Brian Hopkins’ Post

An interesting article in Sifted covers the European quantum ecosystem with some predictions. Here are the main takeaways: 1. Consolidation in the Quantum Sector: The quantum computing industry is expected to see increased mergers and partnerships between hardware and software companies. This trend is driven by the need for strategic alliances and acquisition to grow and strengthen capabilities. 2. Advances in Qubits: The race to build a scalable quantum computer continues, with predictions that more companies will surpass the 1,000-qubit milestone in 2024. Technologies based on superconducting qubits and neutral atoms are seen as leading contenders. 3. Error Correction Breakthroughs: Significant improvements in quantum error correction are anticipated, a key step toward developing fault-tolerant quantum computers that can operate reliably for extended periods. 4. Focus on Practical Applications: Investors and end-users are increasingly focusing on real-world quantum computing applications, such as portfolio optimization, drug discovery, and improving machine learning. As quantum technology becomes more practical, the emphasis is shifting from qubit technology to what quantum can do in terms of speed, energy consumption, and precision. 5. AI and Quantum Computing Convergence: The intersection of quantum computing and AI is expected to grow, with potential breakthroughs in areas such as drug discovery and materials science through combined quantum and AI efforts. 6. Quantum Cybersecurity: As quantum computers become more powerful, the risk they pose to modern cryptographic protocols will grow. This is pushing organizations to develop quantum-safe cryptographic solutions, with technologies like Quantum Key Distribution (QKD) being tested in commercial settings. https://hubs.ly/Q02TfwLs0

What do quantum data centres mean for the future? Quantum computing is complex for even seasoned IT specialists. However, like the AI-boom it will represent a monumental shift in the tech world. For us in the high-performance infrastructure game, its most important application will most likely be the development of fault-tolerant systems, which will require millions of physical qubits. Together, these qubits (two-state quantum systems used in computing) form part of a larger system. We're already seeing these systems move out of the lab and into commercial prototypes in the financial world with quantum data centres beginning to appear in Europe. With the AI boom in full swing, this could be the next major tech revolution to watch. Quantum computers will completely rewrite the rules of traditional computing to solve business challenges beyond anything previously thought possible – as well as supercharging the AI revolution. Read more from Charlotte Trueman, DatacenterDynamics about new quantum data centres in Munich 👉 https://lnkd.in/eG6MH7s2.

Interesting "hype check" article on IEEE Spectrum: Quantum Computing’s Hard, Cold Reality Check... It talks about how QC (Quantum Computing) has been hyped up to unrealistic expectations beyond what the technology was intended to deliver. "The main promise of quantum computing is the ability to solve problems far faster than classical computers, but exactly how much faster varies. There are two applications where quantum algorithms appear to provide an exponential speed up, says Troyer. One is factoring large numbers, which could make it possible to break the public key encryption the internet is built on. The other is simulating quantum systems, which could have applications in chemistry and materials science." Additionally, it wrote that "Another significant barrier is data bandwidth. Qubits’ slow operating speeds fundamentally limit the rate at which you can get classical data in and out of a quantum computer." ... " quantum computers will only really shine on small-data problems with exponential speed ups. All the rest is beautiful theory, but will not be practical"... https://lnkd.in/gmP_mSiS.

We’ve set a new record! Today we are announcing industry-leading neutral-atom two-qubit gate fidelities in our flagship platforms, and together with Microsoft we demonstrate the largest-ever entangled logical qubit state with 24 logical qubits, and performed error detection, error correction, and computation with 28 logical qubits! #MSIgnite These milestones show how Atom Computing’s neutral atoms provide a highly-scalable hardware platform and, together with Microsoft’s #AzureQuantum compute platform, form a state-of-the-art reliable quantum computer. This joint commercial #QuantumComputing offering, which combines logical qubits with #HPC and #AI, will enable organizations to accelerate growing their quantum ecosystems. Read more: https://lnkd.in/gg7C42dM

https://lnkd.in/gQmCAwb6 Quantum Computing Race is on and on... In general, many of us were thinking that IBM is the only Tech Giant who is going to produce gated Quantum Computing with a cumbersome super conductor at Minus 273 degree and with error suppression and sufficient number of Qubits. But there are many players in QC revolution and many kinds of it are popping up.

Beyond Bits: The Quantum Leap of Quantum Computing Imagine a computer that harnesses the bizarre laws of quantum mechanics to solve problems beyond the reach of even the most powerful machines today. That's the promise of quantum computing. Instead of using bits (0s and 1s), quantum computers utilize qubits. These qubits can exist in a state of superposition, meaning they can be both 0 and 1 simultaneously. This "quantum weirdness" unlocks immense potential for tackling complex challenges: Drug Discovery: Simulating molecules at an atomic level could speed up drug development and lead to breakthroughs in medicine. Materials Science: Designing new materials with specific properties could revolutionize fields like energy and construction. Financial Modeling: Quantum algorithms could analyze vast amounts of financial data in real-time, leading to more accurate predictions and better risk management. Cryptography: Cracking current encryption methods could pose a security threat, but it also paves the way for developing unbreakable new forms of encryption. While still in its early stages, quantum computing holds immense potential. However, challenges remain. Building and maintaining quantum computers is complex and expensive. Additionally, developing software tailored to this new technology requires significant advancements. Despite these hurdles, the future of quantum computing is bright. With continued research and development, this technology has the potential to unlock a new era of scientific discovery and innovation, impacting almost every aspect of our lives.

Quantum computing is on the brink of revolutionizing technology and industry, offering transformative potential across various fields. One of the most promising applications is drug discovery and materials science. Quantum computers can simulate molecular interactions with remarkable precision, potentially speeding up the development of new drugs and advanced materials. In optimization, quantum computing could solve complex problems in logistics and financial modeling much faster than classical systems, offering new efficiencies and capabilities. In artificial intelligence, quantum computing might enhance machine learning by accelerating data processing and enabling more sophisticated algorithms. Similarly, in climate modeling, quantum computers could provide more accurate predictions by handling intricate climate systems that classical computers struggle with. However, the journey to practical quantum computing is fraught with challenges. Technical hurdles include building stable quantum systems and managing error rates, as qubits are highly sensitive to interference. Quantum error correction, while crucial, requires significant resources. Moreover, the expensive infrastructure needed for quantum computers, like ultra-cold environments, adds to the cost and complexity of development. There are also critical concerns around security, as quantum computers could potentially break current encryption methods. This necessitates the creation of quantum-resistant cryptographic systems to safeguard data. Despite these obstacles, ongoing research and interdisciplinary collaboration hold the key to overcoming these challenges. As quantum computing technology matures, it promises to unlock new possibilities and drive innovation across diverse sectors, making it a field to watch closely.

Interesting post in EET this morning on quantum computing. Over the years, my perspective on quantum computing has evolved from being alternately optimistic and pessimistic to now more of a pragmatic approach. The energy pouring into quantum computing- from literature, conferences, etc.. is following the pattern of how technology progresses into the mainstream. Generally speaking it sure seems like the quantum evolution is starting in the IT ecosystem. At Open Compute Project Foundation, we are objectively exploring Quantum and there is a community forming around fundamental implementation ideas. Interested in learning more about quantum computing? Check out the engaging quantum track we hosted at the previous EMEA Summit 2024. The insightful talks are definitely worth a listen! https://lnkd.in/g7jvDeQ2 If you're eager to get involved in this cutting-edge field, seize the opportunity to participate in our 2024 Global Summit by submitting proposals for talks, posters, and more. The call for proposals closes this Friday, the 21st. Don't miss out! https://lnkd.in/gQMwb9GC #ocp #quantumcomputing #ocpglobalsummit

Fantastic article by Fujitsu”s Mahesh Krishnan on #Quantum Learn about the transformative potential of quantum computing and how you can harness its power for growth 👉https://okt.to/UJXIoK

Quantum Computing Is Coming. Here’s What Needs To Happen First. https://buff.ly/3WKBHZh #quantum #quantumcareer #quantumcomputing #quantumresearch #quantumtechnologies