Researchers develop a magnetic nanoscale thermal switch

Heat in magnetic nanopillar
The researchers used this knowledge to construct a nanopillar that consists of two magnetic layers with a non-magnetic layer in between. In this pillar the magnetisation of both magnetic layers could be switched on or off independently to influence the heat conduction. The pillar is just 80 nanometres wide – 1000 times smaller than the thickness of a human hair.

If the magnetisation in the outermost layers of the pillar is in the same direction, electrons with the same spin direction in both layers will have a higher heat conduction, and therefore assume a higher temperature. This means heat can easily be transported from one side of the pillar to the other and so a high level of heat conduction occurs.

Yet if the magnetisation in the two layers is in opposite directions then electrons with a high heat conduction in the one magnetic layer have an opposite spin direction from the electrons in the second magnetic layer. This makes it harder to transport heat through the pillar and so the heat conduction is suppressed. Consequently the quantity of heat flowing through the pillar can be switched on and off.

Spin caloritronics
The results are a following step in 'spin caloritronics', a young research field that studies the role of the magnetic movement of electrons in heat transport.

As the switches can be so incredibly small, we can use these to regulate local heat supply or removal. That could be useful in chips that sometimes become far too hot at localised hotspots.

Source: FOM press release.

See also the Nature Physics paper