Tag Archives: superconductors

Germanium Superconductors: A Key to Reliable Quantum Computing

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Germanium is already utilized in standard computer chips

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Superconductors made from germanium, a material traditionally used for computer chips, have the potential to revolutionize quantum computing by enhancing reliability and performance in the future.

Superconductors are materials that enable electricity to flow without resistance, making them ideal for various electrical applications, particularly in maintaining quantum coherence—essential for effective quantum computing.

Nonetheless, most superconductors have been specialized materials that are challenging to incorporate into computer chips. Peter Jacobson and his team at the University of Queensland, Australia, successfully developed a superconductor using germanium, a material already prevalent in the computing sector.

The researchers synthesized the superconductor by introducing gallium into a germanium film through a process called doping. Previous experiments in this area found instability in the resulting combination. To overcome this, the team utilized X-rays to infuse additional gallium into the material, achieving a stable and uniform structure.

However, similar to other known superconductors, this novel material requires cooling to a frigid 3.5 Kelvin (-270°C/-453°F) to function.

David Cardwell, a professor at the University of Cambridge, notes that while superconductors demand extremely low temperatures, making them less suitable for consumer devices, they could be ideally suited for quantum computing, which also necessitates supercooling.

“This could significantly impact quantum technology,” says Cardwell. “We’re already in a very cold environment, so this opens up a new level of functionality. I believe this is a clear starting point.”

Jacobson highlighted that previous attempts to stack superconductors atop semiconductors—critical components in computing—resulted in defects within their crystal structure, posing challenges for practical applications. “Disorder in quantum technology acts as a detrimental effect,” he states. “It absorbs the signal.”

In contrast, this innovative material enables the stacking of layers containing gallium-doped germanium and silicon while maintaining a uniform crystal structure, potentially paving the way for chips that combine the advantageous features of both semiconductors and superconductors.

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Source: www.newscientist.com

Physicists Uncover Unusual Quantum Echoes in Niobium Superconductors

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Researchers from Ames National Laboratory and Iowa State University have unveiled the emergence of Higgs echoes in niobium superconductors. These findings shed light on quantum behavior that could influence the development of next-generation quantum sensing and computing technologies.

Using Higgs Echo Spectroscopy, Huang et al reveal unconventional echo formation due to non-uniform expansion and soft quasiparticle bands, dynamically evolving under THZ drive. Image credit: Ames National Laboratory.

Superconductors are materials known for conducting electricity without resistance.

These superconducting materials exhibit collective oscillations referred to as the Higgs mode.

The Higgs mode represents a quantum phenomenon that occurs when the electronic potential fluctuates similarly to a Higgs boson.

Such modes manifest when the material experiences a superconducting phase transition.

Monitoring these vibrations has posed challenges for scientists for many years.

Additionally, they interact complexly with quasiparticles, which are electron-like excitations arising from superconducting dynamics.

By utilizing advanced terahertz (THZ) spectroscopy, the researchers identified a new type of quantum echo known as Higgs echo in superconductive niobium materials utilized in quantum computing circuits.

“Unlike traditional echoes seen in atoms and semiconductors, Higgs echoes result from intricate interactions between Higgs modes and quasiparticles, generating anomalous signals with unique properties.”

“Higgs echoes can uncover and reveal hidden quantum pathways within a material.”

By employing precisely-timed THZ radiation pulses, the authors were able to detect these echoes.

These THZ radiation pulses can also facilitate the encoding, storage, and retrieval of quantum information embedded in the superconducting material via echoes.

This study illustrates the ability to manipulate and observe the quantum coherence of superconductors, paving the way for innovative methods of storing and processing quantum information.

“Grasping and controlling these distinctive quantum echoes brings us closer to practical quantum computing and advanced quantum sensing technologies,” stated Dr. Wang.

a paper detailing these findings was published in the journal on June 25th in Advances in Science.

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Chuankun Huang et al. 2025. Discovery of unconventional quantum echoes due to Higgs coherence interference. Advances in Science 11 (26); doi:10.1126/sciadv.ads8740

Source: www.sci.news