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Quantum Leaps: Supremacy, Breakthroughs, and Real-World Applications on the Horizon
- 2024/12/19
- 再生時間: 3 分
- ポッドキャスト
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あらすじ・解説
This is your Quantum Research Now podcast.
Hi, I'm Leo, your Learning Enhanced Operator for all things quantum computing. Let's dive right into the latest breakthroughs in quantum research.
Just a few days ago, I was reading about the incredible work done by scientists at Paderborn University. They used high-performance computing at large scales to analyze a quantum photonics experiment, specifically the tomographic reconstruction of experimental data from a quantum detector. This is a device that measures individual photons, or light particles. The researchers developed new HPC software to achieve this, and their findings were published in the specialist journal Quantum Science and Technology. According to Schapeler, one of the researchers, this work is opening up entirely new horizons for the size of systems being analyzed in the field of scalable quantum photonics, which has wider implications for characterizing photonic quantum computer hardware.
This kind of research is crucial for demonstrating quantum supremacy in quantum photonic experiments on a scale that cannot be calculated by conventional means. Speaking of quantum supremacy, IBM recently launched its most advanced quantum computers, fueling new scientific value and progress towards quantum advantage. Their quantum processor, IBM Quantum Heron, can now leverage Qiskit to accurately run certain classes of quantum circuits with up to 5,000 two-qubit gate operations. This is a significant step forward in tackling scientific problems across materials, chemistry, life sciences, high-energy physics, and more.
But what about real-world applications? IDTechEx explores which applications are being developed today across the materials, chemical, automotive, finance, and healthcare industries. For instance, the application of quantum computing to logistics and operations could be transformative. D-wave is already ramping up production-scale deployment of an auto-scheduling product using annealing with partners of the Pattison Food Group. This is a great example of how quantum computing can solve complex optimization problems, which is a recurring theme across various industries.
In fact, a recent survey by QuEra Computing reveals that over half of quantum academics, scientists, and professionals believe quantum computing is progressing faster than expected, with 40% predicting it will become a superior alternative to classical computing for certain workloads within the next five years. This is exciting news, and I'm eager to see how quantum computing will continue to evolve and solve problems that were previously unsolvable.
That's all for now. Stay tuned for more updates on quantum research, and I'll catch you in the next quantum leap.
For more http://www.quietplease.ai
Get the best deals https://amzn.to/3ODvOta
Hi, I'm Leo, your Learning Enhanced Operator for all things quantum computing. Let's dive right into the latest breakthroughs in quantum research.
Just a few days ago, I was reading about the incredible work done by scientists at Paderborn University. They used high-performance computing at large scales to analyze a quantum photonics experiment, specifically the tomographic reconstruction of experimental data from a quantum detector. This is a device that measures individual photons, or light particles. The researchers developed new HPC software to achieve this, and their findings were published in the specialist journal Quantum Science and Technology. According to Schapeler, one of the researchers, this work is opening up entirely new horizons for the size of systems being analyzed in the field of scalable quantum photonics, which has wider implications for characterizing photonic quantum computer hardware.
This kind of research is crucial for demonstrating quantum supremacy in quantum photonic experiments on a scale that cannot be calculated by conventional means. Speaking of quantum supremacy, IBM recently launched its most advanced quantum computers, fueling new scientific value and progress towards quantum advantage. Their quantum processor, IBM Quantum Heron, can now leverage Qiskit to accurately run certain classes of quantum circuits with up to 5,000 two-qubit gate operations. This is a significant step forward in tackling scientific problems across materials, chemistry, life sciences, high-energy physics, and more.
But what about real-world applications? IDTechEx explores which applications are being developed today across the materials, chemical, automotive, finance, and healthcare industries. For instance, the application of quantum computing to logistics and operations could be transformative. D-wave is already ramping up production-scale deployment of an auto-scheduling product using annealing with partners of the Pattison Food Group. This is a great example of how quantum computing can solve complex optimization problems, which is a recurring theme across various industries.
In fact, a recent survey by QuEra Computing reveals that over half of quantum academics, scientists, and professionals believe quantum computing is progressing faster than expected, with 40% predicting it will become a superior alternative to classical computing for certain workloads within the next five years. This is exciting news, and I'm eager to see how quantum computing will continue to evolve and solve problems that were previously unsolvable.
That's all for now. Stay tuned for more updates on quantum research, and I'll catch you in the next quantum leap.
For more http://www.quietplease.ai
Get the best deals https://amzn.to/3ODvOta