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Atomic-Scale Imaging Unlocks New Paths to Next-Gen Superconductors

Atomic-scale imaging reveals that chalcogen atoms play a crucial role in Cooper pairing in Fe-based superconductors, offering new insights into high-Tc superconductivity mechanisms. Superconductivity in quantum materials, whether the Cooper pairing on the Fermi surface is mediated by phonons or by electronic fluctuations, is fundamentally described by Bardeen-Cooper-Schrieffer (BCS) theory....

Superconductivity Inspires New Dark Matter Contender

As traditional dark matter candidates—such as weakly interacting massive particles (WIMPs), axions, and primordial black holes—continue to elude detection, theorists are exploring more exotic possibilities. Guanming Liang and Robert Caldwell of Dartmouth College have proposed a new dark matter model inspired by the physics of superconductivity [1]. Their proposal draws...

Glen and colleague at NASA, Cape Canaveral. Credit: McIntosh Family Collection

A Salute to an Old Friend, Glen McIntosh-1925-2025

As they say, oftentimes in life we don’t know what we’ve got until it’s gone. And only later, upon reflection, do we come to realize and appreciate what we had. Such is the case with my old friend Glen McIntosh. I first met Glen in about 1995, when applying for...

Dylan Temples. Credit: Dan Svoboda, Fermilab

Fermilab’s Lederman Fellows Drive Quantum Research to Discover Dark Matter

A trio of Lederman fellows at Fermilab are developing ways to use quantum technology to probe the universe for dark matter and other physics phenomena. While doing so, they are sharing their enthusiasm for their work to inspire the next generation of scientists. Fermi National Accelerator Laboratory is a leader...

The patented Cryostat-the-First (CS1) insulation test apparatus, of the original NASA CTL, in 1998. Credit: Fesmire

Remembering Dr. Stan Augustynowicz, a Cryogenics Pioneer

Stanisław (“Stan”) was my mentor, business partner, and dear friend. He was a distinguished colleague, a visionary trailblazer, and a true leader in cryogenics. Stan played a pivotal role in the Cryogenic Society of America as Director of International Affairs and Board Member, and he served as VP-USA for the...

HyPStore project team at the University of Southern Queensland. Credit: HyPStore

HyPStore’s Cryogenics-at-the-Core Vision for Liquid Hydrogen Storage

As global industries push toward decarbonization, hydrogen has re-emerged as a promising energy carrier. From aviation to long-haul trucking, hydrogen offers a zero-carbon fuel alternative that could reshape mobility. But unlocking its full potential depends on solving one of its biggest hurdles: storage. Hydrogen is challenging to contain, particularly in...

Latest in Defining Cryogenics

Dewar

A dewar is a type of cryostat named after Sir James Dewar, the researcher who first developed the concept of a vacuum insulated container with silvered walls to reflect thermal radiation. Dewar was the first to liquefy hydrogen, and he created the device to store his discovery. The thermos bottle...

Stirling and Gifford-McMahon Cryocoolers

Stirling and Gifford-McMahon (GM) cryocoolers are two of the most commonly used cryocoolers in cryogenics. Both devices have a significant industrial base and operate at a wide range of temperatures and capacities. The thermodynamic cycles for both of these cryocoolers are quite similar. The Stirling cycle consists of a compressor,...

Liquefied Natural Gas (LNG)

A significant commercial application of cryogenics is the liquefaction, transport and storage of natural gas. Liquefied Natural Gas (LNG) is generally 95 percent methane with a few percent ethane and much lower concentrations of propane and butane. LNG liquefies at 111.6 K. Unlike many applications of cryogenics, the motivation for...

Latest in Cryo Central

Cryogenic Electronics

Randall Kirschman, consulting physicist, Mountain View, California ExtElect@gmail.com Cryogenic electronics—the operation of electronic devices, circuits, and systems at cryogenic temperatures—has been a valuable technology for decades. Cryogenic electronics (also referred to as low-temperature electronics, or cold electronics) can be based on semiconductive devices, on superconductive devices, or on a combination...

Particle Physics: High Energy Physics

Cryogenics and High-Energy Physics 1. From symmetry magazine: http://www.symmetrymagazine.org/cms/?pid=1000627: Cryogenics is the study of how materials behave at temperatures near absolute zero. In high-energy particle accelerators, such frigid temperatures reduce the electrical resistance of wires in superconducting magnets, increasing the magnet strength and allowing faster particle acceleration. The same holds...

HTS Degaussing Systems

From the Spring 2009 issue of Cold Facts (Volume 25, Number 2): Thanks to a joint project by the US Navy and a number of industry partners, high temperature superconducting (HTS) technology is now at the heart of an advanced degaussing system aboard the USS Higgins at the naval station...

Magnetic Resonance Imaging

From http://www.superconductors.org: An area where superconductors can perform a life-saving function is in the field of biomagnetism. Doctors need a non-invasive means of determining what’s going on inside the human body. By impinging a strong superconductor-derived magnetic field into the body, hydrogen atoms that exist in the body’s water and...

Latest in Ask the Experts

What is the temperature range of cryogenics?

Could you please tell me what is the temperature range of cryogenics? In other words, is -100°F considered cryogenic, or does it start lower? Could I expect to see some extended life in D2 stamping dies? What would the recipe be to achieve the desired results using cryogenics?