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Archive for the ‘quantum physics’ category: Page 57

Aug 1, 2024

A higher-dimensional model can help explain cosmic acceleration without dark energy

Posted by in categories: cosmology, information science, quantum physics

Dark energy remains among the greatest puzzles in our understanding of the cosmos. In the standard model of cosmology called the Lambda-CDM, it is accounted for by adding a cosmological constant term in Einstein’s field equation first introduced by Einstein himself. This constant is very small and positive and lacks a complete theoretical understanding of why it has such a tiny value. Moreover, dark energy has some peculiar features, such as negative pressure and does not dilute with cosmic expansion, which makes at least some of us uncomfortable.

Aug 1, 2024

Mind-Bending Discovery: Neutrons Defy Classical Physics in Astonishing Experiment

Posted by in categories: particle physics, quantum physics

Is nature really as strange as quantum theory says — or are there simpler explanations? Neutron measurements prove: It doesn’t work without the strange properties of quantum theory.

Quantum theory allows particles to exist in superposition states, defying classical realism. The Leggett-Garg inequality tests this by comparing quantum behavior against classical expectations. Recent neutron beam experiments at TU Wien confirmed that particles do violate this inequality, reinforcing the validity of quantum theory over classical explanations.

Jul 31, 2024

Researchers identify unique phenomenon in Kagome metal

Posted by in categories: nanotechnology, quantum physics

In traditional Japanese basket-weaving, the ancient “Kagome” design seen in many handcrafted creations is characterized by a symmetrical pattern of interlaced triangles with shared corners. In quantum physics, the Kagome name has been borrowed by scientists to describe a class of materials with an atomic structure closely resembling this distinctive lattice pattern.

Since the latest family of Kagome metals was discovered in 2019, physicists have been working to better understand their properties and potential applications. A new study led by Florida State University Assistant Professor of Physics Guangxin Ni focuses on how a particular Kagome metal interacts with light to generate what are known as plasmon polaritons — nanoscale-level linked waves of electrons and electromagnetic fields in a material, typically caused by light or other electromagnetic waves.

The work was published in Nature Communications (“Plasmons in the Kagome metal CsV 3 Sb 5 ”).

Jul 31, 2024

Layered superconductor coaxed to show unusual properties with potential for quantum computing

Posted by in categories: computing, quantum physics

A team led by researchers from the California NanoSystems Institute at UCLA has designed a unique material based on a conventional superconductor—that is, a substance that enables electrons to travel through it with zero resistance under certain conditions, such as extremely low temperature. The experimental material showed properties signaling its potential for use in quantum computing, a developing technology with capabilities beyond those of classical digital computers.

Jul 31, 2024

Bright prospects for engineering quantum light

Posted by in categories: computing, engineering, internet, quantum physics

Exploring the design of efficient quantum emitters using defects in wide-bandgap semiconductors, specifically silicon carbide (SiC) and diamond.

It highlights how these defects can be engineered to emit single photons, which are crucial for quantum technologies like secure communication and quantum…


Computers benefit greatly from being connected to the internet, so we might ask: What good is a quantum computer without a quantum internet?

Jul 31, 2024

Physicists Design Better Optical Fibers For Quantum Computing

Posted by in categories: computing, quantum physics

Physicists have developed new specialty optical fibers with a micro-structured core to support future quantum computing data transfer needs.

Jul 30, 2024

Quantum Physics Has Reopened Zeno’s Paradoxes

Posted by in category: quantum physics

For thousands of years, scholars pondered the question of how anything can move in our world. The problem seemed to have been solved—until the development of quantum mechanics.

By Manon Bischoff

Jul 30, 2024

Faster Than a Speeding Photon: How Tachyons Challenge Modern Physics

Posted by in categories: particle physics, quantum physics

Recent advancements in tachyon theory have addressed past inconsistencies by incorporating both past and future states into the boundary conditions, leading to a new quantum entanglement theory and suggesting a critical role for tachyons in matter formation.

Tachyons are hypothetical particles that travel at speeds greater than the speed of light. These superluminal particles, are the “enfant terrible” of modern physics. Until recently, they were generally regarded as entities that did not fit into the special theory of relativity. However, a paper just published by physicists from the University of Warsaw and the University of Oxford has shown that many of these prejudices were unfounded. Tachyons are not only not ruled out by the theory, but allow us to understand its causal structure better.

Superluminal Motion and Tachyons.

Jul 29, 2024

Quantum dance of entangled photons captured in real-time

Posted by in categories: particle physics, quantum physics

The captivating world of quantum mechanics is constantly evolving, revealing complexities that challenge our perception of reality. Recent advancements illuminate the puzzling wave functions of entangled photons, providing remarkable insights into the behavior of these fundamental particles.

At the forefront of this research are experts from the University of Ottawa and Sapienza University of Rome. Their innovative approach allows for real-time visualization of entangled photon wave functions, pushing the boundaries of what we thought possible in quantum science.

Quantum entanglement is a mind-boggling phenomenon that underscores the profound interconnectedness of two particles.

Jul 29, 2024

Researchers achieve quantum breakthrough with novel quantum-to-quantum Bernoulli factory design

Posted by in categories: computing, quantum physics

Unlike classical computers, which use bits to process information as either 0s or 1s, quantum computers use quantum bits, also known as qubits, which can represent and process both 0 and 1 simultaneously thanks to a quantum property called superposition. This fundamental difference gives quantum computers the potential to solve some complex problems much more efficiently than classical computers.

INL researcher Ernesto Galvão, in collaboration with Sapienza Università di Roma (Rome) and Istituto di Fotonica e Nanotecnologie (Milan), recently published a groundbreaking study in the journal Science Advances (“Polarization-encoded photonic quantum-to-quantum Bernoulli factory based on a quantum dot source”), where they describe a new set-up for a quantum-to-quantum Bernoulli factory.

A Bernoulli factory is a method to manipulate randomness, using as inputs random coin flips with a certain probability distribution, and outputting coin flips with a different, desired distribution.

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