Electrical control of nuclear spin qubits

Researchers of Karlsruhe Institute of Technology (KIT) and their French partners succeeded in making an important step towards quantum computers. Using a spin cascade in single-molecule magnet, the scientists demonstrated how nuclear spins can be manipulated with electric fields. Electric manipulation allows for a quick and specific switching of quantum bits. The experimental results are now reported in the journal Science .

One of the most ambitious goals of nanotechnology is to realize a quantum computer. Such a computer based on quantum mechanics principles is to solve tasks much more efficiently than a classical computer. While the latter works with bits that assume the value of zero or one, a quantum computer uses so-called quantum bits, briefly referred to as qubits, as smallest computation units. They may also assume values in between. Qubits may rely on nuclear spins, i.e. intrinsic angular momentums of atomic nuclei. They orient relative to a magnetic field in upward (up) or downward (down) direction. Interlinkage of qubits with each other results in mixed quantum states, on the basis of which many calculation steps can be executed in parallel.
To integrate nuclear spin-based qubits into electronic circuits and specifically trigger novel information processes, specific electric manipulation of nuclear spins is required. A team of scientists of the KIT and the Centre National de la Recherche Scientifique (CNRS) in Grenoble and Strasbourg recently succeeded for the first time in manipulating a single nuclear spin in a purely electric manner. "Use of electric instead of magnetic fields paves the way to addressing quantum states in conventional electronic circuits," explains Professor Mario Ruben, Head of the Molecular Materials Research Group of KIT's Institute of Nanotechnology (INT). "There, quantum states can be manipulated specifically by so-called displacement currents. Then, they can be directly read out electronically."
For their experiments, the researchers used a nuclear spin-qubit transistor that consists of a single-molecule magnet connected to three electrodes (source, drain, and gate). The single-molecule magnet is a TbPc2 molecule – a single metal ion of terbium that is enclosed by organic phthalocyanine molecules of carbon, nitrogen, and hydrogen atoms. The gap between the electric field and the spin is bridged by the so-called hyperfine-Stark effect that transforms the electric field into a local magnetic field. This quantum mechanics process can be transferred to all nuclear spin systems and, hence, opens up entirely novel perspectives for integrating quantum effects in nuclear spins into electronic circuits.
Reference :
http://phys.org/news/2014-06-electrical-nuclear-qubits.html

Anyone who thought that Sachithra Senanayake being reported to the ICC for a suspect bowling action might be a cue for Sri Lanka to excuse him from duty, and the added attention it would bring, did not reckon with the player himself. Figures of 1 for 36, including the wicket of England's top-scorer, Alastair Cook, were just one thread of Sri Lanka's series-clinching six-wicket win but, by running out Jos Buttler while the batsman was backing up, Senanayake ensured that the narrative would be wound around him.
Mahela Jayawardene and Lahiru Thirimanne scored half-centuries as Sri Lanka kept cool in an atmosphere that was simultaneously heated and damp. England's bowlers, in particular James Tredwell and James Anderson, managed to ratchet up the asking rate but some business-like thumping from Angelo Mathews, who had to contend with a commentary from the fielding side over his role in Buttler's dismissal, sealed victory and another fortifying series triumph ahead of the Tests.

Mathews had earlier expressed his disappointment over Senanayake's situation - he is required to undergo biometric testing within the next 20 days - but Sri Lanka's capacity for turning adversity in their favour is well known. A comparable incident came during the triangular Carlton & United series in 1999, when Arjuna Ranatunga led his players off at Adelaide Oval after Ross Emerson no-balled Muttiah Muralitharan for throwing. England were again on the losing side, Sri Lanka chasing down a target of 303 with one wicket and two balls to spare.
As then, an offspinner with a controversial action was central to the drama. Having twice stopped in his delivery stride during the 42nd over to warn the batsmen - both Buttler and Chris Jordan - for backing up too far, Senanayake followed through on the threat in the 44th, turning slowly to break the wicket with Buttler a yard or so down the pitch.
The umpires consulted Mathews, Sri Lanka's captain, and he nodded his assent in upholding the appeal. That meant the first instance of 'Mankading' in international cricket since Peter Kirsten's innings was ended by Kapil Dev in such a manner during an ODI between South Africa and India in 1992.
There was predictable hostility from the crowd, even without suspicions over the legality of his bowling, but Senanayake was within his rights to make the appeal; the ICC changed its playing conditions in 2011 to allow bowlers to run out a batsman backing up at any point prior to releasing the ball, rather than before entering his delivery stride, as the MCC Laws state.
Buttler's dismissal, alongside creating a potential flashpoint, deprived England of their firestarter-in-chief for the closing overs of the innings. Although each of the top eight made it into double figures, no one could go beyond Cook's stodgy 56, as they were bowled out for 219 with 11 deliveries remaining. Despite losing 3 for 7 in 21 balls and having to contend with the threat of rain throughout, Sri Lanka were not greatly taxed in overhauling their target.
The openers, Tillakaratne Dilshan and Kusal Perera, raised 50 together in the seventh over but Tredwell's introduction briefly threatened to turn the match. His second ball was crashed by Dilshan to cover, where Joe Root took a fabulous diving catch, before a pearler two overs later straightened on Kumar Sangakkara to clip the outside edge and be taken at slip. Kusal's dismissal, lbw to Anderson, left Sri Lanka 62 for 3 but England were left to regret a missed opportunity off Jayawardene when the batsman had 8 - a thick edge flying between Buttler and Jordan at slip - as a fourth-wicket stand of 98 carried the game away from them.

Read more at http://www.espn.co.uk/cricket/sport/story/312551.html#hJ7WB0GAXcCLfAMd.99

Proteins 'ring like bells'

          As far back as 1948, Erwin Schrödinger—the inventor of modern quantum mechanics—published the book "What is life?"

In it, he suggested that quantum mechanics and coherent ringing might be at the basis of all biochemical reactions. At the time, this idea never found wide acceptance because it was generally assumed that vibrations in protein molecules would be too rapidly damped.

Now, scientists at the University of Glasgow have proven he was on the right track after all.
Using modern laser spectroscopy, the scientists have been able to measure the vibrational spectrum of the enzyme lysozyme, a protein that fights off bacteria. They discovered that this enzyme rings like a bell with a frequency of a few terahertz or a million-million hertz. Most remarkably, the ringing involves the entire protein, meaning the ringing motion could be responsible for the transfer of energy across proteins.
The experiments show that the ringing motion lasts for only a picosecond or one millionth of a millionth of a second. Biochemical reactions take place on a picosecond timescale and the scientists believe that evolution has optimised enzymes to ring for just the right amount of time. Any shorter, and biochemical reactions would become inefficient as energy is drained from the system too quickly. Any longer and the enzyme would simple oscillate forever: react, unreact, react, unreact, etc. The picosecond ringing time is just perfect for the most efficient reaction.


These tiny motions enable proteins to morph quickly so they can readily bind with other molecules, a process that is necessary for life to perform critical biological functions like absorbing oxygen and repairing cells.
The findings have been published in Nature Communications.


Klaas Wynne, Chair in Chemical Physics at the University of Glasgow said: "This research shows us that proteins have mechanical properties that are highly unexpected and geared towards maximising efficiency. Future work will show whether these mechanical properties can be used to understand the function of complex living systems."

Reference :
http://phys.org/news/2014-06-proteins-bells.html

Basic Concepts of Differential Equations

There is good news to all my friends......!!!!!!

                  I am going to start posting the the basic concepts of solving

                           Differential Equations

 

                    I'll soon tell you the date by which I start posing these articles so you have to follow me on Twitter and Facebook I'll post the date on my Facebook and Twitter accounts.

                                                       

Space-based experiment could test gravity's effects on quantum entanglement

                   
                          (Phys.org) —Physicists are continually looking for ways to unify the theory of relativity, which describes large-scale phenomena, with quantum theory, which describes small-scale phenomena. In a new proposed experiment in this area, two toaster-sized "nanosatellites" carrying entangled condensates orbit around the Earth, until one of them moves to a different orbit with a different gravitational field strength. As a result of the change in gravity, the entanglement between the condensates is predicted to degrade by up to 20%. Experimentally testing the proposal may be possible in the near future.

The paper, which is published in a recent issue of the New Journal of Physics by David Edward Bruschi, et al., theoretically demonstrates how relativistic effects impact the quantum world.
"Our work shows that it is possible to test gravitational effects, which are thought to affect classical systems at large and very large scales, with genuinely (small) entangled quantum systems," Bruschi told Phys.org. "Our results aid the understanding of the effects of relativity on entanglement, an important resource for quantum information processing. Since we lack a theory that merges quantum theory and relativity, our work can help direct future theoretical and experimental efforts that investigate quantum effects at large scales."
Besides being of fundamental interest, understanding how gravity and other relativistic features affect quantum entanglement will help physicists develop quantum technologies for space-based applications. In a sense, space-based quantum technologies will take classical space-based technologies such as GPS into the quantum regime. It's well-known that GPS satellites require relativistic corrections to accurately determine time and position, and the same will hold true for quantum technologies.
While GPS is widespread, however, quantum technologies have not yet been developed for the space environment, although several ideas have been proposed. While most of these proposals fall under the framework of the theory of quantum mechanics, the new proposal differs in that is developed within the framework of quantum field theory. This theory merges quantum theory and relativity in the sense that matter and radiation are quantized, while space time is treated as a classical background. The physicists here argue that quantum field theory provides a better model for understanding the effects of gravity on quantum properties.

                          Using a quantum field theory framework, the physicists have expanded upon previous research that showed that changes in acceleration affect entanglement. Due to the equivalence principle, this means that changes in gravity should also affect entanglement.
This is exactly what the physicists found in their analysis. Their proposed experiment involves two space experimentalists, whom the scientists call Valentina and Yuri—named after Valentina Tereshkova and Yuri Gagarin, the first woman and man to go to space. Valentina and Yuri each prepare a Bose-Einstein condensate (BEC), an ultracold group of atoms occupying their lowest energy state, which allows quantum effects to become visible on the macroscopic scale. The BECs' phonon modes are then entangled with each other.
                          Each BEC, which together with its enclosing and maintaining apparatuses has a volume of 0.5 liters, is then loaded onto its own 20 cm x 20 cm nanosatellite. Currently, researchers are working on the CanX 4 and CanX 5 nanosatellites with these dimensions. The nanosatellites start out by moving in the same circular orbit but in opposite directions. Then one of them receives a "velocity kick"—a change in velocity that moves it to an elliptical orbit. After navigating half of this new orbit, a second velocity kick puts the satellite into another circular orbit, different from the first one. Now the two satellites are in different orbits.
The degradation of entanglement between the BECs is expected to occur immediately after the orbit-hopping BEC undergoes its first change in velocity, and can be observed any time that BEC is moving in a different orbit. Although detecting entanglement between the phonon modes in BECs has not yet been achieved, it is currently a topic of great interest and may be possible in the near future. Since CanX 4 and CanX 5 are designed to determine positions with an accuracy of cm, even a small change in orbit should lead to an observable effect on the initial quantum entanglement.
                          Although entanglement can suffer a relatively large degradation due to a change in gravity, there is a bright side to the effect. The researchers also found that the strength of the entanglement oscillates periodically with respect to the gravitational difference between the two orbits. This means that it may be possible to find a situation in which entanglement is not degraded by accurately controlling the satellites' positions. This is one way in which the results will allow researchers to maximize the potential uses of future space-based quantum technologies.
"I believe that our results can be employed to develop future quantum communication and positioning technologies, ultraprecise accelerometers and navigation systems which would benefit from our better understanding of the interplay between quantum physics and relativity theory," Bruschi said.
In the future, the researchers plan to further investigate both the fundamental and practical aspects of quantum and relativistic effects.
                          "My goal is to develop space-based relativistic quantum technologies that will exploit both quantum and relativistic effects to bring the game to the next level," Bruschi said. "I believe that there is much to learn about the overlap of quantum mechanics and relativity theory at large scales and that the applications can be far reaching: from providing a theoretical basis for future space technologies to deepening our understanding of the laws of nature."

Reference :
                 http://phys.org/news/2014-05-space-based-gravity-effects-quantum-entanglement.html

Muhammad Amir going to join Team soon

There is good news for fan of cricket that Muhammad Aamir fast bowler of Pakistan is coming back to join team soon.

 

 

The International cricket council (ICU) has agreed to review the ban of Pakistani fast bowler Mohammed Amir.

The youngster was an up and coming talent in the world of cricket and sport until he was implicated in a match fixing scandal uncovered by the now closed News of the World. Amir’s ban currently is set to end in 2015; however it is looking more likely this may be reduced by a year. The Pakistani nation will be hoping for an early return to add pace and precision to their line up. Amir was tipped to become the next Waqar Younis, however with such a long period out of the sport it is now difficult to determine just how well he will be able to settle back into the sport.

The ICC are currently reviewing their anti corruption laws where the matter of Mohammed Amir’s five year ban is also being discussed. The discussion has been going on since July and is expected to produce a finalized new anti corruption law by January 2014. The possibility of Amir returning to international cricket will then be reviewed after the new laws have been finalized and adopted. The fast bowler is already getting ready to return to training with the Pakistanis and ‘warm up’ domestic games.

Once a great prospect in cricket, Pakistani cricket fans will be eagerly awaiting confirmation of his return to the sport.

Mohammed Amir commented on his ban; “I have learned my lessons and it has been frustrating not being able to play cricket which I love so much.”

Observation of unexpectedly deformed neutron-rich magnesium nuclei prompts rethink of nuclear shell structure

               Although much is known about atoms and their nuclei, scientists continue to make surprising discoveries as they probe the properties of some of the more exotic isotopes. Pieter Doornenbal from the RIKEN Nishina Center for Accelerator-Based Science (RNC) and co‐workers have made another such discovery with the observation that magnesium nuclei with a large number of neutrons appear to lose the nuclear shell structure that has become fundamental to our understanding of the nucleus.
         
           The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.
         
          Nuclear physicists now widely accept that nuclei with 2, 8, 20, 28, 50, 82 or 126 neutrons or protons are particularly stable due to the complete filling of these shells. Nuclei with such 'magic numbers' of protons or neutrons are spherical, whereas nuclei with numbers of nucleons that diverge from these magic values are increasingly deformed.

          Doornenbal and his colleagues investigated the shape of magnesium nuclei with 22, 24 or 26 neutrons—a significant imbalance of neutrons against magnesium's 12 protons. "Studying such nuclei is now possible thanks to the RNC's Radioactive Isotope Beam Factory, which provides the world's highest-intensity radioactive isotope beams," says Doornenbal. The results indicate that the magic numbers for neutron-rich nuclei—and hence the filling of nuclear shells—might differ from those of the naturally occurring stable nuclei, in which the numbers of protons and neutrons are roughly equal.

         The beams of magnesium nuclei were produced by first bombarding a high-energy beam of calcium nuclei against a thin beryllium target. The collision created a multitude of different nuclei that were then screened using magnetic fields to select precursor nuclei—aluminum-37, aluminum-39 and silicon-40. The desired magnesium nuclei were then obtained by bombarding the precursor nuclei against a carbon target to knock out additional nucleons.

        The researchers probed the shape of the magnesium nuclei by measuring the high-energy electromagnetic waves that they emit. By comparing these results to theoretical calculations and previous experimental work, the team inferred a large 'island' of deformation in the isotope chart for neutron-rich nuclei with 20 to 28 neutrons. "This behavior is also expected to occur for larger magic numbers," says Doornenbal. "However, we do not yet have the experimental tools to study it in these regions."


Reference:

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.

Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutron-rich-magnesium-nuclei.html#jCp

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.

Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutron-rich-magnesium-nuclei.html#jCp

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.

Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutron-rich-magnesium-nuclei.html#jCp

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.

Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutron-rich-magnesium-nuclei.html#jCp

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.

Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutron-rich-magnesium-nuclei.html#jCp

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.

Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutron-rich-magnesium-nuclei.html#jCp

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.

Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutron-rich-magnesium-nuclei.html#jCp

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.

Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutron-rich-magnesium-nuclei.html#jCp

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.

Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutron-rich-magnesium-nuclei.html#jCp

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.

Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutron-rich-magnesium-nuclei.html#jCp

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.

Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutron-rich-magnesium-nuclei.html#jCp

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.

Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutro

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.

Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutron-rich-magnesium-nuclei.html#jCp

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.

Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutron-rich-magnesium-nuclei.html#jCp

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.
Nuclear physicists now widely accept that nuclei with 2, 8, 20, 28, 50, 82 or 126 neutrons or protons are particularly stable due to the complete filling of these shells. Nuclei with such 'magic numbers' of protons or neutrons are spherical, whereas nuclei with numbers of nucleons that diverge from these magic values are increasingly deformed.


Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutron-rich-magnesium-nuclei.html#jCp

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.
Nuclear physicists now widely accept that nuclei with 2, 8, 20, 28, 50, 82 or 126 neutrons or protons are particularly stable due to the complete filling of these shells. Nuclei with such 'magic numbers' of protons or neutrons are spherical, whereas nuclei with numbers of nucleons that diverge from these magic values are increasingly deformed.
Doornenbal and his colleagues investigated the shape of magnesium nuclei with 22, 24 or 26 neutrons—a significant imbalance of neutrons against magnesium's 12 protons. "Studying such nuclei is now possible thanks to the RNC's Radioactive Isotope Beam Factory, which provides the world's highest-intensity radioactive isotope beams," says Doornenbal. The results indicate that the magic numbers for neutron-rich nuclei—and hence the filling of nuclear shells—might differ from those of the naturally occurring stable nuclei, in which the numbers of protons and neutrons are roughly equal.
The beams of magnesium nuclei were produced by first bombarding a high-energy beam of calcium nuclei against a thin beryllium target. The collision created a multitude of different nuclei that were then screened using magnetic fields to select precursor nuclei—aluminum-37, aluminum-39 and silicon-40. The desired magnesium nuclei were then obtained by bombarding the precursor nuclei against a carbon target to knock out additional nucleons.
The researchers probed the shape of the magnesium nuclei by measuring the high-energy electromagnetic waves that they emit. By comparing these results to theoretical calculations and previous experimental work, the team inferred a large 'island' of deformation in the isotope chart for neutron-rich nuclei with 20 to 28 neutrons. "This behavior is also expected to occur for larger magic numbers," says Doornenbal. "However, we do not yet have the experimental tools to study it in these regions."


Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutron-rich-magnesium-nuclei.html#jCp

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.
Nuclear physicists now widely accept that nuclei with 2, 8, 20, 28, 50, 82 or 126 neutrons or protons are particularly stable due to the complete filling of these shells. Nuclei with such 'magic numbers' of protons or neutrons are spherical, whereas nuclei with numbers of nucleons that diverge from these magic values are increasingly deformed.
Doornenbal and his colleagues investigated the shape of magnesium nuclei with 22, 24 or 26 neutrons—a significant imbalance of neutrons against magnesium's 12 protons. "Studying such nuclei is now possible thanks to the RNC's Radioactive Isotope Beam Factory, which provides the world's highest-intensity radioactive isotope beams," says Doornenbal. The results indicate that the magic numbers for neutron-rich nuclei—and hence the filling of nuclear shells—might differ from those of the naturally occurring stable nuclei, in which the numbers of protons and neutrons are roughly equal.
The beams of magnesium nuclei were produced by first bombarding a high-energy beam of calcium nuclei against a thin beryllium target. The collision created a multitude of different nuclei that were then screened using magnetic fields to select precursor nuclei—aluminum-37, aluminum-39 and silicon-40. The desired magnesium nuclei were then obtained by bombarding the precursor nuclei against a carbon target to knock out additional nucleons.
The researchers probed the shape of the magnesium nuclei by measuring the high-energy electromagnetic waves that they emit. By comparing these results to theoretical calculations and previous experimental work, the team inferred a large 'island' of deformation in the isotope chart for neutron-rich nuclei with 20 to 28 neutrons. "This behavior is also expected to occur for larger magic numbers," says Doornenbal. "However, we do not yet have the experimental tools to study it in these regions."


Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutron-rich-magnesium-nuclei.html#jCp

The protons and neutrons that make up an atomic nucleus are kept together by a balance of nuclear forces. When the number of neutrons is similar to the number of protons, the nucleus is generally stable and the nucleons arrange themselves in shells as a consequence of the laws of quantum mechanics.
Nuclear physicists now widely accept that nuclei with 2, 8, 20, 28, 50, 82 or 126 neutrons or protons are particularly stable due to the complete filling of these shells. Nuclei with such 'magic numbers' of protons or neutrons are spherical, whereas nuclei with numbers of nucleons that diverge from these magic values are increasingly deformed.
Doornenbal and his colleagues investigated the shape of magnesium nuclei with 22, 24 or 26 neutrons—a significant imbalance of neutrons against magnesium's 12 protons. "Studying such nuclei is now possible thanks to the RNC's Radioactive Isotope Beam Factory, which provides the world's highest-intensity radioactive isotope beams," says Doornenbal. The results indicate that the magic numbers for neutron-rich nuclei—and hence the filling of nuclear shells—might differ from those of the naturally occurring stable nuclei, in which the numbers of protons and neutrons are roughly equal.
The beams of magnesium nuclei were produced by first bombarding a high-energy beam of calcium nuclei against a thin beryllium target. The collision created a multitude of different nuclei that were then screened using magnetic fields to select precursor nuclei—aluminum-37, aluminum-39 and silicon-40. The desired magnesium nuclei were then obtained by bombarding the precursor nuclei against a carbon target to knock out additional nucleons.
The researchers probed the shape of the magnesium nuclei by measuring the high-energy electromagnetic waves that they emit. By comparing these results to theoretical calculations and previous experimental work, the team inferred a large 'island' of deformation in the isotope chart for neutron-rich nuclei with 20 to 28 neutrons. "This behavior is also expected to occur for larger magic numbers," says Doornenbal. "However, we do not yet have the experimental tools to study it in these regions."


Read more at: http://phys.org/news/2014-01-unexpectedly-deformed-neutron-rich-magnesium-nuclei.html#jCp