Pronkin Alexandr Arturovich

Publications in Math-Net.Ru

1. О корректности использования закона Ома и закона Фурье для описания контактного электрического сопротивления
   
   TVT, 63:1 (2025),  52–56
2. Влияние температуры и силы тока на контактное электрическое сопротивление графита
   
   TVT, 62:3 (2024),  363–367
3. Temperature distribution in the area of the electrical contact surface of graphite
   
   TVT, 62:1 (2024),  143–146
4. Assessment of the thermal effect of femtosecond and millisecond laser pulses in microsurgery of mammalian embryos
   
   Kvantovaya Elektronika, 52:5 (2022),  482–490
5. Thermal effect in the contact resistance of graphite
   
   TVT, 60:6 (2022),  946–949
6. Contact electrical resistance of grade MPG-$7$ graphite at DC and AC current
   
   TVT, 60:5 (2022),  789–792
7. Electrical contact resistance of graphite
   
   TVT, 60:4 (2022),  519–523
8. Influence of heating temperature on the electrical resistivity of pyrolytic graphite
   
   TVT, 58:4 (2020),  732–734
9. Electrical resistivity of the $c$ surface of pyrolytic UPV-1 graphite in a temperature range of $2200$–$3200$ K
   
   TVT, 58:1 (2020),  141–143
10. Emittance properties of siliconized silicon carbide in the temperature range of $1400$–$2200$ K
    
    TVT, 57:2 (2019),  301–303
11. Thermal conductivity of silicicated silicon carbide at $1400$–$2200$ K
    
    TVT, 57:1 (2019),  137–139
12. Thermal expansion of zirconium carbide at $1200$–$2850$ K
    
    TVT, 56:6 (2018),  956–958
13. Electrical resistivity of silicated silicon carbide
    
    TVT, 56:5 (2018),  841–843
14. Graphite Surface Microhardening with Femtosecond Laser Pulses
    
    TVT, 56:4 (2018),  616–619
15. Relative elongation of silicicated silicon carbide at temperatures of $1150$–$2500$ K
    
    TVT, 56:2 (2018),  310–312
16. Relative lengthening of $\rm ZrO_2$ in the temperature range of $1200$–$2700$ K
    
    TVT, 55:6 (2017),  782–784
17. Investigation of stability of the relative elongation of GIP-4 graphite under cyclic thermal loads
    
    TVT, 54:1 (2016),  144–146
18. Absorption and width of the optical gap of $\alpha$-$\text{C}$ films obtained by magnetron sputtering
    
    TVT, 53:2 (2015),  312–314
19. Investigation of stability of specific elongation of graphite of $\text{DE}$-$24$ grade under cyclic heat loads
    
    TVT, 53:1 (2015),  54–57
20. Formation of a diamond-like carbon film by magnetron sputtering of a graphite target under radiation flux from a black-body model
    
    Pisma v Zhurnal Tekhnicheskoi Fiziki, 40:7 (2014),  35–41
21. Formation of a thin film containing $\alpha$-carbine in the magnetron sputtering of graphite targets and the impact of an external photoactivation source
    
    TVT, 51:5 (2013),  787–790
22. Preparation of diamond-like films in the process of magnetron sputtering of graphite target
    
    TVT, 47:1 (2009),  141–143