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Artificial Intelligence News -- ScienceDaily

Quantum mechanics once baffled scientists. Now it's changing the world Millions of exploding stars could soon reveal dark energy's secrets SpaceX wants to build AI data centers in space. Will it work? A classic brain test exposed AI's biggest weakness Scientists are seriously asking if bees and ChatGPT are conscious Forget electrons, this breakthrough uses light-matter particles to power AI NASA’s new AI space chip could let spacecraft think for themselves New quantum algorithm solves “impossible” materials problem in seconds Your “um” and pauses could reveal early dementia risk AI lets chemists design molecules by simply describing them This AI knew the answers but didn’t understand the questions AI swarms could hijack democracy without anyone noticing Think AI "knows" what it’s doing? Scientists say think again Artificial neurons successfully communicate with living brain cells Quantum AI just got shockingly good at predicting chaos This simple change stops robot swarms from getting stuck “Giant superatoms” could finally solve quantum computing’s biggest problem This new chip could slash data center energy waste This new chip survives 1300°F (700°C) and could change AI forever AI breakthrough cuts energy use by 100x while boosting accuracy DNA robots could deliver drugs and hunt viruses inside your body AI-powered robot learns how to harvest tomatoes more efficiently Scientists discover AI can make humans more creative Scientists built the hardest AI test ever and the results are surprising ChatGPT as a therapist? New study reveals serious ethical risks Quantum computer breakthrough tracks qubit fluctuations in real time Brain inspired machines are better at math than expected AI reads brain MRIs in seconds and flags emergencies Scientists create smart synthetic skin that can hide images and change shape A tiny light trap could unlock million qubit quantum computers “Existential risk” – Why scientists are racing to define consciousness NASA’s Perseverance rover completes the first AI-planned drive on Mars Scientists found a way to cool quantum computers using noise AI that talks to itself learns faster and smarter Researchers tested AI against 100,000 humans on creativity The human brain may work more like AI than anyone expected Unbreakable? Researchers warn quantum computers have serious security flaws The breakthrough that makes robot faces feel less creepy This AI spots dangerous blood cells doctors often miss Stanford’s AI spots hidden disease warnings that show up while you sleep Less than a trillionth of a second: Ultrafast UV light could transform communications and imaging Scientists create robots smaller than a grain of salt that can think AI may not need massive training data after all What if AI becomes conscious and we never know This tiny chip could change the future of quantum computing This AI finds simple rules where humans see only chaos Scientists reveal a tiny brain chip that streams thoughts in real time This tiny implant sends secret messages to the brain Scientists uncover the brain’s hidden learning blocks Physicists reveal a new quantum state where electrons run wild A single beam of light runs AI with supercomputer power New prediction breakthrough delivers results shockingly close to reality Artificial neurons that behave like real brain cells Too much screen time may be hurting kids’ hearts Breakthrough optical processor lets AI compute at the speed of light Stanford’s tiny eye chip helps the blind see again AI turns x-rays into time machines for arthritis care Scientists build artificial neurons that work like real ones 90% of science is lost. This new AI just found it
Brain-inspired chip runs near absolute zero and could transform quantum computing
2026-06-12 · via Artificial Intelligence News -- ScienceDaily

Researchers at the University of Hong Kong (HKU) have unveiled a significant advance in cryogenic electronics that could help overcome key challenges in quantum computing and support future deep space missions. The team, from HKU's Department of Electrical and Computer Engineering and the Centre for Advanced Semiconductors and Integrated Circuits (CASIC), developed a programmable neuromorphic hardware platform capable of operating at temperatures near absolute zero.

The research was led by Professor Yuhao Zhang and PhD student Xin Yang. Their work introduces a new method for generating and controlling negative differential resistance (NDR) in industry standard Silicon Carbide (SiC) MOSFETs. Using this approach, the researchers demonstrated for the first time that a single transistor can reproduce the energy efficient "spiking" activity of biological neurons at temperatures as low as 10mK.

Brain-Inspired Hardware for Quantum Computing

Quantum computers depend on sophisticated control electronics to manage qubits, which are highly sensitive and must be kept at millikelvin temperatures. Existing silicon based control systems consume considerable power and produce unwanted heat, making it necessary to position them away from the qubits themselves. That distance creates extensive wiring requirements that can hinder performance and make large scale quantum computers more difficult to build.

"Our work introduces a hardware platform that can be integrated alongside quantum processors," said Professor Zhang. "By using the unique carrier dynamics in silicon carbide, we can create circuits that are thousands of times more energy-efficient than conventional electronics, significantly reducing the thermal load on cryogenic systems."

Silicon Carbide Reveals Unique Cryogenic Behavior

The team found that SiC MOSFETs display a strong "S-shape" NDR effect when cooled below 2K. This behavior is driven by electron-donor impact ionization (EDII). Unlike other technologies that depend on heat generated within a device, the newly observed mechanism arises directly from the material's atomic properties. As a result, it remains highly stable and can be reproduced consistently across different manufacturing batches.

"This is a robust and scalable approach," said Mr. Yang. "Because SiC is already used globally in electric vehicles and power grids, we can leverage existing industrial foundries to manufacture these cryogenic chips on 300-mm wafers."

From Artificial Neurons to Deep Space Missions

The study also demonstrated that these artificial neurons can be linked together, or "cascaded," into larger networks. This capability could enable advanced local data processing at cryogenic temperatures and improve important quantum computing functions such as quantum error correction and real time quantum control.

The potential applications extend well beyond quantum computing. Because the circuits are designed to operate reliably in extremely cold environments, they could also be valuable for deep space exploration. Future systems may be able to function in the harsh conditions found on the Moon's surface or in the distant regions of our solar system.

The findings were published in Nature Communications in a paper titled "Cryogenic neuromorphic circuits using gate-controlled negative differential resistance in silicon carbide."