Behind every particle collision generated at the Large Hadron Collider is a multitude of technical feats. One of these is refrigeration on an industrial scale. To guide the particles, the thousands of superconducting magnets in the accelerator must be cooled to a temperature of close to absolute zero. This makes the LHC the largest cryogenic installation in the world: 23 of its 27 kilometers are maintained at 1.9 Kelvin (−271°C) using refrigerators in which superfluid helium circulates.

This unique cooling system needs to be further strengthened in preparation for the High-Luminosity LHC (HL-LHC), a major upgrade to the LHC that is scheduled to begin operation in 2030. On both sides of the two large experiments, ATLAS and CMS, more powerful focusing magnets and new types of cavities will considerably increase the number of collisions at each beam crossing or, in other words, the luminosity. This ultra-sophisticated equipment requires increased cooling power. Two new refrigerators are therefore being installed, in addition to the eight that are already needed for the existing accelerator.

The LHC’s refrigerators work on the same principle as the one in your kitchen, except that they are gigantic installations that occupy several buildings. Located on the surface, they include large compressors and an enormous cold box that contains the heat exchangers and the expansion turbines. These installations lower the helium temperature to 4.5 Kelvin (−268.6°C). Six compression units were installed in October.

A long-standing explanation for magnetoresistance may be incomplete. New evidence suggests a universal interfacial mechanism is at play. A major advance in spintronics came with the discovery of unusual magnetoresistance (UMR). In this effect, the electrical resistance of a heavy metal changes wh