Turning crystal flaws into quantum highways: A new route towards scalable solid-state qubits

Building large-scale quantum technologies requires reliable ways to connect individual quantum bits (qubits) without ...
Morning Overview on MSN

Scientists turn crystal defects into quantum superhighways for scalable qubits

Quantum engineers have spent years trying to tame the fragility of qubits, only to be thwarted by the tiniest imperfections ...
Phys.org

Study shows defects spreading through diamond faster than the speed of sound

Illustration of an intense laser pulse hitting a diamond crystal from top right, driving elastic and plastic waves (curved lines) through the material. The laser pulse creates linear defects, known as ...
Science Daily

Artificial intelligence unravels mysteries of polycrystalline materials

Researchers have used artificial intelligence to solve a difficult problem in crystal science. Seeking to understand why crystals develop tiny defects called dislocations, the researchers discovered ...
Nanowerk

Using electric fields to control the movement of defects in crystals

(Nanowerk News) An international team of researchers, led by Professor Yu Zou (MSE), is using electric fields to control the motion of material defects. This work has important implications for ...
EurekAlert!

University of Toronto Engineering researchers are using electric fields to control the movement of defects in crystals

An international team of researchers, led by University of Toronto Engineering Professor Yu Zou, is using electric fields to control the motion of material defects. This work has important ...
Science Daily

Groundbreaking study shows defects spreading through diamond faster than the speed of sound

Settling a half century of debate, researchers have discovered that tiny linear defects can propagate through a material faster than sound waves do. These linear defects, or dislocations, are what ...