Abstract

Data carriers using spin waves in spintronic and magnonic logic devices offer operation at low power consumption and free of Joule heating yet requiring noncollinear spin structures of small sizes. Heterometallic rings can provide such an opportunity due to the controlled spin-wave transmission within such a confined space. Here, we present a series of {Sc_<i>n</i>Gd_<i>n</i>} (<i>n</i> = 4, 6, 8) heterometallic rings, which are the first Sc-Ln clusters to date, with tunable magnetic interactions for spin-wave excitations. By means of time- and temperature-dependent spin dynamics simulations, we are able to predict distinct spin-wave excitations at finite temperatures for <b>Sc</b>_<b>4</b><b>Gd</b>_<b>4</b>, <b>Sc</b>_<b>6</b><b>Gd</b>_<b>6</b>, and <b>Sc</b>_<b>8</b><b>Gd</b>_<b>8</b>. Such a new model is previously unexploited, especially due to the interplay of antiferromagnetic exchange, dipole-dipole interaction, and ring topology at low temperatures, rendering the importance of the latter to spin-wave excitations.