Tech giant Google unveiled on Monday its new state-of-the-art quantum computing chip, which it said was "a major breakthrough" and could bring practical quantum computing closer to reality.
A custom chip called "Willow" does in minutes what it would take leading supercomputers 10 septillion years to complete, according to Google Quantum AI founder Hartmut Neven.
"Written out, that is a 1 with 25 zeros," Neven said of the time span while briefing journalists. "A mind-boggling number."
Neven's team of about 300 people at Google is on a mission to build quantum computing capable of handling otherwise unsolvable problems like safe fusion power and stopping climate change.
"We see Willow as an important step in our journey to build a useful quantum computer with practical applications in areas like drug discovery, fusion energy, battery design and more," said Google CEO Sundar Pichai on X.
A quantum computer that can tackle these challenges is still years away, but Willow marks a significant step in that direction, according to Neven and members of his team.
While still in its early stages, scientists believe that superfast quantum computing will eventually be able to power innovation in a range of fields.
Quantum research is seen as a critical field, and the United States and China have invested heavily in it. At the same time, Washington has also restricted the export of this sensitive technology.
Olivier Ezratty, an independent expert in quantum technologies, told Agence France-Presse (AFP) in October that private and public investment in the field has totaled around $20 billion worldwide over the past five years.
Regular computers function in a binary fashion: they carry out tasks using tiny data fragments known as bits that are only ever expressed as 1 or 0.
But fragments of data on a quantum computer, known as qubits, can be both 1 and 0 at the same time – allowing them to crunch an enormous number of potential outcomes simultaneously.
Crucially, Google's chip demonstrated the ability to reduce computational errors exponentially as it scales up – a feat that has eluded researchers for nearly 30 years.
The breakthrough in error correction, published in the leading science journal Nature, showed that adding more qubits to the system actually reduced errors rather than increasing them – a fundamental requirement for building practical quantum computers.
According to Google Director of Quantum Hardware Julian Kelly, error correction is the "end game" in quantum computing, and Google is "confidently progressing" along the path.