All articles tagged with #quantum error correction
Researchers have created an optical tweezer array trapping over 6,100 neutral atoms with high coherence times and imaging fidelity, advancing the potential for scalable quantum computing and error correction.
Researchers have discovered that by reintroducing a previously discarded type of particle called neglectons into topological quantum computing models, they can enable Ising anyons to perform universal quantum computation through braiding alone, potentially advancing the development of more robust quantum computers.
Scientists have achieved a record-low quantum error rate of 0.000015% using trapped ions and room temperature operation, significantly advancing the potential for practical quantum computers by reducing the need for extensive error correction and enabling more efficient, smaller, and faster quantum devices.
Physicists have proposed a new theory that could resolve the information paradox of black holes, which was first proposed by Stephen Hawking. The theory involves encoding the interior information of a black hole into its exterior using a two-step algorithm. The first step scrambles the information, while the second step involves postselection, a process that allows for desired outcomes. The encoded information exists in the radiation outside the black hole, and as the black hole evaporates, the interior information becomes increasingly detached from reality. The theory suggests that semiclassical physics fails to accurately capture phenomena that require exponential complexity. While some physicists have raised questions and alternative solutions, others have found the theory intriguing and are exploring its implications.
Researchers have achieved a significant milestone in quantum computing by extending the lifetime of quantum information beyond the breakeven point using Quantum Error Correction (QEC). By successfully mitigating the effects of decoherence, scientists have demonstrated that quantum information can be preserved and processed effectively in the presence of real-world noise. This experimental achievement opens up new possibilities for quantum information processing and paves the way for high-fidelity logical operations between error-corrected qubits, addressing the challenges posed by noise in quantum systems. The experiment utilized the grid code within an electromagnetic mode and was conducted at Yale University.
Physicists are using quantum processors to create non-abelian anyons, elusive particles that could serve as the foundation for topological quantum computing. These particles have shared memory that can be manipulated by braiding, making them ideal qubits. Quantum processors are also being used to simulate and correct errors in shoddy qubits, extending the lifespan of anyons. Theorists are also working on creating a more complicated phase of quantum matter where true non-abelian anyons arise natively in a pristine phase of matter.
Scientists at Yale University have extended the lifespan of a qubit, the workhorse of quantum computing, by keeping it in its ideal state for twice as long as normal. They achieved this by demonstrating the practicality of quantum error correction (QEC), a process that keeps quantum information intact for longer by introducing redundancy and error removal. The experiment also introduced machine learning AI algorithms to tweak the error correction routine. The research validates a cornerstone assumption of quantum computing and paves the way for practical quantum computers.