Quantum computing is rapidly evolving, though still largely theoretical — and each of the Big Tech giants wants to be the one to make it mainstream.

Quantum computing offers a game-changing opportunity for the public sector, with the potential to address some of society’s most pressing challenges.

Analysis pokes holes in protocol that underpins Microsoft’s claim to have created the first topological qubits.

Quantum computing promises to revolutionize industries from AI to drug discovery, but significant engineering challenges remain before we see practical applications.

Microsoft has unveiled a major breakthrough in the field of quantum computing with the Majorana 1 processor. This processor integrates a Topological Core architecture, a world first, enabling

American quantum computing startup PsiQuantum announced yesterday that it has cracked a significant puzzle on the road to making the technology useful: manufacturing quantum chips in useful quantities.

Despite current limitations, there is substantial value in preparing for a future where quantum computing becomes more practical and widespread. Companies are investing heavily in research and talent to be ready when quantum computing matures.

Austin's most eclectic — and arguably most iconic — festival, the South by Southwest Conference and Festival (SXSW), has arrived, with the Tech Industry Track leading the way. With options for any interest — from buzzy artificial intelligence advancements and quantum computing to bringing extinct species back to life (no,

Oskar Painter, Amazon’s head of quantum hardware, criticized Microsoft CEO Satya Nadella ‘s statements as exaggerated. Painter expressed more favorable opinions on quantum efforts by Alphabet Inc.'s Google and IBM.

After several dashed predictions, quantum computing is accelerating rapidly with actual use cases and scientific breakthroughs expected within years, not decades.

Newly achieved precise control over light emitted from incredibly tiny sources, a few nanometers in size, embedded in two-dimensional (2D) materials could lead to remarkably high-resolution monitors and advances in ultra-fast quantum computing,