Nov 10, 2022
433-qubit Quantum Processor Revealed
Posted by Future Timeline in categories: military, quantum physics
IBM has unveiled ‘Osprey’, the successor to its Eagle system, featuring the highest ever qubit count for a quantum processor.
Archive for the ‘quantum physics’ category: Page 370
Nov 10, 2022
IBM announces the world’s fastest quantum computer with 433 qubits
Posted by Gemechu Taye in categories: computing, military, quantum physics
Beating the previous record of 127 qubits.
IBM unveiled its most powerful quantum computer to date at the IBM Summit 2022 on Wednesday. Named “Osprey,” the 433 qubit processor has the largest qubit count of any IBM processor and is triple the size of the company’s previously record-breaking 127-qubit Eagle processor.
“The new 433 qubit ‘Osprey’ processor brings us a step closer to the point where quantum computers will be used to tackle previously unsolvable problems,” said Dr. Darío Gil, senior vice president of IBM and Director of Research.
Nov 10, 2022
Scientists use a quantum state of matter to simulate the early universe’s expansion
Posted by Gemechu Taye in categories: cosmology, evolution, particle physics, quantum physics
The scientists said their spacetime simulation “agrees very well with theory.”
A team of physicists used a “quantum field simulator” to simulate a tiny expanding universe made out of ultracold atoms, a report from VICE
Simulating spacetime.
Nov 10, 2022
IBM unveils quantum supercomputer which could reach 4,000 qubits by 2025
Posted by Dan Kummer in categories: quantum physics, supercomputing
IBM plans to move into a more modular design for future quantum computers to allow for more flexibility and rapid scale-up of qubits.
Nov 9, 2022
Cryptography’s Future Will Be Quantum-Safe. Here’s How It Will Work
Posted by Dan Breeden in categories: computing, encryption, mathematics, quantum physics, security, space
In 1994, the computer scientist Peter Shor discovered that if quantum computers were ever invented, they would decimate much of the infrastructure used to protect information shared online. That frightening possibility has had researchers scrambling to produce new, “post-quantum” encryption schemes, to save as much information as they could from falling into the hands of quantum hackers.
Earlier this year, the National Institute of Standards and Technology revealed four finalists in its search for a post-quantum cryptography standard. Three of them use “lattice cryptography” — a scheme inspired by lattices, regular arrangements of dots in space.
Lattice cryptography and other post-quantum possibilities differ from current standards in crucial ways. But they all rely on mathematical asymmetry. The security of many current cryptography systems is based on multiplication and factoring: Any computer can quickly multiply two numbers, but it could take centuries to factor a cryptographically large number into its prime constituents. That asymmetry makes secrets easy to encode but hard to decode.
Nov 9, 2022
How I Learned to Stop Worrying and Love Uncertainty
Posted by Dan Breeden in categories: education, mathematics, quantum physics
Like most physicists, I spent much of my career ignoring the majority of quantum mechanics. I was taught the theory in graduate school and applied the mechanics here and there when an interesting problem required it … and that’s about it.
Despite its fearsome reputation, the mathematics of quantum theory is actually rather straightforward. Once you get used to the ins and outs, it’s simpler to solve a wide variety of problems in quantum mechanics than it is in, say, general relativity. And that ease of computation—and the confidence that goes along with wielding the theory—mask most of the deeper issues that hide below the surface.
Deeper issues like the fact that quantum mechanics doesn’t make any sense. Yes, it’s one of the most successful (if not the most successful) theories in all of science. And yes, a typical high school education will give you all the mathematical tools you need to introduce yourself to its inner workings. And yes, for over a century we have failed to come up with an alternative theory of the subatomic universe. Those are all true statements, and yet: Quantum mechanics doesn’t make any sense.
Nov 9, 2022
Is it possible to create a universe in the laboratory
Posted by Dan Breeden in categories: quantum physics, singularity
We explore the possibility that a new universe can be created by producing a small bubble of false vacuum. The initial bubble is small enough to be produced without an initial singularity, but classically it could not become a universe — instead it would reach a maximum radius and then collapse. We investigate the possibility that quantum effects allow the bubble to tunnel into a larger bubble, of the same mass, which would then classically evolve to become a new universe. The calculation of the tunneling amplitude is attempted, in lowest order semiclassical approximation (in the thin-wall limit), using both a canonical and a functional integral approach. The canonical approach is found to have flaws, attributable to our method of space-time slicing. The functional integral approach leads to a euclidean interpolating solution that is not a manifold. To describe it, we define an object which we call a “pseudomanifold”, and give a prescription to define its action. We conjecture that the tunneling probability to produce a new universe can be approximated using this action, and we show that this leads to a plausible result.
Nov 9, 2022
A transhumanist utopia | Anders Sandberg
Posted by Dan Breeden in categories: genetics, quantum physics, transhumanism
A continuation of the enlightenment values that freed mankind of superstition.
Anders Sandberg discusses achieving a transhumanist utopia.
Continue reading “A transhumanist utopia | Anders Sandberg” »
Nov 9, 2022
IBM unveils world’s largest quantum computer at 433 qubits
Posted by Jose Ruben Rodriguez Fuentes in categories: computing, military, quantum physics
IBM’s new quantum computer, Osprey, is more than triple the size of its previous record-breaking Eagle processor.
Nov 9, 2022
Paving the Way for Satellite Quantum Communications
Posted by Saúl Morales Rodriguéz in categories: computing, encryption, quantum physics, satellites, security
A series of demonstrations by Micius—a low-orbit satellite with quantum capabilities—lays the groundwork for a satellite-based quantum communication network.
Few things have captured the scientific imagination quite like the vastness of space and the promise of quantum technology. Micius—the Chinese Academy of Science’s quantum communications satellite launched in 2016—has connected these two inspiring domains, producing a string of exciting first demonstrations in quantum space communications. Reviewing the efforts leading up to the satellite launch and the major outcomes of the mission, Jian-Wei Pan and colleagues at the University of Science and Technology of China provide a perspective on what the future of quantum space communications may look like [1]. The success of this quantum-satellite mission proves the viability of several space-based quantum communications protocols, providing a solid foundation for future improvements that may lead to an Earth-spanning quantum communications network (Fig. 1).
Photons, the quanta of light, are wonderful carriers of quantum information because they are easy to manipulate and travel extremely fast. They can be created in a desired quantum state or as the output of some quantum sensor or quantum computer. Quantum entanglement between multiple photons—the nonclassical correlation between their quantum states—can be amazingly useful in quantum communications protocols such as quantum key distribution (QKD), a cryptography approach that can theoretically guarantee absolute information security. QKD schemes have been demonstrated on distances of a few hundreds of kilometers—sufficient to cover communications networks between cities. But increasing their range, eventually to the global scale, is a formidable challenge.
