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Quantum mechanics theory may work without imaginary numbers, new analysis suggests

Physicists from Heinrich Heine University Düsseldorf (HHU) have examined a fundamental property of quantum mechanics in collaboration with the German Aerospace Center (DLR). In an article published in the journal Physical Review Letters, they show that this theory does not necessarily need to be formulated with imaginary numbers—real numbers can, in fact, also be used.

The physical theory of quantum mechanics describes the world of atomic and subatomic particles. Its development began in the 1900s with physicists such as Max Planck, Niels Bohr, Werner Heisenberg and Erwin Schrödinger.

Quantum mechanics can effectively describe phenomena at microscopic scales, including, for example, the diffraction of particles at a double slit —which shows that particles also exhibit wave-like behavior—and the quantum tunneling effect, in which a certain probability exists that particles can penetrate a barrier even if they have insufficient energy to do so. Particularly important phenomena today include entanglement and coherence, which are key for applications such as quantum computers and communication.

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How to create distinguishable states for quantum systems

Researchers around the world are racing to develop new quantum-based systems for sensing, communication, computing, and control that have the promise of outperforming traditional systems. Creating stable, measurable, distinguishable quantum states, which would be the heart of any such system, is a daunting task.

Quantum states possess unique properties that can be exploited for developing novel information processing systems. Two key properties, stability and distinguishability, are hard to achieve, however. Extracting information from a quantum system depends on the distinguishability of quantum states, an intrinsic property associated with a property known as orthogonality. Nevertheless, no two Gaussian states (a widely studied class of quantum states) are orthogonal, and this yields an unavoidable error when attempting to distinguish them.

In addition, present quantum devices tend to remain stable only for a fraction of a second, and require complex protocols to distinguish states. Now, researchers at MIT and the University of Ferrara have found a new approach for creating easily distinguishable states that could help to enable the development of these new quantum-based devices.

Five phases of localization physics observed in a single quantum system

Physicists in China have observed five phases in localization physics within a single quantum system. Using an advanced photonic platform, the team, led by Yucheng Wang and Jingyun Fan at the Southern University of Science and Technology, Shenzhen, has demonstrated that localization physics is likely far richer than physicists anticipated. Their results have been published in Physical Review Letters.

In 1958, American physicist Philip Anderson made the foundational discovery that disordered media are better at trapping waves than orderly lattice structures. Described mathematically by “localization phases,” this phenomenon now underpins our understanding of both condensed matter and wave physics.

So far, theory has distinguished between two distinct localization phases: one exhibiting “extended” states, which support wave transport, and the other associated with “localized” states, which suppress it. Yet through recent theoretical work, physicists uncovered a third distinct phase, named the “critical phase.”

A new way to control tiny quantum light sources by twisting atomically thin layers of hexagonal boron nitride

In a paper published in Science Advances, researchers at the University of Technology Sydney (UTS) in collaboration with the University of Minnesota and Kyung Hee University have found a new way to control quantum light sources, which is one of the key elements needed before quantum technologies can be used reliably in real-world systems.

Lead author Dr. Angus Gale says the research gives scientists a new control mechanism for tiny quantum light sources, bringing them a step closer to being used in practical quantum technologies such as quantum computing, secure communication and ultrasensitive sensing.

“You can measure these quantum emitters and see that they exist, but it’s hard to make them work in practice. This gives us a lever to get closer to that—a step toward the realization of quantum technologies,” said Dr. Gale.

[News] World’s Smallest Semiconductor Nanotube Achieved at 1 Nanometer

A research team led by the The University of Tokyo has fabricated the world’s smallest semiconductor nanotube, according to a study published in the latest issue of Science. Using boron nitride (BN) nanotubes as a template, the researchers successfully synthesized single-walled molybdenum disulfide (MoS₂) nanotubes with a diameter of just 1 nanometer—roughly one hundred-thousandth the width of a human hair.

The achievement not only validates theoretical predictions about the electronic properties of ultrafine materials made decades ago, but also opens new possibilities for the development of next-generation miniaturized electronic devices.

Carbon nanotubes have long attracted attention for their exceptional mechanical and electrical properties. However, slight variations in their atomic structure can significantly alter their conductivity, posing challenges for transistor applications. In contrast, MoS₂ is an intrinsically semiconducting material with promising potential for semiconductor electronics, high-sensitivity sensing, and quantum-scale physics research. Yet producing ultrathin, structurally controlled MoS₂ nanotubes has remained a major challenge, as stability and fabrication complexity increase dramatically as nanotube diameters shrink.

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