Magnetic nanoparticles produced by pulsed laser ablation of thin cobalt films in water

Cover Page

Cite item

Full Text

Open Access Open Access
Restricted Access Access granted
Restricted Access Subscription Access

Abstract

The possibility of synthesizing nanoparticles by pulsed laser ablation of thin cobalt films in water is shown. The average size of the formed nanoparticles varies in the range of 70–1020 nm depending on the thickness of the ablated film. At film thicknesses less than 35 nm, the size dispersion of the nanoparticles

About the authors

I. O. Dzhun

Lomonosov Moscow State University

Email: nesterovvy@my.msu.ru

Skobeltsyn Institute of Nuclear Physics

Russian Federation, Moscow, 119991

V. Y. Nesterov

Lomonosov Moscow State University; Moscow Institute of Physics and Technology

Author for correspondence.
Email: nesterovvy@my.msu.ru

Lomonosov Moscow State University, Faculty of Physics

Russian Federation, Moscow, 119991; Dolgoprudny, 141701

D. V. Shuleiko

Lomonosov Moscow State University

Email: nesterovvy@my.msu.ru

Faculty of Physics

Russian Federation, Moscow, 119991

S. V. Zabotnov

Lomonosov Moscow State University

Email: nesterovvy@my.msu.ru

Faculty of Physics

Russian Federation, Moscow, 119991

D. Е. Presnov

Lomonosov Moscow State University

Email: nesterovvy@my.msu.ru

Skobeltsyn Institute of Nuclear Physics

Russian Federation, Moscow, 119991

Yu. A. Alekhina

Lomonosov Moscow State University

Email: nesterovvy@my.msu.ru

Faculty of Physics

Russian Federation, Moscow, 119991

E. A. Konstantinova

Lomonosov Moscow State University

Email: nesterovvy@my.msu.ru

Faculty of Physics

Russian Federation, Moscow, 119991

N. S. Perov

Lomonosov Moscow State University

Email: nesterovvy@my.msu.ru

Faculty of Physics

Russian Federation, Moscow, 119991

N. G. Chechenin

Lomonosov Moscow State University

Email: nesterovvy@my.msu.ru

Skobeltsyn Institute of Nuclear Physics; Faculty of Physics

Russian Federation, Moscow, 119991

References

  1. Lu A.-H., Salabas E.L., Schüth F. // Angew. Chem. Int. Ed. 2007. V. 46. No. 8. P. 1222.
  2. Long N.V., Yang Y., Teranishi T. et al. // Mater. Des. 2015. V. 86. P. 797.
  3. Liu X.Y., Gao Y.Q., Yang G.W. // Nanoscale. 2016. V. 8. P. 4227.
  4. Alonso-Domínguez D.D., Alvarez-Serrano I.I., Pico M.P. // J. Alloys. Compounds. 2017. V. 695. P. 3239.
  5. Blakemore J.D., Gray H.B., Winkler J.R., Mueller A.M. // ACS Catalysis. 2013. V. 3. No. 11. P. 2497.
  6. Li L.H., Xiao J., Liu P., Yang G.W. // Sci. Reports. 2014. V. 5. Art. No. 9028.
  7. Kunitsyna E.I., Allayarov R.S., Koplak O.V. et al. // ACS Sensors. 2021. V. 6. No. 12. P. 4315.
  8. Abdulwahid F.S., Haider A.J., Al-Musawi S. // Nano Rev. 2022. V. 17. No 11. Art. No. 2230007.
  9. Papis E., Rossi F., M. Raspanti M. et al. // Toxic. Lett. 2009. V. 189. P. 253.
  10. Périgo E.A., Hemery G., Sandre O. et al. // Appl. Phys. Rev. 2015. V. 2. Art. No. 41302.
  11. Ichiyanagi Y., Yamada S. // Polyhedron. 2005. V. 24. P. 2813.
  12. Mehdaoui B., Meffre A., Carrey J. et al. // Adv. Funct. Mat. 2011. V. 21. Art. No. 4573.
  13. Usov N.A., Gubanova E.M., Wei Z.H. // J. Phys. Conf. Ser. 2020. V. 1439. Art. No. 012044.
  14. Мельников Г.Ю., Лепаловский В.Н., Сафронов А.П. и др. // ФТТ. 2023. Т. 65. № 7. С. 1100; Melnikov G. Yu, Lepalovskij V.N., Safronov A.P. et al. // Phys. Sol. St. 2023. V. 65. No. 7. P. 1100.
  15. Sánchez-López E., Gomes D., Esteruelas G. et al. // Nanomaterials. 2020. V. 10. Art. No. 292.
  16. Bose P., Bid S., Pradhan S.K. et al. // J. Alloys Compounds. 2002. V. 343. P. 192.
  17. Sun S., Murray C.B. // J. Appl. Phys. 1999. V. 85. P. 4325.
  18. Mathur S., Veith M., Sivakov V. et al. // Chem. Vap. Depos. 2002. V. 8. P. 277.
  19. Yin J.S., Wang Z.L. // Nanostruct. Mater. 1999. V. 10. P. 845.
  20. Becker J.A., Schafer R., Festag J.R. et al. // Surf. Rev. Lett. 1996. V. 3. P. 1121.
  21. Kurlyandskaya G.V., Portnov D.S, Beketov I.V. et al. // Bioch. Biophys. Acta. 2017. V. 1861. P. 1494.
  22. Blyakhman F.A., Buznikov N.A., Sklyar T.F. et al. // Sensors. 2018. V. 18. Art. No. 872.
  23. Li X.G., Chiba A., Takahashi S. et al. // Materials. 1997. V. 173. Art. No. 101.
  24. Beketov I.V., Safronov A.P., Medvedev A.I. et al. // AIP Advances. 2012. V. 2. Art. No. 022154.
  25. Курляндская Г.В., Архипов А.В., Бекетов И.В. и др. // ФТТ. 2023. Т. 65. № 6. С. 861; Kurlyandskaya G.V., Arkhipov A.V., Beketov I.V. et al. // Phys. Sol. St. 2023. V. 65. No. 6. P. 861.
  26. Hansen M.F., Vecchio K.S., Parker F.T. et al. // Appl. Phys. Lett. 2003. V. 82. P. 1574.
  27. Semaltianos N.G., Karczewski G. // ACS Appl. Nano Mater. 2021. V. 4. P. 6407.
  28. Amendola V., Riello P., Polizzi S. et al. // J. Mater. Chem. 2011. V. 21. P. 18665.
  29. Zhang H., Liang C., Liu J. et al. // Carbon. 2013. V. 55. P. 108.
  30. Franzel L., Bertino M.F., Huba Z.J., Carpenter E.E. // Appl. Surf. Sci. 2012. V. 261. P. 332.
  31. Amendola V., Scaramuzza S., Carraro F., Cattaruzza E. // J. Colloid Interface Sci. 2017. V. 489. P. 18.
  32. Zograf G.P., Zuev D.A., Milichko V.A. // J. Phys. Conf. Ser. 2016. V. 741. Art. No. 012119.
  33. Haustrup N., O’Connor G.M. // J. Nanosci. Nanotechnol. 2012. V. 12. No. 11. P. 8656.
  34. Bubb D.M., O’Malley S.M., Schoeffling J. et al. // Chem. Phys. Lett. 2013. V. 565. P. 65.
  35. Scaramuzza S., Zerbetto M., Amendola V. // J. Phys. Chem. C. 2016. V. 120. No. 17. P. 9453.
  36. Александров В.А. // Междунар. научн. журн. Альтернативная энергетика и экология. 2007. № 11. С. 160.
  37. Matthias E., Reichling M., Siegel J. // Appl. Phys. A. 1994. V. 58. P. 129.
  38. Perminov P.A., Dzhun I.O., Ezhov A.A. et al. // Laser Phys. 2011. V. 21. No. 4. P. 801.
  39. Liang J., Liu W., Li Y. et al. // Appl. Surf. Sci. 2018. V. 456. P. 482.
  40. Zabotnov S.V., Skobelkina A.V., Kashaev F.V. et al. // Sol. St. Phenom. 2020. V. 312. P. 200.
  41. Петров Ю.И. Кластеры и малые частицы. Москва: Наука, 1986.
  42. Santillán J.M.J., van Raap M.B.F., Zelis P.M. et al. // J. Nanopart. Res. 2015. V. 17. No. 2. Art. No. 86.
  43. Santillán J.M.J., Arboleda D.M., Coral D.F. et al. // ChemPhysChem. 2017. V. 18. No. 9. P. 1192.
  44. Ghaem E.N., Dorranian D., Sari A.H. // Physica E. 2020. V. 115. Art. No. 113670.
  45. Hu S., Meltonc C., Mukherjee D. // Phys. Chem. Chem. Phys. 2014. V. 16. Art. No. 24034.
  46. Zhu H.T., Luo J., Liang J.K. et al. // Physica B. 2008. V. 403. P. 3141.
  47. Makhlouf S.A. // J. Magn. Magn. Mater. 2002. V. 246. P. 184.
  48. Ghaem E.N., Dorranian D., Sari A.H. // Opt. Quantum Electron. 2021. V. 53. Art. No. 36.
  49. Svetlichnyi V.A., Shabalina A.V., Lapin I.N. et al. // Appl. Surf. Sci. 2018. V. 462. P. 226.
  50. Luna C., del Puerto Morales M., Serna C.J., Vázquez M. // Nanotech. 2003. V. 14. P. 268.
  51. Dutta P., Seehra M.S., Thota S., Kumar J. // J. Phys. Cond. Matter. 2008. V. 20. Art. No. 015218.
  52. Pal A.K., Chaudhuri S., Barua A.K. // J. Phys. D. Appl. Phys. 1976. V. 9. P. 2261.
  53. Huang H., Zhigilei L.V. // J. Phys. Chem. C. 2021. V. 125. No. 24. P. 13413.
  54. Inogamov N.A., Zhakhovsky V.V., Petrov Y.V. et al. // Contrib. Plasma Phys. 2013. V. 53. No. 10. P. 796.
  55. Zhilan L., Xinghai Ch., Jianxiong W. et al. // Mineral. Mag. 2022. V. 6. No. 2. P. 346.
  56. Lei Z., Chen X., Wang J. et al. // Mineral. Mag. 2022. V. 86. No. 2. P. 346.
  57. Wang R.-P., Zhou G.-W. Liu Y.-L. et al. // Phys. Rev. B. 2000. V. 61. No. 24. P. 16827.
  58. Gao Y., Qin Y., Dong C., Li G. // Appl. Surf. Sci. 2014. V. 311. P. 413.

Supplementary files

Supplementary Files
Action
1. JATS XML
Download

Copyright (c) 2024 Russian Academy of Sciences