Quantum Days’ Post

We are leading a new £58.8 million project that will unlock new secrets of the world’s smallest particles. Announced by UK Research and Innovation, the funding is part of a £473 million investment in new infrastructure for UK science and innovation. The project will enable researchers to study quarks and gluons inside polarised protons as well as inside protons and neutrons combined in larger atomic nuclei to better understand their properties. Working with the US, these discoveries could lead to technological breakthroughs in other areas of science and medicine. The UK-US collaboration will see new detector and accelerator infrastructure installed at the Electron-Ion Collider (EIC), a major new particle accelerator facility at the Brookhaven National Laboratory in the United States. Explore how this collaboration will change science and technology by following the link: https://lnkd.in/eEMsmm4e #ParticlePhysics #ScientificResearch #Innovation #UKResearchandInnovation #UKScience #ParticleAccelerator #TechnologicalBreakthroughs

**The World of Synchrotron Radiation Research: Illuminating the Hidden Dimensions** Synchrotron radiation, a phenomenon discovered in the 1940s, is now a cornerstone in advanced scientific research. This highly collimated beam of light produced by synchrotrons, powerful circular accelerators, enables scientists to probe materials at atomic resolutions. Recent breakthroughs include using synchrotron radiation to visualize protein dynamics in real-time, enhancing drug discovery processes. Moreover, its application in materials science has led to innovations in energy storage technologies, such as more efficient batteries. This field exemplifies how synchrotron radiation's precision can unlock complex biological and material structures, bridging theoretical research with practical technological advancements. #SynchrotronResearch #AdvancedScience #MaterialInnovation

On July 2, 1940, a groundbreaking patent was granted to the legendary physicist Enrico Fermi and his team for their work in producing isotopes through neutron reactions. This innovation paved the way for advancements in various fields, including medicine and energy. Celebrate this historic achievement and discover how isotope production services can benefit your research or industry with cutting-edge technology. Learn more about our IRP services today! 👉Visit us: www.4aipsolution.in 📩contact@4aipsolution.in 👉Follow us on: https://lnkd.in/enCeJBi3 https://lnkd.in/eKyRDCvg https://lnkd.in/gdzyc5_M . . #Innovation #Science #Research #IRPServices #Isotopes #EnricoFermi #NeutronReactions #TechAdvancement #PatentHistory #EnricoFermi #IsotopeProduction #NeutronReactions #MedicalAdvancements #EnergyInnovation #GroundbreakingResearch #HistoricAchievement #ScientificInnovation #CuttingEdgeTechnology #ResearchBenefits #IndustryInnovation #IPRServices #TechnologyAdvancement #CelebrateInnovation

This photo is spectacular. It portrays a true dream team. I would like to know if there is a photo like this with contemporary scientists (with a capital "S"). I doubt it has the same relevance as this one. If you take a look at my LinkedIn profile, you will see that Mme Curie is my inspiration to be a better professional. I hope that my granddaughters have the opportunity to see, at the end of this century, an old photo with great Scientists, but with many more women than this one. #science #innovation #scientists

Thanks to NV-diamond and QT: Terahertz-Lasers approach Recently a major news was published by Science Advances (29 May 2024, Vol 10, Issue 22,DOI: 10.1126/sciadv.adn0616, “Terahertz Emission from Diamond Nitrogen-Vacancy Centers”), where S. Kollaric et al. report about the realization of a Terahertz Laser based on NV centers in diamond. Terahertz radiation has unique penetrating properties that make it highly attractive for spectroscopy and imaging applications across a wide variety of fields (medical science, biology, security, astronomy, pharmaceutical, materials science, physics ...). The authors demonstrate the generation of terahertz radiation using nitrogen-vacancy centers in a diamond single crystal. Population inversion is achieved, showing phonon-mediated relaxation as dominant recombination process. The terahertz radiation is tunable by variation of the applied magnetic field. These findings will lead to the next generation of tunable coherent terahertz sources.

Proposition de doctorat IM2NP CNRS UMR 7334 Giant interband transition nanostructures: Optical and optoelectronic properties and application in photodetection

ZPC's CTO and University of Alberta Professor Dr. John P Davis will be giving an invited talk at #PhotonicsNorth about ''Yttrium iron garnet photonic crystals for cavity magnomechanics.'' Photonics North is at the Vancouver Convention Centre from May 28-30 and aims to strengthen the connections between theory and application and build stronger ties between university research and industry needs. Are you going to be at #Photonics North? #Photonics #Science #MadeInCanada 🍁

Scouting state-of-the-art research infrastructure in Japan This Tuesday marks the start of the J-PARC Symposium 2024 in Mito, just northeast of Tokyo. It also marks the start of four interesting days for Jacob Becker-Christensen, CEO of LINX, who is there to learn about the capabilities of a state-of-the-art research infrastructure: Japan's great spallation neutron source. The symposium is organized by J-PARC, the Japan Proton Accelerator Research Complex, which operates the Japanese spallation neutron source (JSNS). This machine is much like the European Spallation Source ERIC, ESS, which is currently being built right on Denmark’s doorstep in Lund (Sweden). As such the symposium is an ideal scouting opportunity of future industry opportunities much closer to home. The event brings together researchers and experts from around the globe to discuss groundbreaking research and innovations reached via neutron-based analysis techniques. The scope ranges from materials science, chemistry and nanoscience to hardcore particle physics. One key aspect is interdisciplinarity, covering research in fields such as medical technology and energy systems. Additionally, the symposium includes social activities to foster networking and partnerships between participants. It usually gathers 200-300 attendees from across the world. But first Jacob attends the Welcome Reception, held in the afternoon on Monday at the grand music hall in Mito, the venue of the symposium. Beautiful surroundings for a feast of science and innovation. #JParc2024 #Innovation #Neutron #Materialevidenskab #Teknologi #GrønOmstilling #Japan #science, #materialscience #industry, #partnerships #Mito

Phys.org: How does light interact with matter at extreme intensities, near the Schwinger limit? Researchers at LIDYL, CEA, CNRS, UPC proposed a realistic method to reach unprecedented intensities in experimental settings. https://lnkd.in/enR5gKes

Our paper on the observation of vortices in a dipolar supersolid is now out on Nature Magazine 🎉🎉 Go check it out!