The CERN Accelerator School - CAS, in collaboration with ALBA Synchrotron, presents the “Introduction to Accelerator Physics” course, an opportunity to learn more about #AcceleratorPhysics and connect with colleagues in the field.
This course is designed for laboratory and university staff and students, as well as manufacturers of accelerator equipment.
📅 22 September – 5 October 2024
ℹ️ Early applicants will be given priority.
🔗 Find out more and register: https://cas.web.cern.ch
Just back in Stockholm from an incredible experience at EUCAS23 conference in Bologna!
During this event I had the opportunity to meet researchers from all around the world, a few of which I had already met in previous conferences/ summer schools and working experiences. It was, without a doubt, the largest event of this kind I've ever attended, offering an enlightening overview on research fields closely related to mine and their applications to shape the future of superconductive technology: from quantum computing and cutting-edge material science, to the developments magnets for accelerators and fusion reactors.
In the photo below, here am I, in front of my conference poster showing part of my research at Stockholm University. The topic I presented is a preliminary study on how the synchronization of up to a thousand of superconducting microscopic devices, Josephson junctions, can be exploited to make a coherent, efficient and tunable source of high frequency microwaves / THz radiation.
If you are interested to know more about this topic, you can find here the full paper summarized in the poster. https://lnkd.in/dfXTWuMq
Let's be honest, it's hard not to be awestruck by a massive, precision-engineered, particle accelerator that is unlocking the secrets of matter by smashing protons together at relativistic speeds!
This week I had the opportunity to visit one of the wonders of the modern world at CERN with a delegation from Ireland. As Ireland's submission for associate membership to CERN is in progress, we came to Geneva to gain a deeper understanding of how Ireland might best benefit from, and contribute to, this remarkable facility.
The scale, ingenuity and precision of the engineering and physics at CERN are mind-blowing. As the collider is currently offline, it afforded us the rare privilege of visiting the detector 100M below ground.
The LHC (Large Hadron Collider) has a circumference of approx. 27Km and thousands of powerful, supercooled magnets that contain two accelerating beams of protons (going in opposite directions) at very nearly the speed of light. Once they are up to full speed the beams are nudged, ever so slightly, until they collide at the exact location of a sophisticated suite of sensors. The sensors gather incredible amounts of data in fractions of a second that allow physicists to unpack the exact composition of the subatomic particles created by the collision.
The visionary and long-term thinking at CERN is truly inspiring. Not content with the current speed of 99.9999991% the speed of light, the team at CERN are already shaping a future vision with a new accelerator ring of up to 100Km in circumference that will deliver vastly more energy and should help unlock even more new physics and increase our understanding of the universe.
Many thanks to our hosts at CERN who gave so generously of their time to host an Irish delegation of university leadership, researchers, government representatives and ambassadors. A special thanks to my researcher travelling companions for helping me to brush up on my very rusty particle physics.
#CERN#science#technology#Physics#irishresearch.
Science Foundation IrelandDepartment of Further and Higher Education, Research, Innovation and ScienceUCD ResearchUniversity of LimerickTrinity College DublinDublin Institute for Advanced StudiesOrla FeelyHEAnetAoife McGarryDepartment of Foreign Affairs, Ireland
Edoardo Baldini, assistant professor in the Department of Physics at The University of Texas at Austin, has been honored with an Air Force Office of Scientific Research (AFOSR) Young Investigator Program (YIP) award for his proposal “Terahertz-speed manipulation of two-dimensional ferroelectricity.”
For this project, he will use advanced laser techniques to explore the fundamental physics of quantum materials, solids that host quantum mechanical phenomena over a wide range of energy and length scales. The research will specifically focus on the class of two-dimensional van der Waals ferroelectrics, which have recently emerged as promising candidates for cutting-edge electronic, spintronic, and sensing devices. Future progress in using these technologies rests on the ability to manipulate ferroelectricity at terahertz speeds and understand its underlying microscopic interactions.
#research#innovation#quantum
🔬 Join Us for an Engaging Scientific Talk! 🌟
We are excited to invite you to the upcoming SFB Colloquium featuring Prof. Dr. Tobias Stauber from the Instituto de Ciencia de Materiales de Madrid.
🗓️ Date: Tuesday, 02.07.2024
⏰ Time: 14:15
🏢 Location: H34
Prof. Stauber will be presenting on the compelling topic of "Nematic versus Triplet Superconductivity in Twisted Bilayer Graphene."
Be part of an enlightening session where we explore the phase diagrams of realistic moiré systems, starting from a microscopic tight-binding model for twisted bilayer graphene within the Hartree-Fock approximation. The talk will cover the emergent U(4)-ferromagnet, the symmetry-breaking in real samples, and how this affects the asymmetry between the superconducting phases for electron and hole doping. Additionally, the discussion will extend to the theory of Ising superconductivity in twisted trilayer graphene and how real-space chirality can be measured in linear transport experiments.
This is a fantastic opportunity for anyone interested in cutting-edge research in condensed matter physics and materials science.
#CondensedMatterPhysics#TwistedBilayerGraphene#NematicSuperconductivity#TripletSuperconductivity#MoiréSystems#MaterialsScience#ScientificResearch#PhysicsTalk#Colloquium#SFB1277
See you there! 🚀
Science is magic explained it is said.
Dr. Rolf-Dieter Heuer is a German physicist who served as Director-General of CERN from 2009 to 2015. He played a key role in the Higgs boson discovery through his leadership, overseeing the LHC. Dr. Heuer's strategic decisions and advocacy for the LHC were crucial in achieving this milestone in physics
Why do we need to measure Higgs? (Higgs Boson particle)asked an Inventure student.
CMS physicists recently measured the mass of the Higgs boson to be 125.35 GeV with a precision of 0.15 GeV, an uncertainty of roughly 0.1%.
This new precise measurement of the Higgs boson’s mass will not, at least not on its own, lead us in a new direction of physics. But it does add another piece to the puzzle of the exciting world of subatomic particles, and its connection to the world around us. The Higgs boson mass is an unrestricted parameter in the physics theory describing subatomic particles called the Standard Model, and the value of the Higgs boson mass is connected to understanding the long-term stability of the universe. Its precise knowledge is needed to estimate many of the properties of the Higgs boson and the phenomena that we can observe at future colliders.
The Nobel Prize in Physics for the discovery of the Higgs boson at CERN was awarded in 2013 to Peter Higgs and François Englert.
We are thrilled at the exposure our students are getting at CERN and feel confident to ask questions of renowned scientists to understand the magic behind science.
#STEM#LearningForLife#WeBuildTheFuture#FitForLife#TheInventureAdvantage#NewWorld#NewLearning#CarpeDiemCERNLavanya Srinivas
[IRIG NEWS] 💥 Visit of Vice President for Higher Education, Research and Innovation of the Auvergne-Rhône-Alpes Region
Catherine Staron visited CEA-Irig accompanied by Jérôme Fraysse (Deputy Director at DESRI) and Gabriele Fioni (Rector for Higher Education Research and Innovation).
🚩 The opportunity to find out more about CEA-Irig research activities and the challenges of innovation in the following programmes :
👉 spintronics for frugal digital technology at SPINTEC with a focus on neuromorphic computing and innovative memory activities and the Nellow start-up project (Lucian Prejbeanu and Jean-Philippe Attané)
👉 quantum technologies with a focus on the semiconductor qubit sector at PHELIQS (Silvano De Franceschi)
👉 personalised medicine with a focus on organoids-on-chips CEA-Irig /BGE/ Biomics (Xavier Gidrol and Emily Tubbs)
Lire aussi https://lnkd.in/eduAXS_r#Research#innovation#physics#lifesciences
CERN develops pioneering #technology and expertise with the potential of applications in many areas beyond particle physics.
For this, the Laboratory builds its expertise broadly on 3️⃣ technical fields: accelerators, detectors and computing.
🤝 Behind these three pillars of technology lie many threads of technology and human expertise that translate into the acceleration of innovation in industry and the maximisation of the global positive #impact of CERN across industries by liaising with different actors in its ecosystem.
Can you name one of the impact areas deriving from CERN’s three pillars of technology?
🎄 Comment below!
#HolidaySeason#AdventCalendar#innovation#technologies#sustainability
This week, starting May 8th I'll be attending the #QuantumMatter2024 conference in San Sebastián, organized by Donostia International Physics Center (DIPC), Phantoms Foundation, CSIC, and Institut Català de Nanociència i Nanotecnologia (ICN2).
If you're attending, come by our poster (#120) to discuss about fully quantum models, hybrid models, and classical model implementation for image classification exciting research and the future of the field!
#quantummachinelearning#quantumcomputing#quantumimageprocessing