ATLAS Collaboration’s Post

Unlocking the secrets of quasicrystal magnetism: Revealing a novel magnetic phase diagram: Non-Heisenberg-type approximant crystals have many interesting properties and are intriguing for researchers of condensed matter physics. However, their magnetic phase diagrams, which are crucial for realizing their potential, remain completely unknown. Now, a team of researchers has constructed the magnetic phase diagram of a non-Heisenberg Tsai-type 1/1 gold-gallium-terbium approximant crystal. This development marks a significant step forward for quasicrystal research and for the realization of magnetic refrigerators and spintronic devices. #ScienceDaily #Technology

#ScienceDailynews #InnovativeResearch #NextGenScience #ExploringFrontiersUnlocking the secrets of quasicrystal magnetism: Revealing a novel magnetic phase diagram . Non-Heisenberg-type approximant crystals have many interesting properties and are intriguing for researchers of condensed matter physics. However, their magnetic phase diagrams, which are crucial for realizing their potential, remain completely unknown. Now, a team of researchers has constructed the magnetic phase diagram of a non-Heisenberg Tsai-type 1/1 gold-gallium-terbium approximant crystal. This development marks a significant step forward for quasicrystal research and for the realization of magnetic refrigerators and spintronic devices.

Gold has long been a popular way of enhancing the photosensitivity of electronic devices such as biosensors, imaging systems, energy harvesters and information processors. Now researchers have found a way of pushing the efficiency of these devices to the limit using monocrystalline gold, revealing intriguing fundamental physics insights at the same time: https://lnkd.in/d228Mx4g

Non-Heisenberg-type approximant crystals have many interesting properties and are intriguing for researchers of condensed matter physics. However, their magnetic phase diagrams, which are crucial for realizing their potential, remain completely unknown. Now, a team of researchers has constructed the magnetic phase diagram of a non-Heisenberg Tsai-type 1/1 gold-gallium-terbium approximant crystal. This development marks a significant step forward for quasicrystal research and for the realization of magnetic refrigerators and spintronic devices.

Gold has long been used of enhancing the sensitivity to light needed by everything from harvesting renewable energy to the imaging and study of cancer.🔋🏅 Professor Anatoly Zayats and team have found that by using a different crystalline structure of gold, these positive effects can be magnified.🔍 Read the write-up in Physics World below: https://loom.ly/21h3f88

Unlocking the secrets of quasicrystal magnetism: Revealing a novel magnetic phase diagram: Non-Heisenberg-type approximant crystals have many interesting properties and are intriguing for researchers of condensed matter physics. However, their magnetic phase diagrams, which are crucial for realizing their potential, remain completely unknown. Now, a team of researchers has constructed the magnetic phase diagram of a non-Heisenberg Tsai-type 1/1 gold-gallium-terbium approximant crystal. This development marks a significant step forward for quasicrystal research and for the realization of magnetic refrigerators and spintronic devices. @Poseidon-US #ScienceDaily #Technology

physics world explains our recent paper

"High-energy neutrino interactions have been observed within a particle collider for the first time, according to findings detailed in a study that marks an important new milestone in particle physics. Neutrinos are neutral sub-atomic particles that play a significant role in the Standard Model of particle physics. Despite their abundance in the universe, they are sometimes called “ghost particles” given that they seldom interact with matter, making them difficult to detect. For particle physicists, understanding these rare neutrino interactions with other forms of matter is a significant pursuit toward gaining a better understanding of our universe. Such studies may help answer questions like why particles have mass and why there is more matter than antimatter. Now, new research led by professors Akitaka Ariga and Tomoko Ariga that employed the Forward Search Experiment (FASER) at CERN’s Large Hadron Collider (LHC) resulted in the successful detection of electron and muon neutrinos at energy ranges that have never previously been explored."

Article about CF session of physics class In the realm of physics, the BCS theory stands as a cornerstone, revolutionizing our understanding of superconductivity. Proposed by Bardeen, Cooper, and Schrieffer in 1957, this theory elucidates how electrons form pairs and flow without resistance at low temperatures, a phenomenon essential for numerous applications. Superconductors, enabled by BCS theory, play a pivotal role in various fields, from healthcare to energy. Magnetic resonance imaging (MRI) machines, for instance, harness superconducting magnets to produce detailed images of the human body, aiding in medical diagnoses. Similarly, superconducting quantum interference devices (SQUIDs) employ these materials for ultrasensitive magnetic field detection, indispensable in neuroscience research and geological exploration. However, the practical realization of superconductivity often hinges on intricate simulations and computations, a realm where supercomputers shine. These computational behemoths tackle complex equations, modeling the behavior of materials under extreme conditions with unparalleled accuracy and efficiency. In material science, supercomputers facilitate the discovery and optimization of novel superconductors, paving the way for advancements in energy transmission and storage. By simulating the atomic structure and electronic properties of materials, researchers can identify promising candidates for future applications, accelerating the development of sustainable technologies. Moreover, supercomputers play a vital role in simulating the behavior of superconducting devices, optimizing their performance, and predicting potential challenges. From designing more efficient power grids to simulating quantum phenomena, supercomputing enables breakthroughs that were once confined to the realm of theoretical speculation. In essence, the marriage of BCS theory and supercomputing exemplifies the synergy between fundamental physics and cutting-edge technology. As we delve deeper into the mysteries of superconductivity and push the boundaries of computational prowess, we unlock a world of possibilities, where innovation and discovery converge to shape the future of science and technology thank you sir Dr. IMMANUEL PAULRAJ for sharing your knowledge and physics experience with the help of SRIRAM M and so, we had a beautiful opportunity to listen a wonderful class #Effectivelearning #snsct #snsinstitutions #snsdesignthinker #snsdesignthinking

In an innovative approach to controlling #ultrashort# laser #flashes, researchers from the Universities of #Bayreuth and #Konstanz are using soliton physics and two pulse combs within a single laser. The method has the potential to drastically speed up and simplify laser applications. The results of the research have now been published in Science Advances. https://lnkd.in/es4FTBm6