All optical control of magnetization in quantum confined ultrathin magnetic metals

Saeedeh Mokarian Zanjani; Muhammad Tahir Naseem; Özgür Esat Müstecaplıoğlu; Mehmet Cengiz Onbaşlı

doi:10.1038/s41598-021-95319-6

All optical control of magnetization in quantum confined ultrathin magnetic metals

Sci Rep. 2021 Aug 5;11(1):15976. doi: 10.1038/s41598-021-95319-6.

Authors

Saeedeh Mokarian Zanjani¹, Muhammad Tahir Naseem², Özgür Esat Müstecaplıoğlu², Mehmet Cengiz Onbaşlı^{3

4}

Affiliations

¹ Graduate School of Materials Science and Engineering, Koç University, Sarıyer, 34450, Istanbul, Turkey. szanjani16@ku.edu.tr.
² Department of Physics, Koç University, Sarıyer, 34450, Istanbul, Turkey.
³ Graduate School of Materials Science and Engineering, Koç University, Sarıyer, 34450, Istanbul, Turkey. monbasli@ku.edu.tr.
⁴ Department of Electrical and Electronics Engineering, Koç University, Sarıyer, 34450, Istanbul, Turkey. monbasli@ku.edu.tr.

Abstract

All-optical control dynamics of magnetization in sub-10 nm metallic thin films are investigated, as these films with quantum confinement undergo unique interactions with femtosecond laser pulses. Our theoretical analysis based on the free electron model shows that the density of states at Fermi level (DOS_F) and electron-phonon coupling coefficients (G_ep) in ultrathin metals have very high sensitivity to film thickness within a few angstroms. We show that completely different magnetization dynamics characteristics emerge if DOS_F and G_ep depend on thickness compared with bulk metals. Our model suggests highly efficient energy transfer from femtosecond laser photons to spin waves due to minimal energy absorption by phonons. This sensitivity to the thickness and efficient energy transfer offers an opportunity to obtain ultrafast on-chip magnetization dynamics.

Abstract

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