Home Science When Electrons Slowly Vanish Throughout Cooling

When Electrons Slowly Vanish Throughout Cooling

When Electrons Slowly Vanish Throughout Cooling


Quasiparticle Ultrashort Light Pulse

Composed of localized and cell electrons, right here damaged up by an ultrashort gentle pulse. Credit score: College of Bonn

Scientists observe an impact within the quantum world that doesn’t exist within the macrocosm.

Researchers on the College of Bonn and ETH Zurich have carried out an in-depth research of distinctive section transitions in sure metals. Their findings present a greater understanding of quantum physics and probably advance the sector of quantum info expertise.

When they’re cooled under a sure crucial temperature, many substances change their properties. For instance, such a section transition happens, when water freezes. Nevertheless, in sure metals, there are section transitions that don’t exist within the macrocosm. They come up due to the particular legal guidelines of quantum mechanics that apply within the realm of nature’s smallest constructing blocks. It’s thought that the idea of electrons as carriers of quantized electrical cost not applies close to these unique section transitions.

Scientists have now discovered a solution to show this straight. Their findings enable new insights into the unique world of quantum physics. The publication, by researchers on the College of Bonn and ETH Zurich, has now been launched within the journal Nature Physics.

Understanding Phase Transitions

If you cool water below zero degrees Celsius (32 degrees Fahrenheit), it solidifies into ice. In the process, it abruptly changes its properties. As ice, for example, it has a much lower density than in a liquid state. This is why ice cubes and icebergs float. In physics, this is referred to as a phase transition.

But there are also phase transitions in which characteristic features of a substance change gradually. If, for example, an iron magnet is heated up to 760 degrees Celsius (1,400 degrees Fahrenheit), it loses its attraction to other pieces of metal – it is then no longer ferromagnetic, but paramagnetic. However, this does not happen abruptly, but continuously: The iron atoms behave like tiny magnets

At low temperatures, they are oriented parallel to each other. When heated, they fluctuate more and more around this rest position until they are completely randomly aligned, and the material loses its magnetism completely. So while the metal is being heated, it can be both somewhat ferromagnetic and somewhat paramagnetic.

Hans Kroha

Prof. Dr. Hans Kroha with students. Credit: Bernadett Yehdou/University of Bonn

Matter Particles Cannot be Destroyed

The phase transition thus takes place gradually, so to speak, until finally, all the iron is paramagnetic. Along the way, the transition slows down more and more. This behavior is characteristic of all continuous phase transitions.

“We call it ‘critical slowing down,’“ explains Prof. Dr. Hans Kroha of the Bethe Center for Theoretical Physics at the University of Bonn. “The reason is that with continuous transitions, the two phases get energetically closer and closer together.”

It is similar to placing a ball on a ramp: It then rolls downhill, but the smaller the difference in altitude, the more slowly it rolls. When iron is heated, the energy difference between the phases decreases more and more, in part because the magnetization disappears progressively during the transition.

Such a “slowing down” is typical for phase transitions based on the excitation of bosons. Bosons are particles that “generate” interactions (on which, for example, magnetism is based). Matter, on the other hand, is not made up of bosons but of fermions. Electrons, for example, belong to the fermions.

Phase transitions are based on the fact that particles (or also the phenomena triggered by them) disappear. This means that the magnetism in iron becomes smaller and smaller as fewer atoms are aligned in parallel. “Fermions, however, cannot be destroyed due to fundamental laws of nature and therefore cannot disappear,” Kroha explains. “That’s why normally they are never involved in phase transitions.”

Electrons Turn Into Quasiparticles

Electrons can be bound in atoms; they then have a fixed place which they cannot leave. Some electrons in metals, on the other hand, are freely mobile – which is why these metals can also conduct electricity. In certain exotic quantum materials, both varieties of electrons can form a superposition state. This produces what are known as quasiparticles. They are, in a sense, immobile and mobile at the same timetime – a feature that is only possible in the quantum world.

These quasiparticles – unlike “normal” electrons – can be destroyed during a phase transition. This means that the properties of a continuous phase transition can also be observed there, in particular, critical slowing down.

So far, this effect could be observed only indirectly in experiments. Researchers led by theoretical physicist Hans Kroha and Manfred Fiebig’s experimental group at ETH Zurich have now developed a new method, which allows direct identification of the collapse of quasiparticles at a phase transition, in particular the associated critical slowing down.

“This has enabled us to show for the first time directly that such a slowdown can also occur in fermions,” says Kroha, who is also a member of the Transdisciplinary Research Area “Matter” at the University of Bonn and the Cluster of Excellence “Matter and Light for Quantum Computing” of the German Research Foundation. The result contributes to a better understanding of phase transitions in the quantum world. On the long term, the findings might also be useful for applications in quantum information technology.

Reference: “Critical slowing down near a magnetic quantum phase transition with fermionic breakdown” by Chia-Jung Yang, Kristin Kliemt, Cornelius Krellner, Johann Kroha, Manfred Fiebig and Shovon Pal, 31 July 2023, Nature Physics.
DOI: 10.1038/s41567-023-02156-7

The study was carried out in collaboration of ETH Zurich and the University of Bonn. The work was funded by the Swiss National Science Foundation (SNF) and the German Research Foundation (DFG).



Please enter your comment!
Please enter your name here