# Electrons in 1.58 dimensions? What the frac!

## Utrecht physicists build fractal shape out of electrons

12 November 2018

In physics, it is already well-known that electrons behave very differently in three dimensions (cube), two dimensions (sheet) or one dimension (wire). These different electronic properties give rise to a variety of possibilities for technological applications and electronic systems. But what happens if electrons live in 1.58 dimensions – and what does it actually mean to live in 1.58 dimensions? Theoretical and experimental physicists at Utrecht University investigated that in a new study that will be published in Nature Physics on 12 November 2018.

Electrons in bonding (left) and non-bonding (right) Sierpiński triangles; scale bar 2nm. (Figure: Kempkes et al., Nature Physics, 2018)

It may be difficult to imagine 1.58 dimensions, but the idea is more familiar to you than you think at first glance. A non-integer dimension such as 1.58 can be found in fractals: self-similar structures that scale in a different way than normal objects. If you zoom in, you will see the same structure again. For example, a small piece of Romanesco broccoli typically looks similar to the whole head of broccoli. Fractal structures are very common in nature, because they have a large surface area relative to their volume. For example, the fractal shape of your lungs means that their large surface area allows them to exchange as much oxygen with the blood as possible. Fractals are also very useful in technology. For example, fractal-shaped antennae have a large surface area, allowing them to receive and transmit signals in a large frequency range.

## Electronic nanoscale fractals

A relatively new topic in fractals is the quantum behaviour that emerges if you zoom in all the way to the scale of electrons. Using a quantum simulator, Utrecht physicists Sander Kempkes and Marlou Slot were able to build such a fractal out of electrons. The researchers made a ‘muffin tin’ in which the electrons would confine to a fractal shape, by placing carbon monoxide molecules in just the right shape on a copper background with a scanning tunneling microscope. The resulting triangular fractal shape in which the electrons were confined is called a Sierpiński triangle, which has a fractal dimension of 1.58. The researchers observed that the electrons in the triangle actually behave as if they live in 1.58 dimensions.

## Electronic wavefunction

The results from the study show that the electrons form a bonding (left image) and non-bonding (right image) Sierpiński triangle at different energies, yielding nice opportunities for transmitting currents through these fractal structures. In the bonding case, the electrons spread over the entire triangle and can easily go from one place to another (high transmission), whereas in the non-bonding case they are bound to certain positions and need to “jump” to another place (low transmission). Also, by calculating the dimension of the electronic wavefunction, the researchers observed that the electrons themselves are confined to the 1,58 dimensions and the wavefunctions inherit this fractional dimension.

## Interesting and groundbreaking

“From a theoretical point of view, this is a very interesting and groundbreaking result,” says theoretical physicist Cristiane de Morais Smith, who supervised the study together with experimental physicists Ingmar Swart and Daniel Vanmaekelbergh. “It opens a whole new line of research, raising questions such as: are the properties of electrons in all non-integer dimension similar to each other? Do they behave more like in one dimension or in two dimensions? And what happens if a magnetic field is turned on perpendicularly to the sample? Fractals already have a very large number of applications, so these results may have a big impact on research at the quantum scale. One thing is for sure: the future of electronics looks fractastic!”

### Publication

Design and characterization of electrons in a fractal geometry

*Sander N. Kempkes, Marlou R. Slot, Saoirsé E. Freeney, Stephan J.M. Zevenhuizen, Daniël Vanmaekelbergh, Ingmar Swart, Cristiane Morais Smith**

Nature Physics

** All authors are affiliated with Utrecht University*

This research was funded in part by NWO Physics Projectruimte and the European Research Council.

Source: Utrecht University