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Category: quantum physics

Newly engineered giant superatoms show promise for reliable quantum state transfer

Quantum technologies are systems that leverage quantum mechanical effects to perform computations, share information or perform other functions. These systems rely on quantum states, which need to be reliably transferred and protected against decoherence (i.e., a gradual loss of quantum information).

In recent years, quantum physicists and engineers have introduced so-called giant atoms, artificial structures that behave like enlarged atoms and could be used to develop quantum technologies. In a recent paper published in Physical Review Letters, researchers at Chalmers University of Technology built on this concept and introduced new carefully engineered giant ‘superatoms’ (GSAs), a new type of giant-atom-like structures that could generate entanglement and enable the reliable transfer of quantum states between different such devices.

“Over the past years, there has been growing interest in so-called ‘giant atoms,’ which are quantum emitters that couple to their environment at multiple, spatially separated points,” Lei Du, first author of the paper, told Phys.org.

Integrative quantum chemistry method unlocks secrets of advanced materials

A new computational approach developed at the University of Chicago promises to shed light on some of the world’s most puzzling materials—from high-temperature superconductors to solar cell semiconductors—by uniting two long-divided scientific perspectives.

“For decades, chemists and physicists have used very different lenses to look at materials. What we’ve done now is create a rigorous way to bring those perspectives together,” said senior author Laura Gagliardi, Richard and Kathy Leventhal Professor in the Department of Chemistry and the Pritzker School of Molecular Engineering. “This gives us a new toolkit to understand and eventually design materials with extraordinary properties.”

When it comes to solids, physicists usually think in terms of broad, repeating band structures, while chemists focus on the local behavior of electrons in specific molecules or fragments. But many important materials—such as organic semiconductors, metal–organic frameworks, and strongly correlated oxides—don’t fit neatly into either picture. In these materials, electrons are often thought of as hopping between repeating fragments rather than being distributed across the material.

Scientists Discover How To “Purify” Light, Paving the Way for Faster, More Secure Quantum Technology

University of Iowa scientists have identified a new way to “purify” photons, a development that could improve both the efficiency and security of optical quantum technologies.

The team focused on two persistent problems that stand in the way of producing a reliable stream of single photons, which are essential for photonic quantum computers and secure communication systems. The first issue, known as laser scatter, arises when a laser is aimed at an atom to trigger the release of a photon, the basic unit of light. Although this method successfully generates photons, it can also produce extra, unwanted ones. These additional photons reduce the efficiency of the optical system, similar to how stray electrical currents interfere with electronic circuits.

A second complication comes from the way atoms occasionally respond to laser light. In uncommon cases, an atom releases more than one photon at the same time. When this happens, the precision of the optical circuit suffers because the extra photons disrupt the intended orderly flow of single photons.

How 3 imaginary physics demons tore up the laws of nature

Science has a rich tradition of physics by imagination. From the 16th century, scientists and philosophers have conjured ‘demons’ that test the limits of our strongest theories of reality.

Three stand out today: Laplace’s demon, capable of perfectly predicting the future; Loschmidt’s demon, which could reverse time and violate the second law of thermodynamics; and Maxwell’s demon, which create a working heat engine at no cost.

Though imaginary, these paradoxical beings have pushed physicists towards sharper theories. From quantum theory to thermodynamics, these demons have legacies that we still feel today.

Image: Antonio Sortino

Three thought experiments involving “demons” have haunted physics for centuries. What should we make of them today?

All-optical modulation with single photons using an electron avalanche

For a long time, this has been a major hurdle in optics. Light is an incredible tool for fast, efficient communication and futuristic quantum computers, but it’s notoriously hard to control at such delicate, “single-photon” levels.

Electron avalanche multiplication can enable an all-optical modulator controlled by single photons.

At 92 He is Testing a Mitochondrial Transplant That Could Rewrite Aging | Dr John Cramer

Dr. John Cramer, 92-year-old nuclear physicist, discusses participating in the first mitochondrial transplant trial for aging and his longevity theory.
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Dr. John Cramer is a 92-year-old emeritus professor at the University of Washington who has spent decades researching nuclear physics and quantum mechanics. Now, he’s turned his attention to longevity, and he’s not just theorizing. Dr. Cramer is participating in Mitrix’s groundbreaking mitochondrial transplantation trial, which aims to replace damaged mitochondrial DNA with healthy versions grown in bioreactors.

In this conversation, Dr. Cramer explains why he believes mitochondrial dysfunction is the root cause of aging, not just another hallmark. He discusses how energy depletion cascades into all other aging symptoms, why previous interventions like telomere extension haven’t delivered, and what markers will be tracked throughout his trial. He also shares his personal longevity protocol, including rapamycin, senolytics, and hyperbaric oxygen therapy.

This is one of the first detailed discussions of autologous mitochondrial transplantation for aging in humans.

Continue reading “At 92 He is Testing a Mitochondrial Transplant That Could Rewrite Aging | Dr John Cramer” | >

Caltech Team Sets Record with 6,100-Qubit Array

Quantum computers will need large numbers of qubits to tackle challenging problems in physics, chemistry, and beyond. Unlike classical bits, qubits can exist in two states at once—a phenomenon called superposition. This quirk of quantum physics gives quantum computers the potential to perform certain complex calculations better than their classical counterparts, but it also means the qubits are fragile. To compensate, researchers are building quantum computers with extra, redundant qubits to correct any errors. That is why robust quantum computers will require hundreds of thousands of qubits.

Now, in a step toward this vision, Caltech physicists have created the largest qubit array ever assembled: 6,100 neutral-atom qubits trapped in a grid by lasers. Previous arrays of this kind contained only hundreds of qubits.

This milestone comes amid a rapidly growing race to scale up quantum computers. There are several approaches in development, including those based on superconducting circuits, trapped ions, and neutral atoms, as used in the new study.

The neutral-atom platform shows promise for scaling up quantum computers.

How Bose-Einstein condensates replicate Shapiro steps

The microscopic processes taking place in superconductors are difficult to observe directly. Researchers at the RPTU University of Kaiserslautern-Landau have therefore implemented a quantum simulation of the Josephson effect: They separated two Bose-Einstein condensates (BECs) by means of an extremely thin optical barrier.

The characteristic Shapiro steps were observed in the atomic system. The research was published in the journal Science.

Two superconductors separated by a wafer-thin insulating layer—that’s how simple a Josephson junction looks. But despite its simple structure, it harbors a quantum mechanical effect that is now one of the most important tools of modern technology: Josephson contacts form the heart of many quantum computers and enable high-precision measurements—such as the measurement of very weak magnetic fields.

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