posted on 2015-06-10, 00:00authored byFusheng Ma, Yan Zhou, H. B. Braun, W. S. Lew
A linear
array of periodically spaced and individually controllable skyrmions
is introduced as a magnonic crystal. It is numerically demonstrated
that skyrmion nucleation and annihilation can be accurately controlled
by a nanosecond spin polarized current pulse through a nanocontact.
Arranged in a periodic array, such nanocontacts allow the creation
of a skyrmion lattice that causes a periodic modulation of the waveguide’s
magnetization, which can be dynamically controlled by changing either
the strength of an applied external magnetic field or the density
of the injected spin current through the nanocontacts. The skyrmion
diameter is highly dependent on both the applied field and the injected
current. This implies tunability of the lowest band gap as the skyrmion
diameter directly affects the strength of the pinning potential. The
calculated magnonic spectra thus exhibit tunable allowed frequency
bands and forbidden frequency bandgaps analogous to that of conventional
magnonic crystals where, in contrast, the periodicity is structurally
induced and static. In the dynamic magnetic crystal studied here,
it is possible to dynamically turn on and off the artificial periodic
structure, which allows switching between full rejection and full
transmission of spin waves in the waveguide. These findings should
stimulate further research activities on multiple functionalities
offered by magnonic crystals based on periodic skyrmion lattices.