Velocity Effect in Synthesis of Noncircular Nanopores by Etching Tracks of Swift Heavy Ions in Olivine

Мұқаба

Дәйексөз келтіру

Толық мәтін

Ашық рұқсат Ашық рұқсат
Рұқсат жабық Рұқсат берілді
Рұқсат жабық Тек жазылушылар үшін

Аннотация

The velocity effect was studied in the synthesis of nanopores with a noncircular cross section by etching tracks of swift heavy ions in olivine. The developed atomistic model for the etching of olivine irradiated with swift heavy ions predicts the possibility of synthesizing nanopores with a noncircular cross section in it. The model consists of connected blocks that describe the sequential stages of track formation and etching. The TREKIS Monte Carlo model describes the initial electronic and lattice excitations in the nanoscale vicinity of the trajectory of an incident ion. These results are used as initial conditions for molecular dynamics simulation of structural changes along the ion trajectory. The obtained atomic coordinates after cooling of the structurally damaged area serve as the initial data for the original atomistic model of track etching in olivine. The results of the model application show that it is possible to control the cross section of these pores by changing the orientation of the crystal relative to the direction of irradiation. The presented simulation results for Xe ions demonstrate that the size of the resulting pores depends on the velocity of the incident ion, and not only on its linear energy loss.

Авторлар туралы

S. Gorbunov

Lebedev Physical Institute of the RAS

Хат алмасуға жауапты Автор.
Email: gorbunovsa@lebedev.ru
Ресей, Moscow

P. Babaev

Lebedev Physical Institute of the RAS

Email: gorbunovsa@lebedev.ru
Ресей, Moscow

A. Volkov

Lebedev Physical Institute of the RAS

Email: gorbunovsa@lebedev.ru
Ресей, Moscow

R. Voronkov

Lebedev Physical Institute of the RAS

Email: gorbunovsa@lebedev.ru
Ресей, Moscow

R. Rymzhanov

Joint Institute of Nuclear Researches

Email: gorbunovsa@lebedev.ru
Ресей, Dubna

Әдебиет тізімі

  1. Komarov F.F. // Physics-Uspekhi. 2017. V. 60. P. 435.
  2. Kozhina E.P., Bedin S.A., Nechaeva N.L., Podoyni-tsyn S.N., Tarakanov V.P., Andreev S.N., Grigoriev Y.V., Naumov A.V. // Appl. Sci. 2021. V. 11. P 1375. https://doi.org./10.3390/APP11041375
  3. Apel P. // Radiat. Meas. Pergamon. 2001. V. 34. № 1–6. P. 559. https://doi.org./10.1016/S1350-4487(01)00228-1
  4. Barth W., Bayer W., Dahl L., Groening L., Richter S., Yaramyshev S. // Nucl. Instrum. Methods Phys. Res. A. 2007. V. 577. № 1–2. P. 211. https://doi.org./10.1016/J.NIMA.2007.02.054
  5. Apel P.Y. // Radiat. Phys. Chem. 2019. V. 159. P. 25. https://doi.org/10.1016/j.radphyschem.2019.01.009
  6. Hadley A., Notthoff C., Mota-Santiago P., Hossain U.H., Kirby N., Toimil-Molares M.E., Trautmann C., Kluth P. // Nanotechnology. 2019. V. 30. № 27. P. 274001. https://doi.org./10.1088/1361-6528/ab10c8
  7. Bruschi L., Mistura G., Prasetyo L., Do D.D., Dipalo M., De Angelis F. // Langmuir. 2018. V. 34. № 1. P. 106. https://doi.org./10.1021/ACS.LANGMUIR.7B03695
  8. Wu K., Chen Z., Li X. // Chem. Eng. J. 2015. V. 281. P. 813. https://doi.org./10.1016/J.CEJ.2015.07.012
  9. Prakash S., Pinti M., Bellman K. // J. Micromechan. Microeng. 2012. V. 22. № 6. P. 067002. https://doi.org./10.1088/0960-1317/22/6/067002
  10. Patterson N., Adams D.P., Hodges V.C., Vasile M.J., Michael J.R., Kotula P.G. // Nanotechnology. 2008. V. 19. № 23. P. 235304. https://doi.org./10.1088/0957-4484/19/23/235304
  11. Lang M., Voss K., Neumann R., Al E. // GSI Sci. Rep. 2005. 2006. V. 3. P. 343.
  12. Alexeev V., Bagulya A., Chernyavsky M., Gippius A., Goncharova L., Gorbunov S., Gorshenkov M., Kalini-na G., Konovalova N., Liu J. et al. // Astrophys. J. 2016. V. 829. № 2. P. 120. https://doi.org./10.3847/0004-637x/829/2/120
  13. Bagulya A.V., Kashkarov L.L., Konovalova N.S., Okat’eva N.M., Polukhina N.G., Starkov N.I. // JETP Lett. 2013. V. 97. № 12. P. 708. https://doi.org./110.1134/S0021364013120047
  14. Rymzhanov R.A., Gorbunov S.A., Medvedev N., Volkov A.E. // Nucl. Instrum Methods Phys. Res. B. 2019. V. 440. P. 25. https://doi.org./10.1016/j.nimb.2018.11.034
  15. Medvedev N., Volkov A.E., Rymzhanov R., Akhmetov F., Gorbunov S., Voronkov R., Babaev P. // J. Appl. Phys. 2023. V. 133. № 10. P. 100701. https://doi.org./10.1063/5.0128774
  16. Medvedev N.A., Rymzhanov R.A., Volkov A.E. // J. Phys. D. 2015. V. 48. № 35. P. 355303. https://doi.org./10.1088/0022-3727/48/35/355303
  17. Thompson A.P., Aktulga H.M., Berger R., Bolintinea-nu D.S., Brown W.M., Crozier P.S., in’t Veld P.J., Kohlmeyer A., Moore S.G., Nguyen T.D., Shan R., Stevens M.J., Tranchida J., Trott C., Plimpton S.J. // Comput. Phys. Commun. 2022. V. 271. P. 108171. https://doi.org./10.1016/J.CPC.2021.108171
  18. Gorbunov S.A., Babaev P.A., Rymzhanov R.A., Volkov A.E., Voronkov R.A. // J. Phys. Chem. C. 2023. V. 127. № 10. P. 5090. https://doi.org./10.1021/acs.jpcc.2c07236
  19. Gulbekyan G., Gikal B., Kalagin I., Kazarinov N. // Phys. Part. Nucl. Lett. 2010. V. 7. № 7. P. 511. https://doi.org./10.1134/S1547477110070186
  20. Matsui M. // Geophys. Res. Lett. 1996. V. 23. № 4. P. 395. https://doi.org./10.1029/96GL00260
  21. Luce R.W., Bartlett R.W., Parks G.A. // Geochim. Cosmochim. Acta. 1972. V. 36. № 1. P. 35. https://doi.org./10.1016/0016-7037(72)90119-6
  22. Pokharel R., Gerrits R., Schuessler J.A., von Blancken-burg F. // Chem. Geol. 2019. V. 525. P. 18. https://doi.org./10.1016/J.CHEMGEO.2019.07.001

Қосымша файлдар

Қосымша файлдар
Әрекет
1. JATS XML
Жүктеу

© Russian Academy of Sciences, 2024