Amazing Breakthrough in Physics: Quantum computer makes first high-energy physics simulation

The technique would help address problems that classical computers can't handle.

Physicists have performed the first full simulation of a high-energy physics experiment — the creation of pairs of particles and their antiparticles — on a quantum computer. If the team can scale it up, the technique promises access to calculations that would be too complex for an ordinary computer to deal with.

To understand exactly what their theories predict, physicists routinely do computer simulations. They then compare the outcomes of the simulations with actual experimental data to test their theories.

In some situations, however, the calculations are too hard to allow predictions from first principles. This is particularly true for phenomena that involve the strong nuclear force, which governs how quarks bind together into protons and neutrons and how these particles form atomic nuclei, says Christine Muschik, a theoretical physicist at the University of Innsbruck in Austria and a member of the simulation team.

Many researchers hope that future quantum computers will help to solve this problem. These machines, which are still in the earliest stages of development, exploit the physics of objects that can be in multiple states at once, encoding information in ‘qubits’, rather than in the on/off state of classical bits. A computer made of a handful of qubits can perform many calculations simultaneously, and can complete certain tasks exponentially faster than an ordinary computer.



Esteban Martinez, an experimental physicist at the University of Innsbruck, and his colleagues completed a proof of concept for a simulation of a high-energy physics experiment in which energy is converted into matter, creating an electron and its antiparticle, a positron.

The team used a tried-and-tested type of quantum computer in which an electromagnetic field traps four ions in a row, each one encoding a qubit, in a vacuum. They manipulated the ions’ spins — their magnetic orientations — using laser beams. This coaxed the ions to perform logic operations, the basic steps in any computer calculation.

After sequences of about 100 steps, each lasting a few milliseconds, the team looked at the state of the ions using a digital camera. Each of the four ions represented a location, two for particles and two for antiparticles, and the orientation of the ion revealed whether or not a particle or an antiparticle had been created at that location.

The team’s quantum calculations confirmed the predictions of a simplified version of quantum electrodynamics, the established theory of the electromagnetic force. “The stronger the field, the faster we can create particles and antiparticles,” Martinez says. He and his collaborators describe their results on 22 June in Nature1.

Four qubits constitute a rudimentary quantum computer; the fabled applications of future quantum computers, such as for breaking down huge numbers into prime factors, will require hundreds of qubits and complex error-correction codes. But for physical simulations, which can tolerate small margins of error, 30 to 40 qubits could already be useful, Martinez says.

John Chiaverini, a physicist who works on quantum computing at the Massachusetts Institute of Technology in Cambridge, says that the experiment might be difficult to scale up without significant modifications. The linear arrangement of ions in the trap, he says, is “particularly limiting for attacking problems of a reasonable scale”. Muschik says that her team is already making plans to use two-dimensional configurations of ions.



“We are not yet there where we can answer questions we can’t answer with classical computers,” Martinez says, “but this is a first step in that direction.” Quantum computers are not strictly necessary for understanding the electromagnetic force. However, the researchers hope to scale up their techniques so that they can simulate the strong nuclear force. This may take years, Muschik says, and will require not only breakthroughs in hardware, but also the development of new quantum algorithms.

These scaled-up quantum computers could help in understanding what happens during the high-speed collision of two atomic nuclei, for instance. Faced with such a problem, classical computer simulations just fall apart, says Andreas Kronfeld, a theoretical physicist who works on simulations of the strong nuclear force at the Fermi National Accelerator Laboratory (Fermilab) near Chicago, Illinois.



Another example, he says, is understanding neutron stars. Researchers think that these compact celestial objects consist of densely packed neutrons, but they’re not sure. They also don’t know the state of matter in which those neutrons would exist.

Source: Davide Castelvecchi, Nature

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The amazing Google quantum computer

In a recent article it was mentioned that a famous computer, acquired by Google from NASA, has proven beyond doubt to be superior to conventional computers used today. The information was provided by researchers at the Artificial Intelligence Laboratory of Google.
Google’s company said that this incredible computer has included a chip, so powerful and advanced, that would help the artificial intelligence algorithms.
Google researchers say that this computer may be used, accurately, in the advances of quantum physics and with the application of special mathematical theory may advance the AI field, this model would work much faster than a conventional computer.
Many powerful companies in the computer field like IBM, Microsoft, Goggle and the Government, are trying to develop a "quantum computer" using the concepts of quantum mechanics and work with data and to decipher huge amount of data not properly obtained or developed at its full capacity. These companies believe that quantum computer could make their studies of artificial intelligence more completed and also advance in the field of scientific materials.




NASA hopes that quantum computer can help in future space missions. Deepak Biswas, Director of Technology Ames Exploration Center in Mountain View, California NASA; said is a very disruptive technology that could change the way we do things today."
The scientific Boswas addressed the media specifying the joint work between NASA and Google’s company. He explained the management of data by the chip-superconductor called 'Quantum Annealer", which is modifiable with the adaptation of an algorithm called "problems-optimized" which are common in machine-learning and artificial intelligence programs.
Despite the progress of this computer (D-Wave's chip), they still have some detractors, particularly among quantum physicists. Several investigators claim that has not been fully proven that quantum computer can perform quantum physics problems and hit conventional computers.
After the controversial about the capability of this chip, Google AI labs, expressed, through Hartmut Neven, that related investigations have provided strong evidence on this matter. Google has developed a series of improvements to the D-Wave, provided by NASA, compared to conventional computers. Neven said that "Specifically, they have designed and improved the concept of problem-of-test to reach speeds of up to 100 million."
Google results are impressed, despite the questioning of the test validity, and are only part of the vindication of D-Wave. Initially, the computer lost a test with another quantum machine, when it was running a code to solve a problem manually, using a similar chip prepared in D-Wave algorithm. It is known that an alternative algorithm may have left the conventional computers be more competitive, or even win, Neven explained it was, what he called, a "bug" in the design of D-Wave. Neven said the test performed by the group is still important because the shortcut is not available for conventional computers until they complete, in the future, the quantum Annealers capability to work on large amounts of data.



The Google’s company is confident with D-Wave, to do it. Last summer, Google opened a new laboratory in Santa Barbara, led by academic researcher John Martins.

The academic is working on quantum hardware to optimize not just problems of limitations of Annealers. It foreshadows the computer will be called 'The Universal Quantum Computer" and could be programmed to solve any problem that could be more beneficial, but is expected a delay before they improve it. IBM and Microsoft, as well as Government laboratories are also working on this technology.



Google’s company, through its Vice-President John Giannandrea researches coordinator, said the quantum Annealers could be practical, and we may find many uses for more powerful software 'program-of-learning' orientated. 'We found problems during the solution of our non-practical products, using existing computers, and we also still have many problems’ he indicated that 'Possibly we have to wait many years before we make a difference with Google products."
For those persons amazed with this computer, it’s necessary to explain that the main purpose of the computer is to manipulate enormous amount of data, at the most rapidly speed possible. With this problem resolved, Google may provide programmers and general users the access to multiples data bases and even to cross information and obtain the results, of the search, almost immediately, and even the computer may “suggest” how we can use the results of the search more appropriately.
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Source:
Tom Simonite, December 9 2015