539.12.04, 628.9

films, laser, carbon nanotubes. 

A new method of nanotubes causing on the surface of polytetrafluoroethylene (PTFE) films using a device for laser shock-plasma acceleration of finely dispersed materials was developed in this work,. The formed structures were investigated using scanning electron microscopy. The transmission spectra of the formed films were studied. Physical mechanisms during coating application and changes in transmission spectra are explained.

1. Bernholc J., Brenner D., Buongiorno Nardelli M., Meunier V., Roland C. Mechanical and electrical properties of nanotubes. Annual Review of Materials Science. 2002. 32. P. 347–375.
2. Maheswaran R., Shanmugavel B. P. A Critical Review of the Role of Carbon Nanotubes in the Progress of Next-Generation Electronic Applications. J. Electron. Mater. 2022. 51. Р. 2786–2800.
3. Jyoti J., Gupta T. K., Singh B. P., Sandhu M., Tripathi S. K. Recent advancement in three dimensional graphene-carbon nanotubes hybrid materials for energy storage and conversion applications. Journal of Energy Storage. 2022. 50.104235.
4. Lekawa-Raus A., Patmore J., Kurzepa L., Bulmer J., Koziol K. Electrical properties of carbon nanotube based fibers and their future use in electrical wiring. Advanced Functional Materials. 2014. 24 (24). P. 3661–3682.
5. Nag A., Mukhopadhyay S. C. Fabrication and implementation of carbon nanotubes for piezoresistive-sensing applications: A review. Journal of Science: Advanced Materials and Devices. 2022. 7 (1). 100416.
6. Sitkar, O., Kovalyuk, B., Mocharskyi V. Mathematical Modeling of The Nanotubes Implementation into A Solid-State Matrix Using A Powerful Laser. CEUR Workshop Proceedings,2022, 3309, pp. 160–164.
7. Mocharskyi V. S., Nikiforov Yu. M., Kovalyuk B. P. Patent 86399 Ukraine, IPC C23C 24/00. Device for laser shock-plasma acceleration of finely dispersed materials. №u201308851; statement 07/15/2013; published 25.12.2013, Bul. No. 24. 4 p.

1. Bernholc J., Brenner D., Buongiorno Nardelli M., Meunier V., Roland C. Mechanical and electrical properties of nanotubes. Annual Review of Materials Science. 2002. 32. P. 347–375.
2. Maheswaran R., Shanmugavel B. P. A Critical Review of the Role of Carbon Nanotubes in the Progress of Next-Generation Electronic Applications. J. Electron. Mater. 2022. 51. Р. 2786–2800.
3. Jyoti J., Gupta T. K., Singh B. P., Sandhu M., Tripathi S. K. Recent advancement in three dimensional graphene-carbon nanotubes hybrid materials for energy storage and conversion applications. Journal of Energy Storage. 2022. 50.104235.
4. Lekawa-Raus A., Patmore J., Kurzepa L., Bulmer J., Koziol K. Electrical properties of carbon nanotube based fibers and their future use in electrical wiring. Advanced Functional Materials. 2014. 24 (24). P. 3661–3682.
5. Nag A., Mukhopadhyay S. C. Fabrication and implementation of carbon nanotubes for piezoresistive-sensing applications: A review. Journal of Science: Advanced Materials and Devices. 2022. 7 (1). 100416.
6. Sitkar, O., Kovalyuk, B., Mocharskyi V. Mathematical Modeling of The Nanotubes Implementation into A Solid-State Matrix Using A Powerful Laser. CEUR Workshop Proceedings,2022, 3309, pp. 160–164.
7. Mocharskyi V. S., Nikiforov Yu. M., Kovalyuk B. P. Patent 86399 Ukraine, IPC C23C 24/00. Device for laser shock-plasma acceleration of finely dispersed materials. №u201308851; statement 07/15/2013; published 25.12.2013, Bul. No. 24. 4 p.