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Electrons stay put in layers of mismatched ‘quantum Legos’

Electrons can be elusive, but Cornell researchers using a new computational method can now account for where they go—or don’t go—in certain layered materials.

Physics and engineering researchers have confirmed that in certain quantum materials, known as “misfits” because their crystal structures don’t align perfectly—picture LEGOs where one layer has a square grid and the other a hexagonal grid—electrons mostly stay in their home layers.

This discovery, important for designing materials with quantum properties including superconductivity, overturns a long-standing assumption. For years, scientists believed that large shifts in energy bands in certain misfit materials meant electrons were physically moving from one layer to the other. But the Cornell researchers have found that chemical bonding between the mismatched layers causes electrons to rearrange in a way that increases the number of high-energy electrons, while few electrons move from one layer to the other.

Observing ultrafast magnetic domain changes at the nanoscale with soft X-rays

Scientists at the Max Born Institute have developed a new soft X-ray instrument that can reveal dynamics of magnetic domains on nanometer length and picosecond time scales. By bringing capabilities once exclusive to X-ray free-electron lasers into the laboratory, the work paves the way for routine investigations of ultrafast processes of emergent textures in magnetic materials and beyond.

A dropped fridge magnet offers a simple glimpse into a complex physical phenomenon: although it appears undamaged on the outside, its holding force can weaken because its internal magnetic structure has reorganized into countless tiny regions with opposing magnetization, so-called magnetic domains.

These nanoscale textures are central to modern magnetism research, but observing them at very short time scales has long required access to large-scale X-ray free-electron laser (XFEL) facilities.

Ramanujan’s 100-Year-Old Pi Formula That Hides the Secrets of the Universe

A new study reveals that Srinivasa Ramanujan’s century-old formulas for calculating pi unexpectedly emerge within modern theories of critical phenomena, turbulence, and black holes. In school, many of us first encounter the irrational number π (pi) – rounded off as 3.14, with an infinite number o

Quantum Tech Hits Its “Transistor Moment,” Scientists Say

A new article examines the history of computing to help outline the direction of quantum research. It reports that quantum technology is advancing quickly, and that the major obstacles now involve expanding the systems to larger scales. Quantum technology is quickly moving beyond experimental set

Scientists Unveil the Most Realistic Black Hole Accretion Model Ever Created

Using cutting-edge algorithms and exascale supercomputers, researchers have created the most realistic simulations yet of matter flowing into black holes. Building on decades of research, a group of computational astrophysicists has reached an important breakthrough: they have created the most de

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