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🔬 Quantum computing is enabling new possibilities in research and science. With Dynex’s Quantum-as-a-Service (#QaaS) technology, researchers can solve real-world problems at scale with unprecedented speed and efficiency. Fields of potential Use Cases in Optimizations are: 🔹 Advanced quantum physics research. 🔹 Accelerating molecular and genetic studies in biology....

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Dynex

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13,691 Aufrufe • vor 1 Jahr •via X (Twitter)

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The World Intellectual Property Organization (World Intellectual Property Organization (WIPO)) published Dynex’s neuromorphic quantum computing patent (WO/2024/231907), marking significant progress in bridging classical and quantum paradigms. The last step of WIPO outstanding is the formal granting of the published patent, providing Dynex exclusive rights to this groundbreaking technology for up to 20 years. This innovation affirms Dynex’s affordable, accessible and scalable quantum technology powered by a decentralized computing approach. From optimization in logistics and supply chains to breakthroughs in pharmaceuticals and advanced simulations, Dynex’s newly published patent represents a key milestone in enabling real-world quantum applications at scale across industries. Discover how the Dynex’s patent is making use of neuromorphic quantum computing. Quantum: The Next Megacycle in Computing. 🔗 Read more: #QuantumMegaCycle #QuantumComputing #Innovation
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The World Intellectual Property Organization (World Intellectual Property Organization (WIPO)) published Dynex’s neuromorphic quantum computing patent (WO/2024/231907), marking significant progress in bridging classical and quantum paradigms. The last step of WIPO outstanding is the formal granting of the published patent, providing Dynex exclusive rights to this groundbreaking technology for up to 20 years. This innovation affirms Dynex’s affordable, accessible and scalable quantum technology powered by a decentralized computing approach. From optimization in logistics and supply chains to breakthroughs in pharmaceuticals and advanced simulations, Dynex’s newly published patent represents a key milestone in enabling real-world quantum applications at scale across industries. Discover how the Dynex’s patent is making use of neuromorphic quantum computing. Quantum: The Next Megacycle in Computing. 🔗 Read more: #QuantumMegaCycle #QuantumComputing #Innovation

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Computers might solve problems by sending answers from the future. New quantum research suggests it’s theoretically possible—using entanglement to send measurement info backward in time at the quantum scale. It’s probabilistic and doesn’t violate causality. This could enable instantaneous quantum computation. Not time machines—just a rethink of “before” and “after.”
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Computers might solve problems by sending answers from the future. New quantum research suggests it’s theoretically possible—using entanglement to send measurement info backward in time at the quantum scale. It’s probabilistic and doesn’t violate causality. This could enable instantaneous quantum computation. Not time machines—just a rethink of “before” and “after.”

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🚨 CHINA JUST UNVEILED THE WORLD’S FASTEST QUANTUM COMPUTER Chinese scientists have developed a new quantum computer prototype called Jiuzhang 4.0 capable of solving calculations in microseconds that would reportedly take the world’s most powerful supercomputer longer than the age of the universe to complete. The system uses photons particles of light instead of traditional electronic circuits. Why this matters: Normal computers process information step-by-step. Quantum computers can explore enormous numbers of possibilities simultaneously using quantum superposition. Jiuzhang 4.0 reportedly manipulated over 3,000 photons a massive leap from previous generations. Scientists say this breakthrough could eventually impact: • AI • cryptography • drug discovery • climate simulations • advanced materials • space technology • future physics research The real race of the 21st century may not be space… It may be quantum computation. Follow for more future technology and physics breakthroughs.
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🚨 CHINA JUST UNVEILED THE WORLD’S FASTEST QUANTUM COMPUTER Chinese scientists have developed a new quantum computer prototype called Jiuzhang 4.0 capable of solving calculations in microseconds that would reportedly take the world’s most powerful supercomputer longer than the age of the universe to complete. The system uses photons particles of light instead of traditional electronic circuits. Why this matters: Normal computers process information step-by-step. Quantum computers can explore enormous numbers of possibilities simultaneously using quantum superposition. Jiuzhang 4.0 reportedly manipulated over 3,000 photons a massive leap from previous generations. Scientists say this breakthrough could eventually impact: • AI • cryptography • drug discovery • climate simulations • advanced materials • space technology • future physics research The real race of the 21st century may not be space… It may be quantum computation. Follow for more future technology and physics breakthroughs.

TheNewPhysics

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🚨 QUANTUM BREAKTHROUGH: SCIENTISTS JUST SOLVED ONE OF PHYSICS’ BIGGEST UNSOLVED PROBLEMS. Researchers in Japan have successfully detected an elusive quantum entanglement pattern known as a “W state” something physicists have struggled to measure for decades. Why does this matter? Because W states are considered one of the key building blocks for: • quantum teleportation • ultra-secure communication • next-generation quantum internet • massively powerful quantum computers The breakthrough allows scientists to identify complex entangled photon states in a single measurement instead of using extremely slow quantum tomography. In simple terms: they found a faster way to “read” deeply entangled quantum systems. The team built a stable 3-photon optical quantum circuit capable of detecting these exotic states with high fidelity a major step toward scalable quantum networks and photonic quantum computing. This is the kind of breakthrough that moves quantum technology from fragile lab experiments… toward real-world infrastructure. The future internet may not send information through electrical signals alone. It may send reality itself through entanglement. Follow for more future physics and quantum breakthroughs.
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🚨 QUANTUM BREAKTHROUGH: SCIENTISTS JUST SOLVED ONE OF PHYSICS’ BIGGEST UNSOLVED PROBLEMS. Researchers in Japan have successfully detected an elusive quantum entanglement pattern known as a “W state” something physicists have struggled to measure for decades. Why does this matter? Because W states are considered one of the key building blocks for: • quantum teleportation • ultra-secure communication • next-generation quantum internet • massively powerful quantum computers The breakthrough allows scientists to identify complex entangled photon states in a single measurement instead of using extremely slow quantum tomography. In simple terms: they found a faster way to “read” deeply entangled quantum systems. The team built a stable 3-photon optical quantum circuit capable of detecting these exotic states with high fidelity a major step toward scalable quantum networks and photonic quantum computing. This is the kind of breakthrough that moves quantum technology from fragile lab experiments… toward real-world infrastructure. The future internet may not send information through electrical signals alone. It may send reality itself through entanglement. Follow for more future physics and quantum breakthroughs.

TheNewPhysics

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🚨Dynex Core v2 Has Arrived – Redefining Quantum Circuit Computation While most quantum platforms are still limited to executing small-scale gate circuits—often insufficient for solving real-world problems—Dynex now sets a new industry benchmark in performance, scalability, and practical utility. We are proud to announce the official rollout of Dynex Core v2, now available to all users. This new core has been rigorously stress-tested over the past several months and represents the culmination of our research and scientific work—a direct technological milestone on the path toward our proprietary Apollo chip, the first room-temperature quantum-mechanical processor. Dynex Core v2 delivers unprecedented computational power, enabling the execution of complex quantum gate circuits at sizes and speeds previously thought unattainable. It outperforms all current industry platforms—and our own previous versions—by orders of magnitude. 🔬 For example: Dynex successfully computes an n-bit quantum adder circuit with 1,222 qubits in just over 30 seconds—a level of performance never before seen in the quantum space. With Core v2, Dynex continues to lead the quantum computing revolution with real-world, scalable solutions.
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🚨Dynex Core v2 Has Arrived – Redefining Quantum Circuit Computation While most quantum platforms are still limited to executing small-scale gate circuits—often insufficient for solving real-world problems—Dynex now sets a new industry benchmark in performance, scalability, and practical utility. We are proud to announce the official rollout of Dynex Core v2, now available to all users. This new core has been rigorously stress-tested over the past several months and represents the culmination of our research and scientific work—a direct technological milestone on the path toward our proprietary Apollo chip, the first room-temperature quantum-mechanical processor. Dynex Core v2 delivers unprecedented computational power, enabling the execution of complex quantum gate circuits at sizes and speeds previously thought unattainable. It outperforms all current industry platforms—and our own previous versions—by orders of magnitude. 🔬 For example: Dynex successfully computes an n-bit quantum adder circuit with 1,222 qubits in just over 30 seconds—a level of performance never before seen in the quantum space. With Core v2, Dynex continues to lead the quantum computing revolution with real-world, scalable solutions.

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🚨 QUANTUM COMPUTING JUST HIT A NEW LEVEL Europe’s JUPITER supercomputer has reportedly achieved a world-record 50-qubit quantum simulation. That may sound small… But simulating 50 interacting qubits pushes classical computing close to its limits. Why this matters: Quantum systems become exponentially harder to simulate as they grow. At a certain point… even the most powerful traditional supercomputers struggle to predict what quantum systems are doing. That’s where quantum computing changes everything. Researchers are now building machines capable of: • simulating new materials • designing future medicines • solving optimization problems impossible for classical computers • modeling reality at the quantum level itself The race is no longer just about faster computers. It’s about building entirely new forms of computation. The next technological revolution may not run on silicon alone… but on quantum states existing in multiple possibilities at once. Follow for more future physics and quantum breakthroughs.
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🚨 QUANTUM COMPUTING JUST HIT A NEW LEVEL Europe’s JUPITER supercomputer has reportedly achieved a world-record 50-qubit quantum simulation. That may sound small… But simulating 50 interacting qubits pushes classical computing close to its limits. Why this matters: Quantum systems become exponentially harder to simulate as they grow. At a certain point… even the most powerful traditional supercomputers struggle to predict what quantum systems are doing. That’s where quantum computing changes everything. Researchers are now building machines capable of: • simulating new materials • designing future medicines • solving optimization problems impossible for classical computers • modeling reality at the quantum level itself The race is no longer just about faster computers. It’s about building entirely new forms of computation. The next technological revolution may not run on silicon alone… but on quantum states existing in multiple possibilities at once. Follow for more future physics and quantum breakthroughs.

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Most people look at Quip through the lens of post-quantum security. I think the more interesting story is happening somewhere else. Instead of asking users to learn quantum computing, Quip Network is quietly embedding quantum technology into products people can already use. Quantum randomness powers NFTs. Node operators contribute compute through simple tooling. BTC holders get access to quantum-resistant protection. Builders are already creating wallets and explorers on top of the network. Each product introduces a different piece of the quantum stack, but the user never has to understand the underlying science. That is a much harder problem to solve than building the technology itself. The real opportunity for Quip may not be making quantum computing more powerful. It may be making quantum computing invisible. Nucleus
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🚨 SCIENTISTS JUST DETECTED QUANTUM ENTANGLEMENT IN A CENTIMETER-SIZED PIECE OF METAL SOMETHING ONCE THOUGHT IMPOSSIBLE AT THIS SCALE. Researchers at the Vienna University of Technology have found clear evidence of high-degree quantum entanglement among particles inside a macroscopic crystal of a “strange metal” made of cerium, palladium, and silicon. This is one of the first times multipartite entanglement has been convincingly demonstrated in a solid object large enough to hold in your hand. Strange metals are already bizarre their electrons don’t behave like normal individual particles. Now it appears large numbers of them can act as a single, highly entangled quantum system even at everyday scales. Why this matters: • Quantum entanglement has almost always been limited to tiny numbers of particles in carefully isolated lab conditions • This experiment shows entanglement can persist collectively across a visible, macroscopic object • It was measured using neutron scattering, which revealed the material responding as one entangled system rather than many independent particles • This bridges the gap between microscopic quantum effects and real-world materials The deeper implication: For decades, physicists have wondered whether the strange, collective behavior seen in certain quantum materials could be explained by underlying entanglement. This result strongly suggests the answer is yes even at scales we can see and touch. It doesn’t mean your coffee mug is in a quantum superposition, but it does show that quantum correlations can dominate the physics of certain solids in ways we’re only beginning to understand. This kind of macroscopic quantum behavior could eventually help us design new materials with exotic properties, or give us new tools to study fundamental questions about quantum mechanics itself. How do you think discovering entanglement at this scale changes our understanding of where the quantum world ends and the classical world begins? Follow for more frontier quantum physics and materials science.
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🚨 SCIENTISTS JUST DETECTED QUANTUM ENTANGLEMENT IN A CENTIMETER-SIZED PIECE OF METAL SOMETHING ONCE THOUGHT IMPOSSIBLE AT THIS SCALE. Researchers at the Vienna University of Technology have found clear evidence of high-degree quantum entanglement among particles inside a macroscopic crystal of a “strange metal” made of cerium, palladium, and silicon. This is one of the first times multipartite entanglement has been convincingly demonstrated in a solid object large enough to hold in your hand. Strange metals are already bizarre their electrons don’t behave like normal individual particles. Now it appears large numbers of them can act as a single, highly entangled quantum system even at everyday scales. Why this matters: • Quantum entanglement has almost always been limited to tiny numbers of particles in carefully isolated lab conditions • This experiment shows entanglement can persist collectively across a visible, macroscopic object • It was measured using neutron scattering, which revealed the material responding as one entangled system rather than many independent particles • This bridges the gap between microscopic quantum effects and real-world materials The deeper implication: For decades, physicists have wondered whether the strange, collective behavior seen in certain quantum materials could be explained by underlying entanglement. This result strongly suggests the answer is yes even at scales we can see and touch. It doesn’t mean your coffee mug is in a quantum superposition, but it does show that quantum correlations can dominate the physics of certain solids in ways we’re only beginning to understand. This kind of macroscopic quantum behavior could eventually help us design new materials with exotic properties, or give us new tools to study fundamental questions about quantum mechanics itself. How do you think discovering entanglement at this scale changes our understanding of where the quantum world ends and the classical world begins? Follow for more frontier quantum physics and materials science.

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With support from U.S. Department of Commerce, IBM is announcing its plans for Anderon, America’s first quantum foundry that will accelerate American quantum leadership and enable advanced quantum wafer manufacturing. This initiative marks one of the most significant commitments from the U.S. government in quantum R&D to date, and is poised to fuel American economic growth and quantum innovation. Learn more here:
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With support from U.S. Department of Commerce, IBM is announcing its plans for Anderon, America’s first quantum foundry that will accelerate American quantum leadership and enable advanced quantum wafer manufacturing. This initiative marks one of the most significant commitments from the U.S. government in quantum R&D to date, and is poised to fuel American economic growth and quantum innovation. Learn more here:

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🚨 BREAKING NEWS 🚨 SCIENTISTS JUST TELEPORTED QUANTUM INFORMATION THROUGH THE EXISTING INTERNET. Not in a lab vacuum. Not through a special quantum-only cable. They did it through real internet fiber while normal internet traffic (400 Gbps) was still flowing. Researchers at Northwestern University successfully transmitted a quantum state of light across 30 km of active fiber optic cable, proving quantum signals can coexist with the classical internet we already use. Why this matters: Today’s internet moves classical bits. A quantum internet could enable virtually unhackable communication, distributed quantum computing, and ultra-secure networks. Quantum information cannot be copied without disturbing it a built-in security feature. The deeper implication: The internet may evolve from moving classical information into moving quantum states themselves. At that point, the line between communication and computation begins to disappear. We may be watching the early construction of an entirely new layer of civilization. Follow for more frontier physics and future technology.
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🚨 BREAKING NEWS 🚨 SCIENTISTS JUST TELEPORTED QUANTUM INFORMATION THROUGH THE EXISTING INTERNET. Not in a lab vacuum. Not through a special quantum-only cable. They did it through real internet fiber while normal internet traffic (400 Gbps) was still flowing. Researchers at Northwestern University successfully transmitted a quantum state of light across 30 km of active fiber optic cable, proving quantum signals can coexist with the classical internet we already use. Why this matters: Today’s internet moves classical bits. A quantum internet could enable virtually unhackable communication, distributed quantum computing, and ultra-secure networks. Quantum information cannot be copied without disturbing it a built-in security feature. The deeper implication: The internet may evolve from moving classical information into moving quantum states themselves. At that point, the line between communication and computation begins to disappear. We may be watching the early construction of an entirely new layer of civilization. Follow for more frontier physics and future technology.

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🚨 AI JUST DISCOVERED QUANTUM EFFECTS THAT SCIENTISTS DIDN'T KNOW EXIST. Researchers at the University of Washington used artificial intelligence to simulate dozens of atomically thin sheets of molybdenum ditelluride stacked in precise twisted patterns. At small scales, these materials look relatively ordinary. But when the AI modeled much larger stacks, completely new quantum behaviors emerged phenomena that only exist because of the complex, repeating moiré patterns formed across many layers. Why this matters: • Many of the most interesting quantum effects only appear at scales that are too large for traditional supercomputers to simulate • AI can act as a fast “surrogate” that learns from smaller calculations and predicts behavior at much bigger scales • These large-scale moiré systems can host exotic quantum states useful for quantum computing and new types of electronics • The same approach could be used to discover many other hidden quantum materials The deeper implication: We are entering an era where AI doesn’t just help us analyze data it helps us discover entirely new quantum phenomena that were previously invisible because they only exist in systems too complex for conventional modeling. This could dramatically speed up the search for materials that power future quantum technologies. What do you find more exciting using AI to uncover hidden quantum effects in materials, or the possibility that these stacked atomic sheets could become building blocks for future quantum computers? Follow for more frontier quantum materials and AI-driven discovery.
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🚨 AI JUST DISCOVERED QUANTUM EFFECTS THAT SCIENTISTS DIDN'T KNOW EXIST. Researchers at the University of Washington used artificial intelligence to simulate dozens of atomically thin sheets of molybdenum ditelluride stacked in precise twisted patterns. At small scales, these materials look relatively ordinary. But when the AI modeled much larger stacks, completely new quantum behaviors emerged phenomena that only exist because of the complex, repeating moiré patterns formed across many layers. Why this matters: • Many of the most interesting quantum effects only appear at scales that are too large for traditional supercomputers to simulate • AI can act as a fast “surrogate” that learns from smaller calculations and predicts behavior at much bigger scales • These large-scale moiré systems can host exotic quantum states useful for quantum computing and new types of electronics • The same approach could be used to discover many other hidden quantum materials The deeper implication: We are entering an era where AI doesn’t just help us analyze data it helps us discover entirely new quantum phenomena that were previously invisible because they only exist in systems too complex for conventional modeling. This could dramatically speed up the search for materials that power future quantum technologies. What do you find more exciting using AI to uncover hidden quantum effects in materials, or the possibility that these stacked atomic sheets could become building blocks for future quantum computers? Follow for more frontier quantum materials and AI-driven discovery.

TheNewPhysics

29,224 Aufrufe • vor 15 Tagen

🚨 CHINA JUST ACTIVATED A MAGNET 700,000× STRONGER THAN EARTH’S MAGNETIC FIELD Chinese scientists have powered up a superconducting research magnet reaching 35.6 tesla one of the strongest sustained magnetic fields ever created. For comparison: • Earth’s magnetic field ≈ 0.00005 tesla • Hospital MRI ≈ 1.5–3 tesla • This new system = 35.6 tesla And it can reportedly maintain that field for over 200 hours continuously. Why this matters: Extreme magnetic fields allow scientists to explore matter under conditions almost impossible to reproduce naturally. This could help advance: • superconductors • quantum materials • fusion research • next-generation electronics • exotic states of matter • ultra-precise molecular imaging At these field strengths, materials can begin behaving in completely unexpected ways. Electrons reorganize. Quantum effects dominate. Normal physics starts looking abnormal. The race for stronger magnetic fields is becoming a race to unlock entirely new physics. Humanity is no longer just observing extreme conditions in the universe. We’re beginning to manufacture them on Earth. Follow for more future science and technology breakthroughs.
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🚨 CHINA JUST ACTIVATED A MAGNET 700,000× STRONGER THAN EARTH’S MAGNETIC FIELD Chinese scientists have powered up a superconducting research magnet reaching 35.6 tesla one of the strongest sustained magnetic fields ever created. For comparison: • Earth’s magnetic field ≈ 0.00005 tesla • Hospital MRI ≈ 1.5–3 tesla • This new system = 35.6 tesla And it can reportedly maintain that field for over 200 hours continuously. Why this matters: Extreme magnetic fields allow scientists to explore matter under conditions almost impossible to reproduce naturally. This could help advance: • superconductors • quantum materials • fusion research • next-generation electronics • exotic states of matter • ultra-precise molecular imaging At these field strengths, materials can begin behaving in completely unexpected ways. Electrons reorganize. Quantum effects dominate. Normal physics starts looking abnormal. The race for stronger magnetic fields is becoming a race to unlock entirely new physics. Humanity is no longer just observing extreme conditions in the universe. We’re beginning to manufacture them on Earth. Follow for more future science and technology breakthroughs.

TheNewPhysics

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🚨 SCIENTISTS MAY HAVE FOUND A CHEAPER PATH TO QUANTUM COMPUTERS AND IT LOOKS LIKE A HONEYCOMB. Researchers in Japan created tiny cobalt honeycomb structures that show the exact magnetic behavior scientists have been chasing for next-generation quantum materials. Why this matters: Today’s most promising quantum materials rely on rare and expensive elements like iridium and ruthenium. This new approach uses cobalt —l one of the most common metals on Earth. The result: • Strong quantum magnetic interactions • Potential spin-liquid states • Dramatically lower cost • Easier manufacturing at scale The deeper implication is fascinating: Nature keeps reusing the same geometry. Honeycombs appear in beehives, in graphene… and now they may help build the quantum computers of the future. Sometimes the next technological revolution isn’t hidden in a new rare element it’s hidden in a smarter pattern. Could the future of quantum computing be built from one of Earth’s most common metals? Follow for more frontier physics.
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🚨 SCIENTISTS MAY HAVE FOUND A CHEAPER PATH TO QUANTUM COMPUTERS AND IT LOOKS LIKE A HONEYCOMB. Researchers in Japan created tiny cobalt honeycomb structures that show the exact magnetic behavior scientists have been chasing for next-generation quantum materials. Why this matters: Today’s most promising quantum materials rely on rare and expensive elements like iridium and ruthenium. This new approach uses cobalt —l one of the most common metals on Earth. The result: • Strong quantum magnetic interactions • Potential spin-liquid states • Dramatically lower cost • Easier manufacturing at scale The deeper implication is fascinating: Nature keeps reusing the same geometry. Honeycombs appear in beehives, in graphene… and now they may help build the quantum computers of the future. Sometimes the next technological revolution isn’t hidden in a new rare element it’s hidden in a smarter pattern. Could the future of quantum computing be built from one of Earth’s most common metals? Follow for more frontier physics.

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🚨BREAKING: INTERLINK TO DEVELOP QUANTUM-RESISTANT BLOCKCHAIN TECH According to a new post from KV, InterLink Labs 👤 + 🌐... "will build a dedicated research team of leading cryptography experts to study and develop quantum-resistant technology" The move is a response to the growing threat of quantum technology to $BTC and other crypto assets. The project hopes to incorporate quantum-resistant infrastructure into its upcoming mainnet, to help secure its $ITL and $ITLG tokens. "Our goal is to build one of the most quantum-secure digital assets in the world"
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🚨BREAKING: INTERLINK TO DEVELOP QUANTUM-RESISTANT BLOCKCHAIN TECH According to a new post from KV, InterLink Labs 👤 + 🌐... "will build a dedicated research team of leading cryptography experts to study and develop quantum-resistant technology" The move is a response to the growing threat of quantum technology to $BTC and other crypto assets. The project hopes to incorporate quantum-resistant infrastructure into its upcoming mainnet, to help secure its $ITL and $ITLG tokens. "Our goal is to build one of the most quantum-secure digital assets in the world"

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Scientists revealed the exact shape of a photon: a 3D field emerging from an atom. For decades, we only had approximate models of light and matter. Now, with precise equations, we unlock potential for quantum computers, advanced solar panels, and more. Read more - #QuantumPhysics #FutureTech #Science #CleanEnergy
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Scientists revealed the exact shape of a photon: a 3D field emerging from an atom. For decades, we only had approximate models of light and matter. Now, with precise equations, we unlock potential for quantum computers, advanced solar panels, and more. Read more - #QuantumPhysics #FutureTech #Science #CleanEnergy

Nassim Haramein

80,679 Aufrufe • vor 8 Monaten

🚨 QUANTUM PHYSICS SAYS OBSERVATION CAN CHANGE REALITY. One of the strangest discoveries in modern physics is that particles behave differently when they are measured or observed. In famous experiments like the double-slit experiment: Particles act like waves… until they are observed. Then suddenly they behave like solid particles. In simple terms: Reality at the quantum level does not appear fully “decided” until interaction happens. Why this matters: Scientists are still trying to understand: • what observation actually means • how information affects quantum systems • whether consciousness plays any role • how reality transitions from quantum to classical physics This is also deeply connected to: • quantum computing • encryption • teleportation research • quantum sensors • future AI systems • our understanding of reality itself The strangest part? At the deepest scales of nature… The universe may behave less like a machine and more like a probability field waiting to crystallize into events. Follow for more future physics and technology breakthroughs.
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🚨 QUANTUM PHYSICS SAYS OBSERVATION CAN CHANGE REALITY. One of the strangest discoveries in modern physics is that particles behave differently when they are measured or observed. In famous experiments like the double-slit experiment: Particles act like waves… until they are observed. Then suddenly they behave like solid particles. In simple terms: Reality at the quantum level does not appear fully “decided” until interaction happens. Why this matters: Scientists are still trying to understand: • what observation actually means • how information affects quantum systems • whether consciousness plays any role • how reality transitions from quantum to classical physics This is also deeply connected to: • quantum computing • encryption • teleportation research • quantum sensors • future AI systems • our understanding of reality itself The strangest part? At the deepest scales of nature… The universe may behave less like a machine and more like a probability field waiting to crystallize into events. Follow for more future physics and technology breakthroughs.

TheNewPhysics

102,274 Aufrufe • vor 1 Monat

🚨 BREAKING: Human cells may behave far more like quantum systems than we ever imagined. New research suggests biological cells process information in ways surprisingly similar to quantum computers. Your body already runs on electrical signaling. But scientists are now exploring whether quantum-like effects help coordinate biological processes at microscopic scales. That changes the question completely: Maybe consciousness, memory, and cellular communication are not just chemical reactions… but emergent information fields operating across complex electrical networks. Nature may have discovered quantum optimization billions of years before humans built quantum computers. If true, biology itself could become the blueprint for the next generation of computing. We might not be building machines to mimic humans. We may be rediscovering the physics life has been using all along. Follow for more breakthroughs where physics, biology, and computation collide.
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🚨 BREAKING: Human cells may behave far more like quantum systems than we ever imagined. New research suggests biological cells process information in ways surprisingly similar to quantum computers. Your body already runs on electrical signaling. But scientists are now exploring whether quantum-like effects help coordinate biological processes at microscopic scales. That changes the question completely: Maybe consciousness, memory, and cellular communication are not just chemical reactions… but emergent information fields operating across complex electrical networks. Nature may have discovered quantum optimization billions of years before humans built quantum computers. If true, biology itself could become the blueprint for the next generation of computing. We might not be building machines to mimic humans. We may be rediscovering the physics life has been using all along. Follow for more breakthroughs where physics, biology, and computation collide.

TheNewPhysics

12,200 Aufrufe • vor 1 Monat

🚨 JAPAN JUST PUT A REAL QUANTUM COMPUTER ONLINE FOR THE WORLD TO ACCESS. And most people still don’t realize how big this moment is. For decades, quantum computers sounded like science fiction: machines that use quantum states instead of ordinary binary bits. Now researchers in Japan have opened access to a real superconducting quantum system connected to the internet. Why this matters: • quantum simulations • next-generation AI research • new material discovery • drug development • cryptography disruption • solving problems impossible for classical computers But quantum computers work nothing like normal machines. A regular computer checks possibilities one at a time. A quantum computer can explore many probability states simultaneously through superposition and entanglement. In simple terms: It doesn’t just calculate faster… It calculates differently. That’s why these systems look so strange. The giant gold structure isn’t “the computer” itself. It’s an ultra-cold dilution refrigerator designed to keep the quantum processor near absolute zero so fragile quantum states don’t collapse. The terrifying implication is this: Humanity may be entering the first era where computation starts operating on the rules of quantum reality itself. And once quantum hardware becomes scalable… Entire industries may be rewritten from the ground up. What happens when computers stop thinking like machines… and start behaving like physics itself? Which field do you think gets transformed first and would you actually trust it with something important?
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🚨 JAPAN JUST PUT A REAL QUANTUM COMPUTER ONLINE FOR THE WORLD TO ACCESS. And most people still don’t realize how big this moment is. For decades, quantum computers sounded like science fiction: machines that use quantum states instead of ordinary binary bits. Now researchers in Japan have opened access to a real superconducting quantum system connected to the internet. Why this matters: • quantum simulations • next-generation AI research • new material discovery • drug development • cryptography disruption • solving problems impossible for classical computers But quantum computers work nothing like normal machines. A regular computer checks possibilities one at a time. A quantum computer can explore many probability states simultaneously through superposition and entanglement. In simple terms: It doesn’t just calculate faster… It calculates differently. That’s why these systems look so strange. The giant gold structure isn’t “the computer” itself. It’s an ultra-cold dilution refrigerator designed to keep the quantum processor near absolute zero so fragile quantum states don’t collapse. The terrifying implication is this: Humanity may be entering the first era where computation starts operating on the rules of quantum reality itself. And once quantum hardware becomes scalable… Entire industries may be rewritten from the ground up. What happens when computers stop thinking like machines… and start behaving like physics itself? Which field do you think gets transformed first and would you actually trust it with something important?

Paul White Gold Eagle

55,784 Aufrufe • vor 1 Monat

🚨 SCIENTISTS JUST REPROGRAMMED MATTER AT THE ATOMIC LEVEL MIT researchers have shattered a 40-year-old record by moving tens of thousands of atoms inside a material using a focused electron beam. Not in simulations. In real physical matter. The breakthrough allowed scientists to generate over 40,000 quantum defects in just 40 minutes compared to the famous IBM experiment in the 1980s that moved only 35 atoms. But this changes far more than speed. For the first time, researchers can precisely reposition atoms: • In 3 dimensions • At room temperature • Inside solid materials themselves Using a beam controlled with picometer precision, they literally “push” columns of atoms through a crystal like swiping icons on a phone screen. Why this matters: • It could enable programmable matter • Build stable quantum devices • Create entirely new material properties • Unlock exotic quantum states on demand • Rewrite how future computers and sensors are built The wildest part? The defects themselves become the technology. Scientists are no longer just discovering materials. They are beginning to engineer reality atom by atom. Follow for more future physics and quantum breakthroughs.
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🚨 SCIENTISTS JUST REPROGRAMMED MATTER AT THE ATOMIC LEVEL MIT researchers have shattered a 40-year-old record by moving tens of thousands of atoms inside a material using a focused electron beam. Not in simulations. In real physical matter. The breakthrough allowed scientists to generate over 40,000 quantum defects in just 40 minutes compared to the famous IBM experiment in the 1980s that moved only 35 atoms. But this changes far more than speed. For the first time, researchers can precisely reposition atoms: • In 3 dimensions • At room temperature • Inside solid materials themselves Using a beam controlled with picometer precision, they literally “push” columns of atoms through a crystal like swiping icons on a phone screen. Why this matters: • It could enable programmable matter • Build stable quantum devices • Create entirely new material properties • Unlock exotic quantum states on demand • Rewrite how future computers and sensors are built The wildest part? The defects themselves become the technology. Scientists are no longer just discovering materials. They are beginning to engineer reality atom by atom. Follow for more future physics and quantum breakthroughs.

TheNewPhysics

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