Dr. Milton Mattox’s Post

In recent quantum computing news: Quantum Computing Takes A Giant Leap Forward With Breakthrough Discovery Summary: Scientists at The University of Manchester and the University of Melbourne have developed an ultra-pure form of silicon, which will enhance the construction of high-performance qubit devices for scalable quantum computing. Why is this important? This breakthrough reduces information loss in qubits by eliminating problematic silicon isotopes, paving the way for quantum computers that could tackle complex problems like climate change and healthcare. The ultra-pure silicon allows for creating over a million qubits, outperforming current supercomputers and utilizing manufacturing techniques similar to those used for traditional silicon chips. What's the key takeaway? This advancement marks a significant step towards transformative advancements in various fields, including AI, secure communications, and weather forecasting. https://lnkd.in/e2saAqGA #quantumcomputing #quantumtechnology #cybersecurity

In case you missed the news from Quantum Day on April 14, 2024: World Quantum Day 2024: The latest developments in quantum science and technology Summary: World Quantum Day on April 14 celebrates advancements in quantum mechanics, which are crucial for developing technologies like semiconductors and GPS. Future quantum technology promises secure communication, enhanced computation, and advanced sensing. Notable research includes energy-efficient microelectronics, novel qubit creation, and quantum-AI integration. Recent milestones include extended qubit coherence times and novel computer architectures, reinforcing quantum mechanics' pivotal role in evolving science and technology. https://lnkd.in/gXi5aFWn #quantumday #quantumcomputing #quantumtecnology #cybersecurity

New Post: MIT’s Diamond Qubits Redefine The Future Of Quantum Computing – World Pakistan - Researchers developed a modular fabrication process to produce a quantum-system-on-chip that integrates an array of artificial atom qubits onto a semiconductor chip. Credit: Sampson Wilcox and Linsen Li, RLE, edited A new quantum-system-on-chip enables the efficient control of a large array of qubits, advancing toward practical quantum computing. Researchers at MIT and MITRE have developed …

Groundbreaking! An unexpected breakthrough in quantum computing. Oxford Ionics just announced that they managed to stabilize a Qubit using standard silicon technology instead of previously used lasers. That means that the commercialization of quantum computers might be just around the corner (perhaps before the end of the decade). While quantum computing companies like to talk about climate models and drug research, the application everyone is really after is code breaking. A quantum computer can literally hack into any system currently deployed. Combining that with powerful AI will produce the ultimate cyber weapon, enabling anyone possessing such technology to bring down the entire infrastructure of any country at will.

Toshiba Breakthrough Enables High-Fidelity Quantum Computing with Double-Transmon Coupler Researchers at Toshiba Corporation and RIKEN have made a breakthrough in quantum computing, developing a tunable coupler that can connect two superconducting qubits with unprecedented precision. This innovation enables the switching between executing and halting operations by turning the coupling between qubits "on" or "off". The team, led by Yasunobu Nakamura, has achieved a two-qubit gate fidelity of 98.4%, paving the way for the development of practical quantum computers. The coupler's performance can be tuned by adjusting an external magnetic flux, allowing for a wide range of coupling strengths from 6 kHz to 80 MHz. This technology has the potential to suppress crosstalk errors, which occur when control electromagnetic waves applied to one qubit affect another. Toshiba and RIKEN aim to further enhance the performance of their double-transmon coupler, targeting a two-qubit gate fidelity of 99.99% and scaling up the system for practical applications. #quantum #quantumcomputing #technology https://lnkd.in/dJcsbJHr

Toshiba Breakthrough Enables High-Fidelity Quantum Computing with Double-Transmon Coupler Researchers at Toshiba Corporation and RIKEN have made a breakthrough in quantum computing, developing a tunable coupler that can connect two superconducting qubits with unprecedented precision. This innovation enables the switching between executing and halting operations by turning the coupling between qubits "on" or "off". The team, led by Yasunobu Nakamura, has achieved a two-qubit gate fidelity of 98.4%, paving the way for the development of practical quantum computers. The coupler's performance can be tuned by adjusting an external magnetic flux, allowing for a wide range of coupling strengths from 6 kHz to 80 MHz. This technology has the potential to suppress crosstalk errors, which occur when control electromagnetic waves applied to one qubit affect another. Toshiba and RIKEN aim to further enhance the performance of their double-transmon coupler, targeting a two-qubit gate fidelity of 99.99% and scaling up the system for practical applications. #quantum #quantumcomputing #technology https://lnkd.in/dJcsbJHr

IQM Quantum Computers Achieves Technological Milestones With 99.9% 2-Qubit Gate Fidelity And 1 Millisecond Coherence Time 🔽 Key accomplishments include: 🌟Qubit Relaxation Time (T1): 0.964 ± 0.092 ms 🌟Dephasing Time (T2 echo): 1.155 ± 0.188 ms 🌟Record Two-Qubit Gate Fidelity: 99.9% 🌟In-House Chip Fabrication: Quality on par with world-leading institutions These breakthroughs mark a pivotal moment in quantum computing, demonstrating IQM Quantum Computers's commitment to pushing the boundaries of what’s possible. Read more: https://lnkd.in/eVP5zuvi #QuantumComputing #IQM #Innovation #TechnologicalMilestones #QubitFidelity

Toshiba Breakthrough Enables High-Fidelity Quantum Computing with Double-Transmon Coupler Researchers at Toshiba Corporation and RIKEN have made a breakthrough in quantum computing, developing a tunable coupler that can connect two superconducting qubits with unprecedented precision. This innovation enables the switching between executing and halting operations by turning the coupling between qubits "on" or "off". The team, led by Yasunobu Nakamura, has achieved a two-qubit gate fidelity of 98.4%, paving the way for the development of practical quantum computers. The coupler's performance can be tuned by adjusting an external magnetic flux, allowing for a wide range of coupling strengths from 6 kHz to 80 MHz. This technology has the potential to suppress crosstalk errors, which occur when control electromagnetic waves applied to one qubit affect another. Toshiba and RIKEN aim to further enhance the performance of their double-transmon coupler, targeting a two-qubit gate fidelity of 99.99% and scaling up the system for practical applications. #quantum #quantumcomputing #technology https://lnkd.in/dJcsbJHr

A cutting-edge quantum computing chip has been developed to control and regulate trapped ion qubits in a scalable way. Using this chip, Oxford Ionics is touting some of the world’s best performance to date for single and two-qubit gate fidelities. This chip is expected to be integrated into Oxford Ionic’s quantum computers by 2027, giving them new processing power and efficiency capabilities. The potential impact of this technology is enormous, with implications for various industries, including cryptography, AI and complex simulations. Discover how this advancement could set new benchmarks in quantum computing, making it a pivotal development in the tech landscape: https://buff.ly/3AqHMmg #QuantumComputing #TechInnovation #QuantumChip #FutureTech

MIT and MITRE researchers have developed a groundbreaking quantum hardware platform called a "quantum-system-on-chip" (QSoC), which integrates thousands of qubits onto a single chip. This innovative platform uses diamond color centers, a type of artificial atom, to store and manage quantum information. The new system allows for precise control and scalability, crucial for advancing practical quantum computing. The researchers created a lock-and-release fabrication process to transfer diamond color center microchiplets onto a complementary metal-oxide semiconductor (CMOS) chip. This integration enables efficient control of a large array of qubits and supports extensive quantum communication networks. By tuning qubits across different frequencies, the QSoC architecture facilitates a novel entanglement multiplexing protocol, enhancing the potential for large-scale quantum computing. The development process involved complex nanofabrication techniques and custom-built cryo-optical metrology setups to measure performance and ensure stability. The team demonstrated the capability to tune over 4,000 qubits to the same frequency while maintaining their properties, marking a significant step toward scalable and practical quantum computers.