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Primeur weekly 2017-07-31

Focus

ECMWF at the heart of weather and climate modelling as global challenge of societal relevance with game changing prediction capability through exascale ...

NVIDIA hits the top 10 in the TOP500 and Green500 lists with multi-tasking GPUs - NVIDIA Vice President Ian Buck explains ...

Exascale supercomputing

Oak Ridge National Laboratory acquires D-Wave 2000Q Cloud services to accelerate hybrid computing applications ...

Crowd computing

Dark ecology project will use past weather radar data to trace bird migrations ...

Quantum computing

Tiny dancer atoms could prove a hit with quantum computer scientists ...

Qubitekk licenses ORNL single-photon source approach for quantum encryption ...

Ultracold molecules hold promise for quantum computing ...

University of Sydney and Microsoft forge global quantum computing partnership ...

Focus on Europe

Prof. Jan de Boer joins Board of Directors at Netherlands eScience Center ...

Hardware

Cray to expand storage portfolio through strategic transaction and partnership with Seagate ...

Stampede2 storms out of the Corral in support of U.S. scientists ...

Nick Nystrom appointed Interim Director of PSC ...

CSIRO has chosen Dell EMC to build a new scientific computing capability, kicking off a new generation of research ...

One Stop Systems named one of San Diego's fastest growing companies ...

Applications

High risk of unprecedented rainfall in the United Kingdom simulated by Met Office supercomputer ...

NIH awards $9.3 million for further development of PHENIX structural biology software ...

Inaugural Collaborative Science Call yields six proposals melding genomics and supercomputing ...

Stampede supercomputer skyrocketed science ...

IBM combines All-Flash and storage software optimized for Hortonworks ...

PPPL researchers perform first basic-physics simulation of the impact of recycled atoms on plasma turbulence ...

Catch of the day: A net full of trees ...

Liquid electrolyte contacts for advanced characterization of resistive switching memories ...

Ultracold molecules hold promise for quantum computing

27 Jul 2017 Cambridge - Researchers have taken an important step toward the long-sought goal of a quantum computer, which in theory should be capable of vastly faster computations than conventional computers, for certain kinds of problems. The new work shows that collections of ultracold molecules can retain the information stored in them, for hundreds of times longer than researchers have previously achieved in these materials.

These two-atom molecules are made of sodium and potassium and were cooled to temperatures just a few ten-millionths of a degree above absolute zero - measured in hundreds of nanokelvins, or nK. The results are described in a report in Science , by Martin Zwierlein, a MIT professor of physics; Jee Woo Park, a former MIT graduate student; Sebastian Will, a former research scientist at MIT and now an assistant professor at Columbia University, and two others, all at the MIT-Harvard Center for Ultracold Atoms.

Many different approaches are being studied as possible ways of creating qubits, the basic building blocks of long-theorized but not yet fully realized quantum computers. Researchers have tried using superconducting materials, ions held in ion traps, or individual neutral atoms, as well as molecules of varying complexity. The new approach uses a cluster of very simple molecules made of just two atoms.

"Molecules have more 'handles' than atoms", Martin Zwierlein stated, meaning more ways to interact with each other and with outside influences. "They can vibrate, they can rotate, and in fact they can strongly interact with each other, which atoms have a hard time doing. Typically, atoms have to really meet each other, be on top of each other almost, before they see that there's another atom there to interact with, whereas molecules can see each other" over relatively long ranges. In order to make these qubits talk to each other and perform calculations, using molecules is a much better idea than using atoms", he stated.

Using this kind of two-atom molecules for quantum information processing "had been suggested some time ago", stated Jee Woo Park, "and this work demonstrates the first experimental step toward realizing this new platform, which is that quantum information can be stored in dipolar molecules for extended times."

"The most amazing thing is that these molecules are a system which may allow realizing both storage and processing of quantum information, using the very same physical system", Sebastian Will stated. "That is actually a pretty rare feature that is not typical at all among the qubit systems that are mostly considered today."

In the team's initial proof-of-principle lab tests, a few thousand of the simple molecules were contained in a microscopic puff of gas, trapped at the intersection of two laser beams and cooled to ultracold temperatures of about 300 nanokelvins. "The more atoms you have in a molecule the harder it gets to cool them", Martin Zwierlein stated, so they chose this simple two-atom structure.

The molecules have three key characteristics: rotation, vibration, and the spin direction of the nuclei of the two individual atoms. For these experiments, the researchers got the molecules under perfect control in terms of all three characteristics - that is, into the lowest state of vibration, rotation, and nuclear spin alignment.

"We have been able to trap molecules for a long time, and also demonstrate that they can carry quantum information and hold onto it for a long time", Martin Zwierlein stated. And that, he says, is "one of the key breakthroughs or milestones one has to have before hoping to build a quantum computer, which is a much more complicated endeavour."

The use of sodium-potassium molecules provides a number of advantages, Martin Zwierlein said. For one thing, "the molecule is chemically stable, so if one of these molecules meets another one they don't break apart."

In the context of quantum computing, the "long time" Martin Zwierlein refers to is one second - which is "in fact on the order of a thousand times longer than a comparable experiment that has been done" using rotation to encode the qubit, he said. "Without additional measures, that experiment gave a millisecond, but this was great already." With this team's method, the system's inherent stability means "you get a full second for free."

That suggests, though it remains to be proven, that such a system would be able to carry out thousands of quantum computations, known as gates, in sequence within that second of coherence. The final results could then be "read" optically through a microscope, revealing the final state of the molecules.

"We have strong hopes that we can do one so-called gate - that's an operation between two of these qubits, like addition, subtraction, or that sort of equivalent - in a fraction of a millisecond", Martin Zwierlein stated. "If you look at the ratio, you could hope to do 10,000 to 100,000 gate operations in the time that we have the coherence in the sample. That has been stated as one of the requirements for a quantum computer, to have that sort of ratio of gate operations to coherence times."

"The next great goal will be to 'talk' to individual molecules. Then we are really talking quantum information", Sebastian Will stated. "If we can trap one molecule, we can trap two. And then we can think about implementing a 'quantum gate operation' - an elementary calculation - between two molecular qubits that sit next to each other", he stated.

Using an array of perhaps 1,000 such molecules, Martin Zwierlein said, would make it possible to carry out calculations so complex that no existing computer could even begin to check the possibilities. Though he stresses that this is still an early step and that such computers could be a decade or more away, in principle such a device could quickly solve currently intractable problems such as factoring very large numbers - a process whose difficulty forms the basis of today's best encryption systems for financial transactions.

Besides quantum computing, the new system also offers the potential for a new way of carrying out precision measurements and quantum chemistry, Martin Zwierlein said.

The team also included MIT graduate student Zoe Yan and postdoc Huanqian Loh. The work was supported by the National Science Foundation, the U.S. Air Force Office of Scientific Research, the U.S. Army Research Office, and the David and Lucile Packard Foundation.

Source: Massachusetts Institute of Technology - MIT

Back to Table of contents

Primeur weekly 2017-07-31

Focus

ECMWF at the heart of weather and climate modelling as global challenge of societal relevance with game changing prediction capability through exascale ...

NVIDIA hits the top 10 in the TOP500 and Green500 lists with multi-tasking GPUs - NVIDIA Vice President Ian Buck explains ...

Exascale supercomputing

Oak Ridge National Laboratory acquires D-Wave 2000Q Cloud services to accelerate hybrid computing applications ...

Crowd computing

Dark ecology project will use past weather radar data to trace bird migrations ...

Quantum computing

Tiny dancer atoms could prove a hit with quantum computer scientists ...

Qubitekk licenses ORNL single-photon source approach for quantum encryption ...

Ultracold molecules hold promise for quantum computing ...

University of Sydney and Microsoft forge global quantum computing partnership ...

Focus on Europe

Prof. Jan de Boer joins Board of Directors at Netherlands eScience Center ...

Hardware

Cray to expand storage portfolio through strategic transaction and partnership with Seagate ...

Stampede2 storms out of the Corral in support of U.S. scientists ...

Nick Nystrom appointed Interim Director of PSC ...

CSIRO has chosen Dell EMC to build a new scientific computing capability, kicking off a new generation of research ...

One Stop Systems named one of San Diego's fastest growing companies ...

Applications

High risk of unprecedented rainfall in the United Kingdom simulated by Met Office supercomputer ...

NIH awards $9.3 million for further development of PHENIX structural biology software ...

Inaugural Collaborative Science Call yields six proposals melding genomics and supercomputing ...

Stampede supercomputer skyrocketed science ...

IBM combines All-Flash and storage software optimized for Hortonworks ...

PPPL researchers perform first basic-physics simulation of the impact of recycled atoms on plasma turbulence ...

Catch of the day: A net full of trees ...

Liquid electrolyte contacts for advanced characterization of resistive switching memories ...