Scientists Clarke, Devoret, and Martinis win Nobel for quantum discovery

🏆 Quantum computing steps out of the lab. The 2025 Nobel Prize in Physics recognised discoveries demonstrating that quantum phenomena like tunnelling can exist at chip scale, not just in theory. It’s a signal that scientific uncertainty is fading and real-world progress is accelerating. As breakthroughs multiply and confidence grows, quantum is shifting from theory to investable reality. 🔗 Explore the quantum future at https://lnkd.in/excxB2Q4 #marketingcommunication

🔴 The 2025 Nobel Prize in Physics goes to John Clarke, Michel Devoret and John Martinis for demonstrating quantum effects in superconducting circuits large enough to hold in your hand. A landmark moment proving that quantum phenomena can exist at a tangible scale. 🔬 This recognition is more than symbolic: it highlights how far quantum technology has come. From lab-scale experiments to real, portable systems. At SaxonQ, we share that vision: our room-temperature quantum chipscan quite literally be held in your hand, bringing quantum computing one step closer to everyday applications. 🎉 A great day for the quantum community and a strong signal that the age of practical quantum technology has truly begun.

U.S. Scientists Awarded Nobel Prize in Physics for Contributions to Quantum Technology #technology Source: https://ift.tt/Pnvyrft Exciting news in the realm of science and technology! John Clarke, Michel H. Devoret, and John M. Martinis have been awarded the Nobel Prize in Physics for their groundbreaking research in quantum tunneling. Their work not only advances our understanding of quantum mechanics but also lays the foundation for the future of digital technology, including quantum computing, cryptography, and sensors. This remarkable achievement highlights the interplay between theoretical physics and practical applications, showcasing how century-old principles can lead to revolutionary advancements in our current digital landscape. As John Clarke noted, the implications of their work are profound, impacting everyday technologies like cellphones. To learn more about their contributions and what this means for the future, read the full blog post here: [U.S. Scientists Awarded Nobel Prize in Physics for Contributions to Quantum Technology](https://ift.tt/Pnvyrft). #rswebsols #NobelPrize #QuantumTechnology #PhysicsResearch #Innovation #DigitalFuture

✨ Breaking Boundaries in Quantum Science ✨ Today, the 2025 Nobel Prize in Physics has been awarded to John Clarke, Michel Devoret, and John Martinis for their pioneering experiments that bring quantum phenomena to the macroscopic scale. Their work demonstrates quantum tunneling and quantized energy levels in electrical circuits—physically tangible systems one can hold in hand—pushing the frontier of what’s possible in quantum technologies. 🔍 Why this matters Their breakthroughs form a bridge between abstract quantum theory and real-world devices, enabling advances in quantum computing, quantum cryptography, and quantum sensing. By making quantum effects observable in “large” systems, they open doors to scalable quantum architectures that were once in the realm of thought experiments. This recognition reaffirms that curiosity-driven fundamental research continues to lay the groundwork for tomorrow’s transformative tech. 📈 Takeaways for all of us In a time when “disruption” is often tied to software or business models, this award reminds us that the deepest shifts begin with science. Whether you’re in engineering, data, business, or policy, breakthroughs like this influence the tools, infrastructures, and possibilities we’ll all live and build with in years ahead. 👏 Congratulations, John Clarke, Michel Devoret, and John Martinis! May your work inspire more audacious ideas, steady persistence, and bold leaps in fields across the spectrum. — #NobelPrize #Physics #QuantumTechnology #Innovation #ScienceForFuture #ResearchMatters

In a sea of LLMs, how does one bet on a long-term AI partnership? It comes down to foundational R&D. Satya Nadella once described Google's "vertically integrated AI play"—from silicon to data, models, products, and distribution. Add world-leading talent and research to the mix. With multiple Nobel Prizes in the past two years awarded to Googlers and DeepMind researchers (Chemistry and Physics), we see: 🧠 Rewriting Software: AlphaFold's protein structure breakthroughs. ⚛️ Rewiring Hardware: Foundational quantum computing advances. In the midst of a multitude of AI models today (many great ones in their own right) wrapping around such foundational research, distinguishing the dressing from the salad can be challenging. Attention is all you need.

Today, John Martinis has won The Nobel Prize in Physics, together with his colleagues John Clarke and Michel Devoret, for their contributions to realizing superconducting qubits for scalable quantum computers. Martinis’s masterpiece, the Google Quantum AI Sycamore quantum chip, was actually calibrated not in California but in Berlin, within BERLIN QUANTUM and the Einstein Foundation Berlin Research Unit of the Berlin University Alliance on quantum devices! This once again shows how closely the quantum community is connected worldwide - and that Berlin is a strong part of the international research landscape. The Tagesspiegel reported on this end of last year, and you find a link to the the publication in the first comment.

"It's like holding a tiny universe in your hand." 🌌🔬 That's how one scientist described the 2025 Nobel Prize-winning discovery. 🏆 Picture this: Holding a piece of quantum physics in your hand. 🖐️✨ That's exactly what the 2025 Nobel Prize winners accomplished. 👨🔬👩🔬 Their groundbreaking work with superconducting circuits demonstrated quantum effects on a macroscopic scale. 🔬🔭 Why does this matter? 🤔💡 1. Quantum tunneling and energy quantization are now observable in larger systems. 👁️🔍 2. This discovery forms the foundation of today's quantum computers. 💻🔢 3. It unlocks potential for quantum cryptography and advanced computing. 🔐💻 Throughout my data analysis journey, grasping these principles has been invaluable. 📊📈 They've fundamentally altered our approach to complex problem-solving. 🧩🔓 Intrigued by quantum mechanics' impact on your industry? 🏭🤯 Let's explore the possibilities together! 🤝🚀 #QuantumComputing #TechnologyInnovation #DataScience #FutureOfTech #NobelPrize #QuantumMechanics #ScienceBreakthrough

✨The latest issue of NIMSNOW is out -- and it's all about Quantum Materials! 🏅The world of “quantum,” which drew attention with this year’s Nobel Prize in Physics, is entering a new era. As we mark 100 years since the birth of quantum mechanics, expectations are rising for quantum technologies such as quantum computers, quantum communication, and quantum sensors— all powered by the fascinating science of quantum materials. 🚀Explore the cutting edge of this research in our latest issue: 🔗 https://lnkd.in/g_EyxiMM

Big win for quantum computing! 👏 John Clarke, Michel H. Devoret, and John M. Martinis win the Nobel Prize in Physics for their groundbreaking work on quantum mechanics, paving the way for super-powerful computers that can solve complex problems in seconds! 🚀💻 #QuantumLeap #NobelPrize

I'm particularly happy with this years Nobel Price in physics since it connects so well to my field of work with close colleagues even having worked with the laureates in past projects. To understand a bit more on what has been the main discoveries beyond the press text of "for the discovery of macroscopic quantum mechanical tunneling and energy quantisation in an electric circuit", read on. Quantum mechanics describe how a particle can move straight through potential barriers using a process called tunneling. This has been viewed historically as a process on atomic scales. The breakthroughs rewarded here demonstrated that this phenomenon could occur in a system large enough to be held in one's hand. That connection - between the macroscopic and microscopic - is always exciting. Josephson junctions are constructed of two superconductors (components that can conduct current with no electrical resistance) separated by a thin insulating barrier. These macroscopic systems are fundamental building blocks in quantum computers. Beyond the experiments on superconductivity, proof was made of energy quantization in these macroscopic systems, meaning the circuit can only exist in discrete energy states rather than a continuous spectrum - as in the "classical" world. This work was foundational for superconducting quantum bits (qubits) that form the basis of modern quantum computers, quantum sensors, and quantum cryptography systems.