QuantumLeap Inc. Achieves Quantum Supremacy, Igniting Market Frenzy and Tech Sector Upheaval The central event is QuantumLeap Inc.'s verifiable demonstration of its 'Odyssey' quantum processor. The processor completed a specific computational task in just over three minutes, a task that would take the world's most powerful classical supercomputer an estimated 10,000 years. This event moves quantum computing from a theoretical and experimental phase to the brink of practical application, fundamentally altering the technological landscape. The market is currently driven by extreme sentiment. On one hand, there is intense FOMO (Fear Of Missing Out) among investors, leading to a massive speculative run-up in QLI's stock price. On the other hand, a wave of fear is rippling through sectors reliant on current encryption standards, as their business models are now under a potential existential threat. This has created a clear divergence between 'quantum-ready' and 'quantum-vulnerable' stocks. Source - https://lnkd.in/df9kr4tw
QuantumLeap Inc. achieves quantum supremacy, impacting tech and markets
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Telstra and Silicon Quantum Computing (SQC) have revealed the results of a 12-month trial partnership exploring how quantum machine learning could enhance network predictive intelligence. Read more: https://lnkd.in/eX-p45s8 #telstra #quantum #sqc Shailin Sehgal Michelle Simmons
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The Analogy (Classical to Quantum Bridge) Ever wonder how a quantum computer corrects its own errors? It helps to start with a classical analogy. Imagine a bit that randomly flips from 0 to 1 with some probability. To protect it, you make 5 copies. If one bit flips, a majority vote restores the original. You've just created a "logical bit" that's more reliable than any single physical component. Now, let's upgrade this for the quantum world. In quantum, you can't just "look" at the bits to take a vote—you'd collapse the superposition! So, how do you do it? You measure parities—the relationships between qubits—without learning their individual states. This is like detecting that two nodes in a network disagree, allowing you to pinpoint and correct the error in the chain. This process, formalized as finding a minimum weight perfect matching on a graph, is the engine behind many quantum error-correcting codes. We're building resilience not by making things perfect, but by making them smart enough to fix their own mistakes. #QuantumErrorCorrection #ClassicalComputing #QuantumLogic #Algorithms #DeepTech
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Quantum computing sneaking into finance isn’t exactly news, but this story hits better than most hype. Abaqus, a startup with a name that nods to old-school calculators yet brings quantum tech, is trying to edge out classical models in portfolio optimization and fraud detection. That cautious vibe stuck out–a reminder this ain’t plug-and-play yet, financial stakes are high, and quantum’s still awkward. Still, if quantum cracks this, the game shifts hard: new risk views, new biz models. I’m watching for when the edge moves from “cool concept” to “cash registers ringing.”
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Whaou! Google Willow quantum processor ran an algorithm to compute the structure of a molecule 13,000x faster than the best classical algorithm on one of the world’s fastest supercomputers
Today, we’ve published a new breakthrough quantum algorithm in Nature Magazine, that provides a path towards real-world quantum computing applications. The Google Quantum AI team has successfully run an algorithm that can compute the structure of a molecule, with potential for real-world applications. Our Willow quantum processor ran the algorithm — which we’ve named “Quantum Echoes” — 13,000x faster than the best classical algorithm on one of the world’s fastest supercomputers. Importantly this computation is verifiable, which means its outcome can be repeated by other quantum computers or confirmed by experiments. This is the first time in history that any quantum computer has successfully run a verifiable algorithm that surpasses the ability of classical computers. With our latest breakthrough algorithm on Willow, we’re optimistic that within five years we’ll see real-world applications that are possible only on quantum computers. Read more here: https://lnkd.in/eQ8PsFsh
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We recognise that Google’s announcement of the “Quantum Echoes” algorithm on their Willow processor isn’t simply about scaling hardware or brute-force qubit counts — it shows a strategic shift to algorithmic resilience: choosing a problem whose structure naturally self-corrects or averages out errors, rather than relying solely on physical fault-tolerant error-correction overheads. By aligning the algorithm’s internal dynamics (e.g., forward-and-reverse evolutions, echo-type cancellation) with the noise profile, Google sidesteps many of the classical pitfalls of quantum-computing roadmaps (excess overhead, unfettered decoherence, unverifiable claims). Essentially, they’ve outsourced part of the error-correction burden to the algorithmic layer — the physics layer still matters, but the scalability constraints become less extreme because the problem itself tolerates or cancels noise. In doing so, they refine the narrative of “verifiable quantum advantage” into one less about ideal fault tolerance and more about structured robustness, and this might mark a pragmatic pivot in how quantum-computing milestones are framed and achieved. Link to the QP-paper here: https://lnkd.in/gBVUh2cJ #QuantumPessimism #PSIW
Today, we’ve published a new breakthrough quantum algorithm in Nature Magazine, that provides a path towards real-world quantum computing applications. The Google Quantum AI team has successfully run an algorithm that can compute the structure of a molecule, with potential for real-world applications. Our Willow quantum processor ran the algorithm — which we’ve named “Quantum Echoes” — 13,000x faster than the best classical algorithm on one of the world’s fastest supercomputers. Importantly this computation is verifiable, which means its outcome can be repeated by other quantum computers or confirmed by experiments. This is the first time in history that any quantum computer has successfully run a verifiable algorithm that surpasses the ability of classical computers. With our latest breakthrough algorithm on Willow, we’re optimistic that within five years we’ll see real-world applications that are possible only on quantum computers. Read more here: https://lnkd.in/eQ8PsFsh
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Google is leading the revolutionary journey in quantum computing, achieving phenomenal advancements that are paving the way for real-world applications 🚀
Today, we’ve published a new breakthrough quantum algorithm in Nature Magazine, that provides a path towards real-world quantum computing applications. The Google Quantum AI team has successfully run an algorithm that can compute the structure of a molecule, with potential for real-world applications. Our Willow quantum processor ran the algorithm — which we’ve named “Quantum Echoes” — 13,000x faster than the best classical algorithm on one of the world’s fastest supercomputers. Importantly this computation is verifiable, which means its outcome can be repeated by other quantum computers or confirmed by experiments. This is the first time in history that any quantum computer has successfully run a verifiable algorithm that surpasses the ability of classical computers. With our latest breakthrough algorithm on Willow, we’re optimistic that within five years we’ll see real-world applications that are possible only on quantum computers. Read more here: https://lnkd.in/eQ8PsFsh
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Google’s “Quantum Echoes” ran 13,000x faster than classical supercomputers. First verifiable quantum algorithm to surpass classical computing. The uncomfortable question - What happens to LLMs in 5 years? Today’s transformers are bottlenecked by classical constraints—sequential processing, massive energy consumption, diminishing returns on scaling. Quantum-native AI could leverage superposition for parallel solution exploration and learn from fundamentally less data. Are we perfecting steam engines in 1890? The billions invested in classical AI infrastructure today might become tomorrow’s expensive legacy systems. #QuantumComputing #AI #FutureTech
Today, we’ve published a new breakthrough quantum algorithm in Nature Magazine, that provides a path towards real-world quantum computing applications. The Google Quantum AI team has successfully run an algorithm that can compute the structure of a molecule, with potential for real-world applications. Our Willow quantum processor ran the algorithm — which we’ve named “Quantum Echoes” — 13,000x faster than the best classical algorithm on one of the world’s fastest supercomputers. Importantly this computation is verifiable, which means its outcome can be repeated by other quantum computers or confirmed by experiments. This is the first time in history that any quantum computer has successfully run a verifiable algorithm that surpasses the ability of classical computers. With our latest breakthrough algorithm on Willow, we’re optimistic that within five years we’ll see real-world applications that are possible only on quantum computers. Read more here: https://lnkd.in/eQ8PsFsh
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This is super relevant for an article I'm publishing tomorrow on the patent space here. Hint: Google is quite behind in the patent space compared to IBM, which is the definitive leader in quantum computing. However, Google has made a lot of progress on error correction, which is really the name of the game in commercializing this tech.
Today, we’ve published a new breakthrough quantum algorithm in Nature Magazine, that provides a path towards real-world quantum computing applications. The Google Quantum AI team has successfully run an algorithm that can compute the structure of a molecule, with potential for real-world applications. Our Willow quantum processor ran the algorithm — which we’ve named “Quantum Echoes” — 13,000x faster than the best classical algorithm on one of the world’s fastest supercomputers. Importantly this computation is verifiable, which means its outcome can be repeated by other quantum computers or confirmed by experiments. This is the first time in history that any quantum computer has successfully run a verifiable algorithm that surpasses the ability of classical computers. With our latest breakthrough algorithm on Willow, we’re optimistic that within five years we’ll see real-world applications that are possible only on quantum computers. Read more here: https://lnkd.in/eQ8PsFsh
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The ability to compute molecular structures with such precision and verify the results across quantum hardware is a game-changer for fields like chemistry, materials science, and beyond. The “Quantum Echoes” algorithm, leveraging the out-of-order time correlator and the innovative “molecular ruler” technique, not only matches traditional NMR results but also reveals additional molecular insights. This opens exciting possibilities for applications like drug discovery and advanced materials design. The analogy of reading a shipwreck’s nameplate from a sonar scan vividly captures the unprecedented precision of this approach. This breakthrough sets a new benchmark for quantum computing’s potential to transform scientific discovery. I’m eager to see how the Willow chip and Quantum Echoes pave the way for a “quantum-scope” revolution!
Today, we’ve published a new breakthrough quantum algorithm in Nature Magazine, that provides a path towards real-world quantum computing applications. The Google Quantum AI team has successfully run an algorithm that can compute the structure of a molecule, with potential for real-world applications. Our Willow quantum processor ran the algorithm — which we’ve named “Quantum Echoes” — 13,000x faster than the best classical algorithm on one of the world’s fastest supercomputers. Importantly this computation is verifiable, which means its outcome can be repeated by other quantum computers or confirmed by experiments. This is the first time in history that any quantum computer has successfully run a verifiable algorithm that surpasses the ability of classical computers. With our latest breakthrough algorithm on Willow, we’re optimistic that within five years we’ll see real-world applications that are possible only on quantum computers. Read more here: https://lnkd.in/eQ8PsFsh
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