Google's Quantum Chip: Proof of the Multiverse? скачать в хорошем качестве

Google's Quantum Chip: Proof of the Multiverse?

In this intriguing video, we dive into Google's revolutionary quantum chip, Willow, and its astounding ability to solve a complex computational problem in under five minutes—something that would take classical supercomputers about 10 septillion years! But what does this mean for our understanding of reality? Could Willow's feat suggest that we live in a multiverse? Join us as we explore the theories of quantum mechanics, including insights from physicist David Deutsch, and examine both the supportive and critical perspectives surrounding this breakthrough. Is this the first experimental hint of parallel universes, or can it be explained through existing quantum theories? Don't forget to like and share this video! #QuantumComputing #Multiverse #GoogleWillow #QuantumAI #Physics Google’s quantum chip solves a problem that ‘proves’ we live in a multiverse. In a groundbreaking experiment, Google’s new quantum chip, Willow, solved a computational problem in under five minutes — a task that would have taken the fastest classical supercomputers about 10 septillion years. The feat has set off a major debate: Does Willow’s success offer real proof that we live in a multiverse? Hartmut Neven, head of Google’s Quantum AI team, thinks so. He argues that the chip’s extraordinary computational power lines up perfectly with multiverse interpretations of quantum mechanics – the idea that quantum computers draw power from many parallel universes working together. This concept was first proposed by physicist David Deutsch, who suggested that quantum computations happen across a vast number of coexisting realities. Willow’s staggering achievement, some claim, is the first experimental hint that Deutsch’s theory might be right. Critics, however, aren’t convinced. They argue that other interpretations of quantum mechanics – like the Copenhagen or pilot-wave theories – could explain Willow’s success without invoking parallel worlds. They also point out that Random Circuit Sampling, the task Willow completed, was specifically designed to stress-test quantum advantage rather than to provide direct evidence of parallel universes. Still, several aspects of Willow’s performance weigh heavily in favor of the multiverse view. Its ability to hold and manipulate many quantum states simultaneously fits naturally with the idea that computations unfold across different branches of reality. The near-instant solution to a problem that should have taken septillions of years in a single universe is difficult to reconcile without invoking multiple realities at work. And decades ago, Deutsch predicted that if quantum computers ever achieved supremacy, it would be because they were operating across parallel universes – a prediction that Willow’s achievement now seems to fulfill. Proof or not, Willow has changed the conversation about reality itself.