVT, 56:6 (2018),  953–955
15. Measuring the specific heat of conducting substances in conditions of microsecond heating with a current pulse
    
    TVT, 56:5 (2018),  704–710
16. Thermophysical properties of multicomponent nickel-chromium alloy VSDP-3 upon melting and in the liquid phase
    
    TVT, 55:5 (2017),  846–849
17. Pecularities of high-temperature properties of HAPG graphite within the melting region
    
    TVT, 54:4 (2016),  536–539
18. Investigation of the high-temperature properties of zirconium nitride by impulse current heating method
    
    TVT, 53:3 (2015),  478–480
19. The electrical resistivity of liquid carbon under rapid heating of dense isotropic graphite in different media
    
    TVT, 48:2 (2010),  210–216
20. The density of liquid hafnium from the melting point to the boiling point
    
    TVT, 45:2 (2007),  187–192
21. Heat capacity of liquid hafnium from the melting point to the boiling point at atmospheric pressure
    
    TVT, 43:1 (2005),  39–44
22. Melting point of graphite and liquid carbon (Concerning the paper 'Experimental investigation of the thermal properties of carbon at high temperatures and moderate pressures' by E.I. Asinovskii, A.V. Kirillin, and A.V. Kostanovskii)
    
    UFN, 173:12 (2003),  1371–1379
23. Specific heat capacity of liquid zirconium up to $4100$ K
    
    TVT, 39:5 (2001),  712–719
24. Temperature dependence of the density and electrical resistivity of liquid zirconium up to $4100$ K
    
    TVT, 39:4 (2001),  566–572
25. Zirconium temperature measurements from the melting point to $4100$ K involving the use of blackbody models in the liquid state
    
    TVT, 39:3 (2001),  518–523
26. Electrical resistivity of liquid carbon
    
    TVT, 36:5 (1998),  725–731
27. Properties of solid and liquid zirconium
    
    TVT, 29:5 (1991),  883–886
28. Electrical resistivity and enthalpy of nickel and its alloys in the solid and liquid states
    
    TVT, 28:5 (1990),  914–923
29. Electrical-resistivity of rhenium in the solid and liquid states in relation to its enthalpy and heat of fusion
    
    TVT, 26:3 (1988),  492–500
30. Features of light radiation of metals near the melting-point with rapid impulsive heating
    
    TVT, 25:5 (1987),  912–918
31. Electrical-resistivity of graphite in a broad region of the condensed state
    
    TVT, 24:5 (1986),  892–899
32. ELECTRIC METAL EXPLOSION IN EXPERIMENTS FOR DEVELOPING SUPERSTRONG MAGNETIC-FIELDS
    
    Zhurnal Tekhnicheskoi Fiziki, 54:9 (1984),  1794–1796
33. Metals during rapid heating by dense currents
    
    UFN, 144:2 (1984),  215–250
34. Электросопротивление жидких металлов $(\mathrm{Mo},\mathrm{Cu},\mathrm{Al})$ при импульсном нагревании в ограниченном объеме
    
    TVT, 21:2 (1983),  390–392
35. Features of the electrical-resistivity of liquid tungsten under conditions of restricted volume and of free expansion
    
    TVT, 20:6 (1982),  1093–1097
36. “Energy anomalies” in the electrical explosion of conductors
    
    TVT, 19:6 (1981),  1184–1191
37. Specific-heat of solid and liquid niobium up to $5000$-degrees-K
    
    TVT, 19:5 (1981),  954–957
38. Расширение жидкого вольфрама при быстром нагревании электрическим током
    
    TVT, 16:1 (1978),  67–71
39. Specific heat of refractory metals close to the melting point, measured in the course of rapid heating
    
    TVT, 14:2 (1976),  285–289
40. Теплота плавления и электропроводность ниобия и родия в точке плавления
    
    TVT, 11:6 (1973),  1182–1187
41. Measurement of latent heats of fusion for refractory metals
    
    TVT, 9:3 (1971),  635–638
42. Disappearance of the electrical conductivity of a metal due to intense heating by high-density current
    
    TVT, 8:3 (1970),  524–531
43. Продукты электрического взрыва вольфрама при токах $\sim10^{11}$ а/м$^2$
    
    TVT, 7:5 (1969),  1020–1021
44. Экспериментальное определение температуры плавления диборида гафния
    
    TVT,  0


45. Sergei Vladimirovich Lebedev (Obituary)
    
    UFN, 161:3 (1991),  181–183