So looks like good old Google posted this past Monday that Willow, its latest quantum computing chip had come to tell us something utterly mind boggling! Well not to all but this thing is going at such speed and reliability in it's performance that now the claims by Google are indeed newsworthy in themselves, but what really caught the tech industry's attention was an even wilder claim tucked into the blog post about the chip.
Google Quantum AI founder Hartmut Neven wrote in his blog post that this chip was so mind-boggling fast that it must have borrowed computational power from other universes. Ergo the chip's performance indicates that parallel universes exist and "we live in a multiverse." Willow’s performance on this benchmark is astonishing: It performed a computation in under five minutes that would take one of today’s fastest supercomputers 1025 or 10 septillion years. If you want to write it out, it’s 10,000,000,000,000,000,000,000,000 years. This mind-boggling number exceeds known timescales in physics and vastly exceeds the age of the universe.
This lends credence to the idea that quantum computation occurs in many parallel universes, in line with the idea that we live in a multiverse, a prediction first made by David Deutsch. This drop-the-mic moment on the nature of reality was met with skepticism by some, but, surprisingly, others on the internet who profess to understand these things argued that Nevan's conclusions were more than plausible.
The multiverse, while stuff of science fiction, is also an area of serious study by the founders of quantum physics. The skeptics, however, point out that the performance claims are based on the benchmark that Google itself created some years ago to measure quantum performance. That alone doesn't prove that parallel versions of you aren't running around in other universes — just where the underlying measuring stick came from.
Unlike classic digital computers that calculate based on whether a bit is a 0 or 1 (on or off), quantum computers rely on incredibly tiny qubits. These can be on/off or both (somewhere in between) and they can also tap into quantum entanglement — a mysterious connection at the tiniest levels of the universe between two or more particles where their states are linked, no matter the distance that separates them. Quantum computers use such quantum mechanics to calculate highly complex problems that cannot currently be addressed with classic computers. The problem is that the more qubits used in the computer, the more prone to errors they are. So it's not clear yet if quantum computers will ever be reliable enough and powerful enough to live up to their hype.
Google's mission with Willow was to reduce those errors, and Neven says it accomplishes that.
Unlike classic digital computers that calculate based on whether a bit is a 0 or 1 (on or off), quantum computers rely on incredibly tiny qubits. These can be on/off or both (somewhere in between) and they can also tap into quantum entanglement — a mysterious connection at the tiniest levels of the universe between two or more particles where their states are linked, no matter the distance that separates them. Quantum computers use such quantum mechanics to calculate highly complex problems that cannot currently be addressed with classic computers. The problem is that the more qubits used in the computer, the more prone to errors they are. So it's not clear yet if quantum computers will ever be reliable enough and powerful enough to live up to their hype.
Google's mission with Willow was to reduce those errors, and Neven says it accomplishes that.
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