Quantum researchers finally captured the field’s “holy grail,” showing real machines can beat classical computing ...

Quantum computers still face a major hurdle on their pathway to practical use cases: their limited ability to correct the ...

Quantum computers are getting faster. IBM's Starling computer will be released in 2029 and will be 20,000 times faster than ...

Many see quantum computing's advent as marking a paradigm shift from classical, or conventional, computing. Conventional computers process information in the form of digital bits (0s and 1s ...

He calls the back and forth between the quantum- and classical-computing communities a “symbiotic relationship,” in which the two sides challenge each other by developing ever-more sophisticated ...

[Related: In photos: Journey to the center of a quantum computer] However, classical computers have an upper limit when it comes to these types of problems, especially when the models become more ...

In theory, quantum computers could solve problems that are beyond even the most powerful classical computer. However, there’s broad consensus that such devices will need to become much larger ...

An article on quantum machine learning research is published in Frontiers in Physics. Neural networks are now commonly used to solve a wide range of computational problems. At this stage, the power of ...

They have proven, for the first time, that a quantum computer can generate bits of randomness that are certifiably random—verified using classical supercomputers. This breakthrough goes beyond ...

To somewhat work around these limitations, IBM has now pitched the idea of a hybrid quantum-classical computer (marketed as ‘quantum-centric supercomputing’), which as the name suggests ...

Quantum computing stocks are rising today after a key announcement from one of the industry’s leaders. While the fast-growing artificial intelligence (AI) market tends to overshadow quantum ...

The approach, known as Shor’s algorithm, relies on properties of quantum physics, such as superposition and entanglement, that are impossible with today’s classical computers.