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Using random circuit sampling (RCS), we've demonstrated that quantum computers can outperform classical supercomputers, even with noise. This 'beyond classical' capability is possible because qubits can exist in multiple states at once, giving quantum computers an edge.

Google Quantum AI

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64,089 次观看 • 1 年前 •via X (Twitter)

Anya Rossi• Live Now

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Cryptodutch ⚡️ 的头像

Cryptodutch ⚡️1 年前

Blockchain will be in a huge danger soon. $CELL is the only Post-Quantum blockchain that will be resistance of QC. 4 layers of Post-Quantum. 18 mil mc & will make huge movesz Such a no brainer

🗝️ChRθηθδ 🦋✨ C E O @ P A P I L L O N 的头像

🗝️ChRθηθδ 🦋✨ C E O @ P A P I L L O N1 年前

💙🦋🚀

Fred 的头像

Fred1 年前

No. It is false statement. Using random circuit, google shown it is possible to design a system for quantum which takes longer for classic. Unfortunately, Scott only damaged this field with CS mentality.

Headline Hungama 的头像

Headline Hungama1 年前

This breakthrough underscores the immense potential of quantum computing to tackle problems that are intractable for even the most powerful classical supercomputers.

Sun's Son Music 的头像

Sun's Son Music1 年前

👍🏻It's really about time.🤷🏻

David Makola 的头像

David Makola1 年前

@GoogleAI Hi, I'm David Makola, I'm a creator and conceptor of new technologies. I've created a new software system for Android and Pixel, which allows the user to use and handle smartphone with his mind(thoughts). I've applied at Google Jobs in Mountain View. I'm waiting to work with you

Caduceus 的头像

Caduceus1 年前

Impressive advancements! 🚀 At #Caduceus, our platform's edge-rendering capabilities and #AI-driven infrastructure are built to support such breakthroughs. From DePIN to #aigc and beyond, we're here to power the next frontier in decentralized applications. Welcome aboard the future! 🌐✨

FiveRivers Technologies 的头像

FiveRivers Technologies1 年前

Incredible progress! Seeing quantum computers achieve 'beyond classical' performance, even with noise, highlights their potential to tackle problems once thought impossible.

相关视频

QUANTUM COMPUTERS DON’T THINK FASTER - THEY THINK EVERYTHING AT ONCE A classical computer tests each possibility one at a time. A quantum computer? It runs every possibility simultaneously. With 20 qubits, it can process a million outcomes at once. With 300 qubits, it could match the number of particles in the observable universe. Now that’s next-level computing. Source: Everysci24

QUANTUM COMPUTERS DON’T THINK FASTER - THEY THINK EVERYTHING AT ONCE A classical computer tests each possibility one at a time. A quantum computer? It runs every possibility simultaneously. With 20 qubits, it can process a million outcomes at once. With 300 qubits, it could match the number of particles in the observable universe. Now that’s next-level computing. Source: Everysci24

Mario Nawfal

154,890 次观看 • 10 个月前

Random Circuit Sampling (RCS) is a necessary benchmark to measure quantum computer performance in the presence of noise. Why is RCS considered a cornerstone of quantum computing? Find out in our latest breakdown. #QuantumAI

Random Circuit Sampling (RCS) is a necessary benchmark to measure quantum computer performance in the presence of noise. Why is RCS considered a cornerstone of quantum computing? Find out in our latest breakdown. #QuantumAI

Google Quantum AI

11,807 次观看 • 1 年前

"We have demonstrated the ability to solve important problems in the area of material simulation on our quantum computers today in minutes that it would take well over millions of years to solve on classical computers," D-Wave CEO Alan Baratz says.

"We have demonstrated the ability to solve important problems in the area of material simulation on our quantum computers today in minutes that it would take well over millions of years to solve on classical computers," D-Wave CEO Alan Baratz says.

Yahoo Finance

18,132 次观看 • 1 年前

Microsoft just had the biggest breakthrough in Quantum computing! Meet Majorana 1 - a chip that can perform incredibly complex calculations that would be impossible for even the largest classical computers… and I got to see it in person!!

Microsoft just had the biggest breakthrough in Quantum computing! Meet Majorana 1 - a chip that can perform incredibly complex calculations that would be impossible for even the largest classical computers… and I got to see it in person!!

iJustine

569,001 次观看 • 1 年前

🚨INSIDE THE LAB THAT MAKES COMPUTING COLDER THAN SPACE The sound hits first, a constant rumble from refrigeration systems working to cool quantum chips to temperatures colder than space itself. These aren’t your everyday computers. They operate near absolute zero, where atoms barely move and quantum rules take over. At the center is a chip packed with a thousand qubits. Nearby, AI supercomputers and classical machines work in tandem, each playing a role in processing power beyond today’s standards. Bits, neurons, and qubits, once separate, now converge in one cold, humming room built for the future. Source: FORTUNE

🚨INSIDE THE LAB THAT MAKES COMPUTING COLDER THAN SPACE The sound hits first, a constant rumble from refrigeration systems working to cool quantum chips to temperatures colder than space itself. These aren’t your everyday computers. They operate near absolute zero, where atoms barely move and quantum rules take over. At the center is a chip packed with a thousand qubits. Nearby, AI supercomputers and classical machines work in tandem, each playing a role in processing power beyond today’s standards. Bits, neurons, and qubits, once separate, now converge in one cold, humming room built for the future. Source: FORTUNE

Mario Nawfal

65,157 次观看 • 11 个月前

This is what separates quantum from classical computing... D-Wave, $QBTS, used their quantum computer to compute properties of magnetic materials in just minutes—a task that would require more than the world’s annual energy on a classical machine. “We are able to solve problems on our quantum computers that cannot be solved classically.” - Alan Baratz, CEO of D-Wave 🗣️

This is what separates quantum from classical computing... D-Wave, $QBTS, used their quantum computer to compute properties of magnetic materials in just minutes—a task that would require more than the world’s annual energy on a classical machine. “We are able to solve problems on our quantum computers that cannot be solved classically.” - Alan Baratz, CEO of D-Wave 🗣️

Stocktwits

29,311 次观看 • 10 个月前

Our team ran a verifiable quantum algorithm that probes how parts of a quantum system interact, from molecules to magnets and beyond. On our Willow chip, it ran 13,000× faster than the best classical supercomputers. A first in quantum computing →

Our team ran a verifiable quantum algorithm that probes how parts of a quantum system interact, from molecules to magnets and beyond. On our Willow chip, it ran 13,000× faster than the best classical supercomputers. A first in quantum computing →

Google Quantum AI

63,555 次观看 • 1 个月前

JOE ROGAN: DO QUANTUM COMPUTERS PROVE THE MULTIVERSE EXISTS? "There's an equation that quantum computers solve quickly, like in a couple of minutes, that if you converted the entire universe into a computer, it would take so much time to solve this equation that the universe would die of heat death. And these quantum computers can solve it in minutes. They believe this is proof of the multiverse, that this quantum computer is somehow connected to other sources of computing power in an infinite number of universes." Source: Joe Rogan Experience

JOE ROGAN: DO QUANTUM COMPUTERS PROVE THE MULTIVERSE EXISTS? "There's an equation that quantum computers solve quickly, like in a couple of minutes, that if you converted the entire universe into a computer, it would take so much time to solve this equation that the universe would die of heat death. And these quantum computers can solve it in minutes. They believe this is proof of the multiverse, that this quantum computer is somehow connected to other sources of computing power in an infinite number of universes." Source: Joe Rogan Experience

Mario Nawfal

65,696 次观看 • 1 年前

Using the BLUEPRINT of reality? Classical computers compute with BITS: 0 or 1 - ONE state at a time. Quantum computers use QUBITS: 0 and 1 or both "simultaneously" through superposition. These states EVOLVE continuously on something like a Bloch sphere - the same MATHEMATICS that describes spin, atoms and electron orbitals. The GEOMETRY feels familiar. Wheels within wheels. Computation, now operating in the rule-set of REALITY itself. Engineering in the same language of nature. THIS is a profound shift. So what follows? 📽 credits: uncover.quantum

Using the BLUEPRINT of reality? Classical computers compute with BITS: 0 or 1 - ONE state at a time. Quantum computers use QUBITS: 0 and 1 or both "simultaneously" through superposition. These states EVOLVE continuously on something like a Bloch sphere - the same MATHEMATICS that describes spin, atoms and electron orbitals. The GEOMETRY feels familiar. Wheels within wheels. Computation, now operating in the rule-set of REALITY itself. Engineering in the same language of nature. THIS is a profound shift. So what follows? 📽 credits: uncover.quantum

WhatdoIknow

19,029 次观看 • 3 个月前

Why is this important to us "normal folk"? Because quantum computers will create innovations exponentially faster than regular computers. A few possibilities: • Quantum machine learning for AI • Optimizing traffic flow in smart cities ↓

Why is this important to us "normal folk"? Because quantum computers will create innovations exponentially faster than regular computers. A few possibilities: • Quantum machine learning for AI • Optimizing traffic flow in smart cities ↓

Kevin Joey Chen

326,514 次观看 • 1 年前

QUANTUM COMPUTING: THE FUTURE IS NOW IBM recently announced a quantum computer capable of solving problems in minutes that would take today's supercomputers millions of years. Developed by IBM, Google, and others, quantum computers push the boundaries of science and engineering, utilizing atomic forces to achieve unprecedented computational power. A simple maze shows how quantum computing can outpace classic computers. Michio Kaku: “All the big boys who are in this race to create a workable, operationally efficient quantum computer because the nation or company that does this will rule the world economy.” Source: 60 Minutes

QUANTUM COMPUTING: THE FUTURE IS NOW IBM recently announced a quantum computer capable of solving problems in minutes that would take today's supercomputers millions of years. Developed by IBM, Google, and others, quantum computers push the boundaries of science and engineering, utilizing atomic forces to achieve unprecedented computational power. A simple maze shows how quantum computing can outpace classic computers. Michio Kaku: “All the big boys who are in this race to create a workable, operationally efficient quantum computer because the nation or company that does this will rule the world economy.” Source: 60 Minutes

Mario Nawfal

327,790 次观看 • 1 年前

Can you program a quantum computer only using pi? To celebrate pi day 2026, in this video I go through the paper "All You Need is pi: Quantum Computing with Hermitian Gates", which shows that you can construct any quantum computing operations out of quantum operations that have the special property of undoing themselves ("Hermitian gates") — and for single-qubit gates, these are entirely made of rotations of an angle of pi! Happy Pi Day 🥧 *Timestamps* 0:00 Intro 1:03 Single qubits & gates 3:11 Gates on many qubits 3:58 Quantum circuit diagrams 4:44 Universal gate set 5:54 Self-reverse gates (Hermitian) 8:08 All you need is pi? 10:14 Decomposing gates 13:14 Hardware pi pulses 14:28 Clocked quantum computers

Can you program a quantum computer only using pi? To celebrate pi day 2026, in this video I go through the paper "All You Need is pi: Quantum Computing with Hermitian Gates", which shows that you can construct any quantum computing operations out of quantum operations that have the special property of undoing themselves ("Hermitian gates") — and for single-qubit gates, these are entirely made of rotations of an angle of pi! Happy Pi Day 🥧 Timestamps 0:00 Intro 1:03 Single qubits & gates 3:11 Gates on many qubits 3:58 Quantum circuit diagrams 4:44 Universal gate set 5:54 Self-reverse gates (Hermitian) 8:08 All you need is pi? 10:14 Decomposing gates 13:14 Hardware pi pulses 14:28 Clocked quantum computers

Dr Maria Violaris

18,011 次观看 • 2 个月前

What happens once AI and Quantum computers are combined?

What happens once AI and Quantum computers are combined?

Johnny

464,152 次观看 • 1 年前

Quantum computers

Quantum computers

mrredpillz jokaqarmy

48,785 次观看 • 1 年前

6,100-Qubit Processor Shatters Quantum Computing Record | David Nield, ScienceAlert Another major quantum computing record has been broken, and by a considerable margin: physicists have now built an array containing 6,100 qubits, the largest of its type and way above the thousand or so qubits previous systems contained. It's the work of scientists from the California Institute of Technology, who used cesium atoms as their qubits, trapping them in place with a complex system of lasers that acted as tweezers to keep the atoms as stable as possible. Qubits differ from the classical bits of traditional computers by exploiting what's known as a superposition: not just binary states of 1 or 0, but a spread of probabilities that allows for algorithms that can solve problems considered out of reach of conventional computing methods. Related: Quantum Advantage: A Physicist Explains The Future of Computers A lot of qubits will be needed to make quantum algorithms practical, however. One reason for these large arrays is error correction, which helps overcome the inherent fragility of the qubit by providing a surplus to double-check the machine's operation. "This is an exciting moment for neutral-atom quantum computing," says physicist Manuel Endres. "We can now see a pathway to large error-corrected quantum computers. The building blocks are in place." There was no single breakthrough that enabled this jump in qubit numbers, but rather a series of engineering advancements in many key areas – from the laser tweezers to the ultra-high (very low pressure) vacuum chamber. Stability has also been a problem for quantum computing systems. The innovations in this latest array kept qubits in a superposition state for almost 13 seconds – almost ten times longer than previous configurations had managed. What's more, individual qubits could be manipulated with 99.98 percent accuracy, establishing a significant benchmark in the programmability of quantum technology. "Large scale, with more atoms, is often thought to come at the expense of accuracy, but our results show that we can do both," says physicist Gyohei Nomura. "Qubits aren't useful without quality. Now we have quantity and quality." To make quantum computers a practical alternative to modern supercomputers, more qubits and even greater levels of stability will be required. Experts are tackling the problem from several different angles, which is why records for some types of quantum computer don't necessarily apply to others. Next, the researchers need to work on exploiting entanglement, which will enable the system to make the leap from storing information to actually processing it. Not too far in the future, we could be using these computers to discover new materials, matter, and fundamental laws of physics. "It's exciting that we are creating machines to help us learn about the Universe in ways that only quantum mechanics can teach us," says physicist Hannah Manetsch. Read more:

6,100-Qubit Processor Shatters Quantum Computing Record | David Nield, ScienceAlert Another major quantum computing record has been broken, and by a considerable margin: physicists have now built an array containing 6,100 qubits, the largest of its type and way above the thousand or so qubits previous systems contained. It's the work of scientists from the California Institute of Technology, who used cesium atoms as their qubits, trapping them in place with a complex system of lasers that acted as tweezers to keep the atoms as stable as possible. Qubits differ from the classical bits of traditional computers by exploiting what's known as a superposition: not just binary states of 1 or 0, but a spread of probabilities that allows for algorithms that can solve problems considered out of reach of conventional computing methods. Related: Quantum Advantage: A Physicist Explains The Future of Computers A lot of qubits will be needed to make quantum algorithms practical, however. One reason for these large arrays is error correction, which helps overcome the inherent fragility of the qubit by providing a surplus to double-check the machine's operation. "This is an exciting moment for neutral-atom quantum computing," says physicist Manuel Endres. "We can now see a pathway to large error-corrected quantum computers. The building blocks are in place." There was no single breakthrough that enabled this jump in qubit numbers, but rather a series of engineering advancements in many key areas – from the laser tweezers to the ultra-high (very low pressure) vacuum chamber. Stability has also been a problem for quantum computing systems. The innovations in this latest array kept qubits in a superposition state for almost 13 seconds – almost ten times longer than previous configurations had managed. What's more, individual qubits could be manipulated with 99.98 percent accuracy, establishing a significant benchmark in the programmability of quantum technology. "Large scale, with more atoms, is often thought to come at the expense of accuracy, but our results show that we can do both," says physicist Gyohei Nomura. "Qubits aren't useful without quality. Now we have quantity and quality." To make quantum computers a practical alternative to modern supercomputers, more qubits and even greater levels of stability will be required. Experts are tackling the problem from several different angles, which is why records for some types of quantum computer don't necessarily apply to others. Next, the researchers need to work on exploiting entanglement, which will enable the system to make the leap from storing information to actually processing it. Not too far in the future, we could be using these computers to discover new materials, matter, and fundamental laws of physics. "It's exciting that we are creating machines to help us learn about the Universe in ways that only quantum mechanics can teach us," says physicist Hannah Manetsch. Read more:

Owen Gregorian

43,078 次观看 • 8 个月前

Quantum computers can search billions of outcomes at once—solving problems once thought impossible, especially when paired with AI. From drug discovery to climate modeling, the impact is going to be huge.

Quantum computers can search billions of outcomes at once—solving problems once thought impossible, especially when paired with AI. From drug discovery to climate modeling, the impact is going to be huge.

Chelsea L. Andrews ✨

23,622 次观看 • 9 个月前

Building quantum computers faces a core challenge: control qubits without losing info. Hear from Yu Chen, Director, Quantum Processor, on the “secret sauce” behind Willow. It let Quantum Echoes run 13,000x faster, a verifiable quantum advantage. Read →

Building quantum computers faces a core challenge: control qubits without losing info. Hear from Yu Chen, Director, Quantum Processor, on the “secret sauce” behind Willow. It let Quantum Echoes run 13,000x faster, a verifiable quantum advantage. Read →

Google Quantum AI

34,898 次观看 • 7 个月前

DARPA researchers make #quantum computing breakthrough creating first-ever quantum circuit with logical quantum bits (qubits), a key discovery that could accelerate fault-tolerant quantum computing & revolutionize designs for quantum computer processors:

DARPA researchers make #quantum computing breakthrough creating first-ever quantum circuit with logical quantum bits (qubits), a key discovery that could accelerate fault-tolerant quantum computing & revolutionize designs for quantum computer processors:

DARPA

262,792 次观看 • 2 年前