Glassy materials are everywhere, with applications far exceeding windowpanes and drinking glasses. They range from bioactive glasses for bone repair and amorphous pharmaceuticals that boost drug solubility to ultra-pure silica optics used in gravitational-wave detectors. In principle, any substance can become glass if its hot liquid is cooled fast enough to avoid forming an ordered crystal.

A distinguishing feature of glass is that its atoms freeze into an irregular, disordered arrangement. This stands in contrast to crystals, where atoms sit in a regular pattern. This disorder gives glass many of its unique and useful properties, but scientists still struggle to understand how atomic-scale disorder produces the properties observed in everyday glasses.

A research team led by Kuang Guangli and Jiang Donghui at the High Magnetic Field Laboratory of the Hefei Institutes of Physical Science of the Chinese Academy of Sciences (CHMFL), has developed a “pocket-type” high-temperature superconducting (HTS) coil, achieving a record combined magnetic field of 44.86 tesla.

The coil, wound using domestically produced REBa₂Cu₃O₇₋ₓ (REBCO) tapes, generated 28.20 T at zero field in a liquid helium bath and produced an additional 10.36 T inside the 34.5 T steady-state magnetic field of the WM5 water-cooled magnet.

Steady high magnetic fields are critical for frontier research in materials science, physics, and biology, enabling scientists to observe new phenomena and explore new laws of matter. REBCO high-temperature superconducting material has become one of the optimal choices for developing devices that generate higher magnetic fields, owing to its high current-carrying capacity and favorable mechanical properties.