BOR KIRITILGAN (8,0)@(17,0) IKKI QAVATLI UGLERODLI NANOTRUBKANING ELEKTR VA ISSIQLIK XUSUSIYATLARI
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Ushbu tadqiqotda (8,0)@(17,0) xirallikka ega ikki qavatli uglerodli nanotrubka (IQUNT)larning elektr va issiqlik o‘tkazuvchanlik
xususiyatlariga bor (B) atomlari kiritilishining ta’siri o‘rganildi. Bor atomlari turli konsentratsiyalarda (ρ%) kiritilib, haroratning
o‘zgarishi sharoitida o‘tkazuvchanlik mexanizmlari tahlil qilindi. Kiritilgan atomlar va haroratning o‘zgarishi zaryad taqsimlanishi
va fonon tarqalishiga ta’sir etib, natijada IQUNTlarning elektr va issiqlik o‘tkazuvchanlik samaradorligi sezilarli darajada
modifikatsiyalanishi aniqlandi.
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characterization, and the application, Mater. Sci. Eng. B 268, 115095 (2021).
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therapy techniques, J. Organomet. Chem. 999, 122819 (2023).
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Nanotube at Different Temperatures: Mechanistic Insights from Molecular Dynamics Simulations, East European Journal of
Physics, 1, 361-365 (2024)
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atoms, UJP 23, 3 (2021).
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10, 3 (2024).
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applications, Mod. Electron. Mater. 8, 1 (2022).
12. Utkir Uljayev et al., Boron interaction with double-walled carbon nanotubes across temperature ranges, Mod. Electron.
Mater. 10(3), 145-152 (2025).
13. G. Chen et al., Chemically Doped Double-Walled Carbon Nanotubes: Cylindrical Molecular Capacitors, Phys. Rev. Lett. 90,
257403 (2003).
14. Y.-K. Kwon and P. Kim, Unusually High Thermal Conductivity in Carbon Nanotubes, in High Thermal Conductivity
Materials, edited by S. L. Shindé and J. S. Goela (Springer, New York, NY, 2006), pp. 227–265.
15. S. V. Sawant et al., Boron doped carbon nanotubes: Synthesis, characterization and emerging applications – A review, Chem.
Eng. J. 427, 131616 (2022).
16. M. M. S. Fakhrabadi, A. Allahverdizadeh, V. Norouzifard, and B. Dadashzadeh, Effects of boron doping on mechanical
properties and thermal conductivities of carbon nanotubes, Solid State Commun. 152, 1973 (2012).
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