To explore what happens when electrical resistance develops in unconventional metals, researchers led by Princeton University physicists sent a density wave through a gas of ultracold atoms (top left). The researchers observed the dissipation of the density wave over time, which is analogous to what happens in metals when resistance slows the flow of electricity. The bottom row shows the same experiment using a finer wave. Image: Peter Brown and Waseem Bakr, Princeton University.
To explore what happens when electrical resistance develops in unconventional metals, researchers led by Princeton University physicists sent a density wave through a gas of ultracold atoms (top left). The researchers observed the dissipation of the density wave over time, which is analogous to what happens in metals when resistance slows the flow of electricity. The bottom row shows the same experiment using a finer wave. Image: Peter Brown and Waseem Bakr, Princeton University.

Using laser light to trap atoms in a checkerboard-like pattern, a team led by scientists at Princeton University have studied how resistance – the loss of electrical current as heat – can develop in unconventional metals. Their results, which are reported in a paper in Science, may help explain how certain types of superconductors made from copper oxides are able to conduct electricity so efficiently.

Superconducting materials can efficiently transmit electricity without losing any of the current as heat. Because they don't waste electricity, they have the potential to boost the energy-efficiency of the electrical power grid, and may also open up possibilities for new technologies.

"If you want to carry electricity in power lines more efficiently, then improving our fundamental understanding of transport in these materials will have a significant impact on our ability to design better materials," said Waseem Bakr, assistant professor of physics at Princeton University and senior author of the paper.

To explore how resistance develops in materials, the researchers created an experiment that involved trapping atoms in an evenly spaced grid made from intersecting laser beams. The resulting structure, called an optical lattice, holds the atoms like eggs in an egg carton or checkers on a checkerboard.

This setup allows researchers to see what is happening between the atoms. Normally this is not possible because the atoms in a solid are tightly packed.

In this experiment, the atoms were about 10,000 times farther from each other than the atoms in a typical material, which allowed the researchers to view them using a microscope. The tiny particles were kept at intensely cold temperatures – just a few billionths of a degree above absolute zero – to quell their normal jumpiness.

The researchers used the atoms as a stand-in for electrons, the charged particles that carry electrical current. Atoms are easier to image and manipulate than electrons.

"Our lithium atoms in an optical lattice obey the same physics as electrons in real materials," explained Peter Brown, a graduate student in physics at Princeton and first author of the paper. "This is advantageous because we have greater control over our system than is possible using real materials – for example, we can tune the interactions between atoms and change the density of atoms."

To explore how resistance develops, the researchers projected a laser beam onto the atoms in the lattice, creating ripples of density that travel through the atoms. The team measured how quickly the waves died away, which happens because the atoms bump against each other and get out of sync.

The team repeated the experiment for a variety of different temperatures, each time heating up the atoms to a different temperature and observing how the resistance changed with temperature.

They saw two interesting things happen. One was that as the temperature increased the resistance increased in a linear fashion: an increase in temperature led to a proportional increase in resistance. This was surprising because the simplest theory for these systems, which is called the Fermi liquid theory, predicts a different pattern of response to temperature. This involves the resistance increasing as the square of temperature: so, as temperature increases, resistivity increases slowly at first and then rapidly.

The unexpected linear response to temperature is one that is seen in copper oxide, or ‘cuprate’, superconductors, which are prized for their ability to work at relatively high temperatures compared to other types of superconductors. Their behavior has earned these materials the name ‘strange metals’, and some researchers think that understanding this behavior might shed light on the origin of high-temperature superconductivity.

Another observation the team made is that at high temperatures the resistance exceeds what theorists predicted was possible in those systems. The explanation for this is that the atoms are no longer behaving as discrete particles, but rather as a quantum soup where each particle no longer has its own identity. This state happens when a system exceeds a theoretical bound called the Mott-Ioffe-Regel (MIR) limit. Physicists call such materials ‘bad metals’.

This state is interesting because resistance is thought to develop when particles scatter, bouncing off nearby particles like pinballs in a machine. Surpassing the MIR bound implies that the particles do not follow this simple picture.

"Common sense says that a particle cannot scatter until it bounces off another particle. But what we saw was that resistivity keeps increasing and doesn't respect this bound," Bakr said.

This story is adapted from material from Princeton University, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.