TU Wien 进行的计算表明使用钯金属作为“金发姑娘”材料来制造超导体,即使在相对较高的温度下也能保持超导性。
在现代物理学领域,一项令人振奋的工作正在进行:确定制造在高温高压下保持超导性的超导体的最佳方法。 最近,随着镍的出现,这项努力重新焕发了活力,开创了超导性的新纪元。
这些超导体的基础在于镍,这使得许多科学家将这段超导研究时期称为“镍时代”。 在很多方面,镍与铜相似,都是在 1980 年代发现的,以铜为基础。
但现在一类新材料开始发挥作用:维也纳工业大学与日本大学合作,可以比以前更准确地在计算机上模拟不同材料的行为。
有一个“金发姑娘区”,超导性在其中运作良好。 这个区域不是镍,也不是铜,而是钯。 这可能会开启超导研究的“扁平化新时代”。 结果现已发表在科学杂志上
The search for higher transition temperatures
At high temperatures, superconductors behave very similarly to other conducting materials. But when they are cooled below a certain “critical temperature”, they change dramatically: their electrical resistance disappears completely and suddenly they can conduct electricity without any loss. This limit, at which a material changes between a superconducting and a normally conducting state, is called the “critical temperature”.
“We have now been able to calculate this “critical temperature” for a whole range of materials. With our modeling on high-performance computers, we were able to predict the phase diagram of nickelate superconductivity with a high degree of accuracy, as the experiments then showed later,” says Prof. Karsten Held from the Institute of Solid State Physics at TU Wien.
Many materials become superconducting only just above absolute zero (-273.15°C), while others retain their superconducting properties even at much higher temperatures. A superconductor that still remains superconducting at normal room temperature and normal atmospheric pressure would fundamentally revolutionize the way we generate, transport, and use electricity. However, such a material has not yet been discovered.
Nevertheless, high-temperature superconductors, including those from the cuprate class, play an important role in technology – for example, in the transmission of large currents or in the production of extremely strong magnetic fields.
Copper? Nickel? Or Palladium?
The search for the best possible superconducting materials is difficult: there are many different chemical elements that come into question. You can put them together in different structures, you can add tiny traces of other elements to optimize superconductivity. “To find suitable candidates, you have to understand on a quantum-physical level how the electrons interact with each other in the material,” says Prof. Karsten Held.
This showed that there is an optimum for the interaction strength of the electrons. The interaction must be strong, but also not too strong. There is a “golden zone” in between that makes it possible to achieve the highest transition temperatures.
Palladates as the optimal solution
This golden zone of medium interaction can be reached neither with cuprates nor with nickelates – but one can hit the bull’s eye with a new type of material: so-called palladates. “Palladium is directly one line below nickel in the periodic table. The properties are similar, but the electrons there are on average somewhat further away from the atomic nucleus and each other, so the electronic interaction is weaker,” says Karsten Held.
The model calculations show how to achieve optimal transition temperatures for palladium data. “The computational results are very promising,” says Karsten Held. “We hope that we can now use them to initiate experimental research. If we have a whole new, additional class of materials available with palladates to better understand superconductivity and to create even better superconductors, this could bring the entire research field forward.”
Reference: “Optimizing Superconductivity: From Cuprates via Nickelates to Palladates” by Motoharu Kitatani, Liang Si, Paul Worm, Jan M. Tomczak, Ryotaro Arita and Karsten Held, 20 April 2023, Physical Review Letters.
DOI: 10.1103/PhysRevLett.130.166002
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