New research on classical telegraph equation published in Spixiana

Electrons that act like photons reveal a quantum secret: Quantum materials, defined by their photon-like electrons, are opening new frontiers in material science. Researchers have synthesized organic compounds that display a universal magnetic behavior tied to a distinctive feature in their band structures called linear band dispersion. This discovery not only deepens the theoretical understanding of quantum systems but also points toward revolutionary applications in next-generation information and communication technologies that conventional materials cannot achieve. #ScienceDaily #Technology

Recent research published in the Journal of Chemical Theory and Computation introduces a hierarchy of first-principles simulations for molecular polariton dynamics, examining whether electromagnetic fields should be treated classically or quantum mechanically. The study demonstrates that quantum entanglement between photons and molecules emerges only when the electromagnetic field is treated quantum-mechanically, revealing behaviors not captured by classical approaches. This work provides a conceptual framework for experimentalists and advances our understanding of light–matter interactions, with implications for controlling molecular behavior in future quantum technologies. The methodology leverages time-dependent density functional theory and explores both electronic and vibrational energy scales.

Exploring the Physics and Chemistry of Rare Earths Handbook 1) Rare earth elements (REEs) are crucial for modern technology, playing a key role in devices like smartphones and wind turbines. 2) There are 17 rare earth elements, including 15 lanthanides, scandium, and yttrium, known for their unique magnetic and optical properties. 3) Yttrium, discovered in 1787, was the first rare earth element, and these elements gained practical importance in the mid-20th century. 4) Neodymium magnets, vital for electric vehicles and wind turbines, exemplify the strong magnetic properties of rare earth elements. 5) Europium and terbium's optical properties enable them to emit specific light wavelengths, crucial for LED displays and lighting. 6) Gadolinium's paramagnetic properties make it a valuable contrast agent in MRI procedures, highlighting the medical applications of REEs. 7) REEs primarily exist in a +3 oxidation state but can form other states, such as cerium, which is key in catalytic converters. 8) The separation and purification of REEs are challenging due to similar chemical properties, driving innovation in extraction methods. 9) REEs form complex compounds used in industrial processes, such as petroleum refining, underscoring their diverse applications. 10) Understanding the chemistry and physics of REEs provides a competitive advantage in the natural resources sector. https://lnkd.in/ePveAHYc

Recent research reveals that ordinary ice, when stressed through bending, stretching, or twisting, can generate electricity due to flexoelectricity. The study, led by nanophysicist Xin Wen from Institut Catala de Nanociencia i Nanotecnologia, highlights that ice's electric properties vary with temperature and could generate electricity through ferroelectricity at low temperatures. This discovery aligns with natural phenomena like thunderstorms, providing insights into ice particle interactions. Further studies are needed, but this finding could redefine ice as an active material in science and technology. #Physics #Science #Research https://lnkd.in/gHwBB3cj

My independent research has been published in Journal of Computational Electronics. Link: https://lnkd.in/gAXWzmbn Full-text (view only): https://rdcu.be/eGzbZ Expressing quantum mechanics in phase space through the Wigner–Moyal equation yields a remarkably intuitive form: the classical Boltzmann transport equation with an infinite series of nonlinear quantum corrections. This attractive formulation has long been known (1949~) and widely used, particularly for deriving quantum correction models in nanoscale devices. Yet, ironically, directly solving the Wigner–Moyal equation for arbitrary potentials has also been regarded as numerically unstable and essentially unusable. I showed that the long-standing instability of the Wigner–Moyal equation arises from unbounded quantum nonlocality at microscopic scales, and that this can be bounded by the uncertainty limit through a numerical observer effect—proposing, for the first time, a stable method to solve it for arbitrary potential profiles. This opens a new path for stable quantum transport simulations bridging classical and quantum dynamics, while the ability of the observer effect to tune nonlocality points to phenomena beyond intrinsic quantum mechanics.

👋Particle Entanglement Advancement👋 Molecular Audio Canada's successful research findings demonstrate high-quality particle entanglement across diverse waveforms underscores the critical need for prioritizing measurement determination. Addressing the measurement problem is paramount for enabling scientific mapping of the causal chain. A novel approach to Thomas Young's Modulus showcases the capacity to generate particle entanglement fields with predictive mathematical controls and physically measurable customizations. Analysis indicates that human observers perceive the wave function collapse as the "Effect" when measurements are taken, rather than the cause of the collapse. Further insights on this matter are available. Echoing Roger Penrose's perspective on the physics underlying "wave function collapse," the developed modulus exhibits a behavioral paradigm that aligns with Penrose's theory.

🚨 Physicists Just Discovered a New Phase of Matter! In a groundbreaking study, researchers at Rutgers University have uncovered a brand-new phase of matter at the interface of two exotic materials: a Weyl semimetal and a magnetic material known as spin ice. When combined under ultra-strong magnetic fields, the boundary between these materials revealed a never-before-seen state called a quantum liquid crystal. Unlike ordinary matter, where electrons move symmetrically, in this strange state electrons flow in six distinct directions—breaking the expected rules of symmetry. This phenomenon, known as electronic anisotropy, could mark the beginning of an entirely new field of quantum materials research. Scientists believe this discovery may lead to ultra-sensitive quantum sensors, capable of working in extreme conditions such as deep space exploration or inside powerful scientific machines. Using custom nanostructures and experiments at the National High Magnetic Field Laboratory, the Rutgers team demonstrated that when two unusual materials interact, they can give rise to quantum behaviors that don’t exist in either material alone. As lead author Tsung-Chi Wu notes: “This is just the beginning.” Future research may unlock technologies based on matter that behaves in ways nature itself never intended. 📖 Source: Wu, T.-C., et al. Electronic anisotropy and rotational symmetry breaking at a Weyl semimetal/spin ice interface. Science Advances, June 13, 2025. #QuantumPhysics #NewPhaseOfMatter #WeylSemimetal #SpinIce #QuantumLiquidCrystal #ScienceNews #PhysicsBreakthrough #QuantumMaterials #Nanotechnology

“Heavy” Electrons Hold the Key to a New Type of Quantum Computer A research team from The University of Osaka has uncovered that “heavy fermions”—electrons with a dramatically increased effective mass—exhibit quantum entanglement governed by Planckian time in the compound Cerium‑Rhodium‑Tin (CeRhSn). This quasi‑kagome Kondo lattice material demonstrates non‑Fermi liquid behavior nearly up to room temperature, and heavy electron lifetimes approach the fundamental Planckian limit. The findings, reported in npj Quantum Materials, highlight anisotropic dynamical Planckian scaling in the Drude response below 80 K in the Ce quasi‑kagome plane, signaling quantum criticality tied to strong conduction–f‑electron hybridization . This discovery opens exciting possibilities for manipulating entanglement in solid‑state materials and designing novel quantum computing architectures based on Planckian‑time–controlled heavy fermions. Full research article: Anisotropic non‑Fermi liquid and dynamical Planckian scaling of a quasi‑kagome Kondo lattice system, published 5 August 2025 in npj Quantum Materials (Vol. 10, Article 85), DOI: 10.1038/s41535‑025‑00797‑w . #QuantumComputing #QuantumPhysics #HeavyFermions #PlanckianTime #QuantumEntanglement #CondensedMatterPhysics #QuantumTechnology #CeRhSn #NextGenComputing #PhysicsResearch #QuantumMaterials

Recent advances in quantum materials research have extended the Středa formula to non-equilibrium, periodically driven systems, revealing a universal, quantized magnetic response rooted in topology. By applying Cesàro summation, researchers demonstrated that what appears as a trivial sum of zeros actually encodes robust bulk magnetization and edge phenomena unique to Floquet systems. This approach resolves longstanding theoretical challenges and suggests new experimental strategies, such as particle-density measurements, to detect these effects even in disordered materials. The findings offer a framework for classifying nonequilibrium phases and investigating energy exchange in driven quantum systems.

🥳 Big news! My first research paper on multimode photon-photon interaction is finally out on arXiv!!! This has been one of the greatest experiences of my life so far. When I first entered this field, I was completely unaware of how deep and beautiful it truly is. Over time, I built up my knowledge in microwave engineering, quantum circuits, classical Lagrangian formulations, and quantum models all just to understand how such circuits behave. Working alongside an IIT professor and a PhD student, I experienced what real research feels like rigorous, relentless, but immensely rewarding. These 1.5 years of work felt like living as a midnight owl, burning through equations, simulations, and ideas. And in the end, it all came together in this paper. What makes this moment special to me is not just the publication, but the journey. Before this, I was working alone in quantum chaos, facing a simulation error I couldn’t solve for months. In that phase, I reached out to professors and professionals worldwide, hoping for guidance. Most never replied and I don’t blame them, they’re busy. But that experience taught me something powerful: even the smallest insight from a senior can change the direction of a young researcher’s path. If you can help someone younger, even with one line of advice, please do it. You never know what spark you might light. Eventually, I found the right mentors who recognized my curiosity and gave me an opportunity. And here I am today contributing to the literature of one of my favorite fields in all of physics: quantum physics. This is just the beginning. I wish to continue publishing, to push boundaries, and to contribute work that truly makes an impact. And I hope my story inspires others my age if you have ideas, skills, or even just curiosity, put it out into the world. Start somewhere. You never know where it might take you. #QuantumPhysics   #QuantumComputing   #ResearchJourney   #AcademicLife   #Innovation   #Technology   #STEM   #Science   #EarlyCareerResearch   #InspireYoungMinds #IITBHU #GCIS https://lnkd.in/gpcUZ9wE