Founded in fall 2023, the Cornell Quantum Computing Association (QCA) pushes the boundaries of student research in the field ...

A device made from superconducting qubits could prove a powerful technology for enabling practical quantum computing or more ...

Quantum computers differ fundamentally from classical ones. Instead of using bits (0s and 1s), they employ "qubits," which can exist in multiple states simultaneously due to quantum phenomena like ...

Quantum computers promise enormous computational power, but the nature of quantum states makes computation and data ...

Deep-diving guide explains the basics, surveys major quantum algorithms and steps through implementing them on publicly available quantum computers.

Since the 1990s, evidence has been growing that quantum computers should be able to solve a range of particularly complex ...

In a milestone that brings quantum computing tangibly closer to large-scale practical use, scientists at Oxford University Physics have demonstrated the first instance of distributed quantum ...

Twenty years ago, theoretical physicists and computer scientists were developing quantum algorithms for virtual quantum computers, with no working hardware in sight. Today, just about anyone can log ...

At first glance, quantum computers seem like machines that only will exist in the far-off future. And in a way, they are. Currently, the processing power that these devices have are limited by the ...

Quantum computing is a transformative technology—one that carries serious implications for the cryptographic security on which cryptocurrencies and modern finance rely.

Researchers from the National University of Singapore proposed a quantum algorithm that could improve artificial intelligence through quantum computing.

Quantum algorithms have shown the potential to revolutionize route optimization. By considering multiple routes simultaneously, quantum computers can identify more efficient paths, minimizing ...