Пошуковий запит: (<.>U=Ж364.2$<.>) |
Загальна кількість знайдених документів : 355
Представлено документи з 1 до 20
|
| |
1. |
Akash Ahlawat 3D FDM printable polymer composites and polymer nanocomposites: state of the art // J. of Nano- and Electronic Physics. - 2021. - 13, № 2.
|
2. |
Valinejad M. A comparative study of the oxidation and wet chemical methods for uncapping the multi-walled carbon nanotubes // Журн. нано- та електрон. фізики. - 2013. - 5, № 1.
|
3. |
Mykhailenko O. V. A molecular container for anti-aromatic system based on double-walled carbon nanotube: in silico study // Наносистеми, наноматеріали, нанотехнології : зб. наук. пр. - 2018. - 16, вип. 1.
|
4. |
Musabekov K. A research of colloidal silver immobilization in bionanocomposites of natural polymers and montmorillonite // Вост.-Европ. журн. передовых технологий. - 2020. - № 6/6.
|
5. |
Kotok V. A study of the possibility of conducting selective laser processing of thin composite electrochromic Ni(OH)2-PVA films // Вост.-Европ. журн. передовых технологий. - 2021. - № 1/12.
|
6. |
Закарян Д. А. Ab initio вычисление коэффициентов термического расширения боридов MeB2 (Me - Ti, Zr), LaB6 и эвтектических композитов LaB6 - MeB2. — 2012 // Порошковая металлургия.
|
7. |
Filonenko S. F. Acoustic emission at properties change of composite destructed by von Mises criterion // Electronics and Control Systems. - 2021. - № 1.
|
8. |
Andrzej D. Analysis of strength criteria in the design of products from composite materials // Вісн. КПІ. Сер. Приладобудування. - 2021. - Вип. 61.
|
9. |
Lepikh Ya. I. Annealing temperature modes influence on properties of heterophase nanocomposites based on ceramics "glass - Ag-Pd" systems // Functional Materials. - 2014. - 21, № 3.
|
10. |
Volkova E. I. Carbon nanotubes and their properties in the course on nanomaterials for engineering students // Наук. пр. Донец. нац. техн. ун-ту. Сер. Хімія і хім. технологія. - 2013. - Вип. 1.
|
11. |
Parita Basnet Chemical approach based ZnS - ZnO nanocomposite synthesis and assessment of their structural, morphological and photocatalytic properties // J. of Nano- and Electronic Physics. - 2021. - 13, № 1.
|
12. | Clusters and nanostructured materials (CNM-5) : program & materials of the meeting, International meeting, Uzhgorod Vodograj Ukraine, 22 - 26 October 2018. — Uzhgorod: PE Sabov A. M., 2018
|
13. |
Boroznina N. P. Comparative analysis of sensor activity of carbon nanotubes modified with functional groups // Журн. нано- та електрон. фізики. - 2017. - 9, № 3.
|
14. |
Balog R. Comparative study of Ni(II) and Cu(II) adsorption by As-prepared and oxidized multi-walled N-doped carbon nanotubes // Наносистеми, наноматеріали, нанотехнології : зб. наук. пр. - 2020. - 18, вип. 2.
|
15. |
Javanbakht T. Comparative study of physicochemical properties and antibiofilm activity of graphene oxide nanoribbons // J. of Eng. Sciences. - 2020. - 7, № 1.
|
16. |
Kirilyuk A. P. Complex-dynamical nanobiotechnology paradigm and intrinsically creative evolution // Наносистеми, наноматеріали, нанотехнології : зб. наук. пр. - 2016. - 14, вип. 1.
|
17. |
Kurnosov N. V. Composite films of graphene oxide with semiconducting carbon nanotubes: Raman spectroscopy characterization // Фізика низ. температур. - 2021. - 47, N 3 (спец. вип.).
|
18. |
Labunov V. A. Composite nanostructure of vertically aligned carbon nanotube array and planar graphite layer obtained by the injection CVD method // Semiconductor Physics, Quantum Electronics and Optoelectronics. - 2010. - 13, № 2.
|
19. |
Kondryuk D. V. Concentration-size dependences for the electron energy in AlxGa1-xAs/GaAs/AlxGa1-xAs nanofilms // Semiconductor Physics, Quantum Electronics and Optoelectronics. - 2014. - 17, № 2.
|
20. |
Aram S. Shirinyan Concept of size-dependent atomic interaction energies for solid nanomaterials: thermodynamic and diffusion aspects // Металлофизика и новейшие технологии. - 2015. - 37, № 4.
|
| |