Magnon drag isolated using unique device geometry

Scientists have finally isolated magnon drag from other thermoelectric effects after a 50-year quest.

Last Updated: Dec 19, 2011, 11:18 AM IST

Washington: Scientists have finally isolated magnon drag from other thermoelectric effects after a 50-year quest.
As electrons move past atoms in a solid, their charge distorts the nearby lattice and can create a wave. Reciprocally, a wave in the lattice affects the electrons motion, in analogy to a wave in the sea that pushes a surfer riding it.

This interaction results in a thermoelectric effect that was first observed during the 1950’s and has come to be known as phonon-drag, because it can be quantified from the flow of lattice-wave quanta (phonons) that occurs over the temperature gradient.

Soon after the discovery of the phonon drag, an analogous phenomenon was predicted to appear in magnetic materials: the so-called magnon drag.

In a magnetic material the intrinsic magnetic moment or spin of the electrons arrange in an organized fashion. In ferromagnets, the spins maintain a parallel orientation.

If a distortion in the preferred spin orientation occurs, a spin wave is created that could affect electron motion. It is therefore reasonable to expect that the flow of magnons (spin-wave quanta) could also drag the electrons.

Despite the similarities with phonon drag, the observation of the magnon drag has been elusive, and only a few indirect indications of its existence have been reported over the years. The main reason being the presence of other thermoelectric effects, most notably the phonon drag, that make it difficult to discriminate its contribution to the thermopower.

Now, researchers of ICN’s Physics and Engineering of Nanodevices Group, Marius V. Costache, German Bridoux, Ingmar Neumann and group leader ICREA Prof. Sergio O. Valenzuela have discriminated the magnon drag from other thermoelectric effects using a unique device geometry.

The device resembles a thermopile formed by a large number of pairs of ferromagnetic wires placed between a hot and a cold source and connected thermally in parallel and electrically in series.

By controlling the relative orientation of the magnetization in pairs of wires, the magnon drag can be studied independently of the electron and phonon drag thermoelectric effects.

This information is crucial to understand the physics of thermal spin transport.