The kind of light you use can reveal very different things about a material. Visible light mainly shows what is happening at the surface. X-rays can probe structures inside. Infrared light highlights the heat a material gives off.

Researchers at MIT have now turned to terahertz light to uncover quantum vibrations in a superconducting material, signals that scientists have not been able to observe directly until now.

From the article:

…in copper, the transition was extremely fast, taking about 26 attoseconds.

In the layered materials TiSe₂ and TiTe₂, the same process slowed to between 140 and 175 attoseconds. In CuTe, with its chain-like structure, the transition exceeded 200 attoseconds. These findings show that the atomic scale shape of a material strongly affects how quickly a quantum event unfolds, with lower symmetry structures leading to longer transition times.

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Time may feel smooth and continuous, but at the quantum level it behaves very differently. Physicists have now found a way to measure how long ultrafast quantum events actually last, without relying on any external clock. By tracking subtle changes in electrons as they absorb light and escape a material, researchers discovered that these transitions are not instantaneous and that their duration depends strongly on the atomic structure of the material involved.

Quantum materials and superconductors are difficult enough to understand on their own. Unconventional superconductors, which cannot be explained within the framework of standard theory, take the enigma to an entirely new level. A typical example of unconventional superconductivity is strontium ruthenate, SRO₂₁₄, the superconductive properties of which were discovered by a research team that included Yoshiteru Maeno, who is currently at the Toyota Riken—Kyoto University Research Center.

The findings are published in the journal Physical Review Letters.

Debate over SRO₂₁₄’s superconducting nature.

Imagine trying to read Braille while wearing thick winter gloves; you might feel the general shape of the book, but the story remains a mystery. For decades, this has been the reality for physicists trying to “feel” the invisible energy landscapes that govern how electrons move in quantum materials. Now, researchers at the Weizmann Institute of Science have taken the gloves off.

A single atomic defect acts as a new type of microscope to reveal the electrostatic potential landscape steering the behavior of electrons in quantum materials. (Image: Weizmann Institute of Science)