Laura Heyderman, Zhaochu Luo and Pietro Gambardello have discovered the new phenomen in nanomagnets. (Photograph: ETH Zurich)
The phenomenon observed jointly by PSI and ETH Zurich researchers enables the development of planar magnetic networks. Among other things, synthetic antiferromagnets can be produced. In these antiferromagnets, atomic groups point either North or South at regular intervals. The number of opposing nanomagnets is approximately the same, so that they neutralize each other in sum. This is why, at first glance, antiferromagnets do not act like magnets – for example, they do not stick to a fridge door.
The neighbouring atoms, which are oriented either to the West or to the East, act as spacers separating the magnets pointing North or South, each of which is as small as a few nanometers. This makes it possible, for example, to build new, more efficient computer memories and switches, which in turn makes microprocessors more powerful.
Logical gates for computers
The individual nanomagnets, which face either North or South, are suitable for constructing logic gates. A logic gate is a building block in a computer and functions as a kind of switch. Signals enter these gates and are then processed into an output signal. In a computer many of these gates are networked to perform operations. Such a gate can also be constructed with the help of nanomagnets aligned to the North or South. These are analogous to processors commonly used today with transistors processing signals in binary form, which interpret all signals as zero or one. Nanomagnets that are oriented either North or South can also do this. This could make microprocessors more compact and efficient.
According to Prof. Pietro Gambardella, who supervised this study with Prof. Laura Heyderman, "This work provides a platform to design arrays of linked nanomagnets and achieve all-electric control of planar logic gates and storage devices," as reported in Science this week.
In addition to laboratory based methods, the researchers achieved their results by means of X-ray photoelectron microscopy at the PSI's Swiss Light Source SLS.
