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Archive for the ‘computing’ category: Page 61

Aug 6, 2024

Long-Standing Quantum Problem Finally Solved

Posted by in categories: computing, particle physics, quantum physics

An answer to a decades-old question in the theory of quantum entanglement raises more questions about this quirky phenomenon.

Physicists have a long list of open problems they consider important for advancing the field of quantum information. Problem 5 asks whether a system can exist in its maximally entangled state in a realistic scenario, in which noise is present. Now Julio de Vicente at Carlos III University of Madrid has answered this fundamental quantum question with a definitive “no” [1]. De Vicente says that he hopes his work will “open a new research avenue within entanglement theory.”

From quantum sensors to quantum computers, many technologies require quantum mechanically entangled particles to operate. The properties of such particles are correlated in a way that would not be possible in classical physics. Ideally, for technology applications, these particles should be in the so-called maximally entangled state, one in which all possible measures of entanglement are maximized. Scientists predict that particles can exist in this state in the absence of experimental, environmental, and statistical noise. But it was unclear whether the particles could also exist in a maximally entangled state in real-world scenarios, where noise is unavoidable.

Aug 6, 2024

New light source emits bright, entangled photons for quantum communication

Posted by in categories: computing, particle physics, quantum physics

Imagine the possibility of sending messages that are completely impervious to even the most powerful computers. This is the incredible promise of quantum communication, which harnesses the unique properties of light particles known as photons.

Aug 6, 2024

Unlocking Future Technologies With Magnetic Control of Rare Earth Elements

Posted by in categories: computing, materials

Laser pulses have been shown to adjust the magnetic properties of rare earths by affecting 4f electrons, opening avenues for quicker and more energy-efficient data storage devices.

The special properties of rare earth magnetic materials are due to the electrons in the 4f shell. Until now, the magnetic properties of 4f electrons were considered almost impossible to control. Now, scientists have shown for the first time that laser pulses can influence 4f electrons — and thus change their magnetic properties. The discovery, which was made through experiments at EuXFEL and FLASH, opens up a new way to data storage with rare earth elements.

Breakthrough in Magnetic Properties Control.

Aug 5, 2024

New Quantum Experiments to Test Simulation Hypothesis and its Connection to Consciousness

Posted by in categories: computing, neuroscience, quantum physics, virtual reality

Science: Physicists Will conduct experiments to verify if we live in the real reality or if we live in a virtual reality. In a computer simulation. In a dream. Or if not.


Researchers at California State Polytechnic University (CalPoly), Pomona are carrying out a series of quantum physics experiments expected to provide strong scientific evidence that we live in a computer simulated virtual reality. — PR13031782.

Aug 5, 2024

A Breakthrough on the Edge: One Step Closer to Topological Quantum Computing

Posted by in categories: computing, particle physics, quantum physics

Researchers at the University of Cologne have achieved a significant breakthrough in quantum materials, potentially setting the stage for advancements in topological superconductivity and robust quantum computing / publication in Nature Physics.

A team of experimental physicists led by the University of Cologne have shown that it is possible to create superconducting effects in special materials known for their unique edge-only electrical properties. This discovery provides a new way to explore advanced quantum states that could be crucial for developing stable and efficient quantum computers. Their study, titled ‘Induced superconducting correlations in a quantum anomalous Hall insulator’, has been published in Nature Physics.

Superconductivity is a phenomenon where electricity flows without resistance in certain materials. The quantum anomalous Hall effect is another phenomenon that also causes zero resistance, but with a twist: it is confined to the edges rather than spreading throughout. Theory predicts that a combination of superconductivity and the quantum anomalous Hall effect will give rise to topologically-protected particles called Majorana fermions that will potentially revolutionize future technologies such as quantum computers. Such a combination can be achieved by inducing superconductivity in the edge of a quantum anomalous Hall insulator that is already resistance-free. The resultant chiral Majorana edge state, which is a special type of Majorana fermions, is a key to realizing ‘flying qubits’ (or quantum bits) that are topologically protected.

Aug 5, 2024

Sam Altman’s Brain Chips | Rain Neuromorphic Chips | UAE Funds and US National Security and Q*

Posted by in categories: computing, neuroscience, security

LINKS: https://www.wired.com/story/openai-buy-ai-chips-startup-sam-…i/https:/.

Aug 4, 2024

A strategy to synthesize fin-like metal nanosheets for 2D transistors

Posted by in categories: chemistry, computing

The effective integration of extremely thin insulating layers with two-dimensional (2D) semiconductors could enable the fabrication of 2D transistors with an electrical capacitance comparable to SiO2 with thicknesses below 1-nm. These transistors could, in turn, help to boost the performance and reduce the power consumption of electronic devices.

Researchers at Nankai University in China recently introduced a new strategy to synthesize single-crystalline metal nanosheets that could be easily transferred onto 2D substrates. This strategy, outlined in a paper in Nature Electronics, was successfully used to deposit 2-nm-thick dielectrics based on Al2O3 or HfO2 for highly performing top-gated transistors.

“At the very beginning, we aimed to developing the (CVD) synthetic strategy of 2D Cu2O, which is a p-type high-mobility 2D semiconductor,” Jinxiong Wu, corresponding author of the paper, told Tech Xplore.

Aug 4, 2024

How Your Brain Remembers: How Episodic Memories Form

Posted by in categories: computing, neuroscience

Summary: Researchers developed a computer model that mimics how the hippocampus stores new episodic memories without erasing old ones. This model demonstrates that the CA3 region of the hippocampus serves as an anchor point for memories, allowing efficient storage in surrounding regions.

The findings reveal insights into how the brain organizes personal experiences and maintains stability despite constant updates. The model shows promise for enhancing our understanding of memory retention and cognitive processing.

Aug 3, 2024

Researchers trap atoms, force them to serve as photonic transistors

Posted by in categories: computing, particle physics, quantum physics

This could be the road to quantum computation.


“In contrast, solid-state emitters embedded in a photonic circuit are hardly ‘the same’ due to slightly different surroundings influencing each emitter. It is much harder for many solid-state emitters to build up phase coherence and collectively interact with photons like cold atoms. We could use cold atoms trapped on the circuit to study new collective effects,” Hung continues.

The platform demonstrated in this research could provide a photonic link for future distributed quantum computing based on neutral atoms. It could also serve as a new experimental platform for studying collective light-matter interactions and for synthesizing quantum degenerate trapped gases or ultracold molecules.

Continue reading “Researchers trap atoms, force them to serve as photonic transistors” »

Aug 3, 2024

New transistor’s superlative properties could have broad electronics applications

Posted by in categories: computing, physics

In 2021, a team led by MIT physicists reported creating a new ultrathin ferroelectric material, or one where positive and negative charges separate into different layers. At the time, they noted the material’s potential for applications in computer memory and much more. Now the same core team and colleagues—including two from the lab next door—have built a transistor with that material and shown that its properties are so useful that it could change the world of electronics.

Although the team’s results are based on a single transistor in the lab, “in several aspects its properties already meet or exceed industry standards” for the ferroelectric transistors produced today, says Pablo Jarillo-Herrero, the Cecil and Ida Green Professor of Physics, who led the work with professor of physics Raymond Ashoori. Both are also affiliated with the Materials Research Laboratory.

“In my lab we primarily do . This is one of the first, and perhaps most dramatic, examples of how very basic science has led to something that could have a major impact on applications,” Jarillo-Herrero says.

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