UNBOXING A QUANTUM COMPUTER!

Unboxing a Quantum Computer!

I strongly recommend to seeing this viral video on quantum computing. One million people saw this video with in a day.

//The coldest place in the known universe is on Earth! It's quantum computing company D-Wave's HQ, and they actually let Linus in!//

https://www.youtube.com/watch?v=60OkanvToFI

Source : Linus Tech Tips

Electron Exchange in Quantum Dots Improved Stability of Electron Spins in Qubits

Improved Stability of Electron Spins in Qubits

Calculation with electron spins in a quantum computer assumes that the spin states last for a sufficient period of time. Physicists at the University of Basel and the Swiss Nanoscience Institute have now demonstrated that electron exchange in quantum dots fundamentally limits the stability of this information. Control of this exchange process paves the way for further progress in the coherence of the fragile quantum states. The report from the Basel-based researchers appears in the scientific journal Physical Review Letters.

[caption id="attachment_646" align="aligncenter" width="650"]              Double quantum dot: The three lower and upper contacts trap up to two            individual electrons, the spin states of which form the quantum-mechanical information unit. The lateral contacts act as sensors.[/caption]

The basic idea of a quantum computer is to replace the ones and zeros used in today’s bits with quantum states, or qubits. Qubits are units of information that not only assume the values zero and one, but in which zero and one are possible at the same time, and in any chosen combination, in the form of a quantum superposition. Qubits can, for example, be implemented using the spins of individual electrons held in nanoscale structures made of semiconducting material, known as quantum dots. By exploiting quantum-mechanical principles such as superposition, a quantum computer can achieve enormous processing speeds – but only if the electron spins persist for long enough.

In recent years, it has been possible to extend this so-called coherence time to over a millisecond, thanks to the successful reduction of interference caused by nuclear spins. Thus, the search for other factors that affect the stability of the electron spins increased in importance.

Discovery of electron exchange

Physicists at the University of Basel and the Swiss Nanoscience Institute have now established that qubits’ coherence is limited by a process in which individual electrons are exchanged between a quantum dot and an external reservoir. The reservoir represents a type of electrode that is in contact with the quantum dot and is required for the measurements.

The researchers, led by Professor Dominik Zumbühl, observed that thermal excitation prompts an electron to jump from the quantum dot into the reservoir, and that shortly thereafter an electron jumps from the reservoir into the quantum dot.

This exchange creates a short-lived charge state, which the researchers in Basel have now been able to demonstrate for the first time with a charge sensor. The exchange process also leads to a randomizing of the electron spins, through which quantum information is lost.

Fundamental process for coherence

Based on the experimental observations, the researchers were able to significantly extend the existing theoretical description of double quantum dots, which can contain two electrons. They also succeeded in influencing the intensity of the temperature-dependent exchange process by cooling the electrons down to 60 millikelvins. At the same time, the process was slowed and the stability of the spins prolonged by changing the voltages at the entrances, or gates, to the quantum dot.

An understanding and control of this exchange process, which is fundamental to quantum dots, paves the way for further progress in qubit coherence. At the same time, it opens the way to a quick generation of desired spin states in quantum dots.

Implementation of a theoretical concept with Basel roots

This approach, whereby quantum dots in semiconductors are exploited in order to use the spin of an individual electron as a qubit, can be traced back to Prof. Daniel Loss of the University of Basel and the American physicist David DiVincenzo. Their concept, which they originally presented in 1998, has the potential to allow the creation of quantum computers with a large number of connected spin qubits. The current study was carried out in collaboration with researchers from the University of St Andrews (GB) and the University of California, Santa Barbara (US).

News Release Source : Improved Stability of Electron Spins in Qubits

Image Credit : University of Basel

 

Quantum Behavior of Mini Magnets Unraveled

Superconducting qubit and magnetic sphere hybrid

Quantum behavior of millimeter-sized magnets unraveled

Research Center for Advanced Science and Technology
2015/07/27

Researchers in the University of Tokyo have demonstrated that it is possible to exchange a quantum bit, the minimum unit of information used by quantum computers, between a superconducting quantum-bit circuit and a quantum in a magnet called a magnon. This result is expected to contribute to the development of quantum interfaces and quantum repeaters.

[caption id="attachment_600" align="alignleft" width="500"] Quantum Behavior of Mini Magnets Unraveled[/caption]

 

 

 

 

Illustration of magnet-qubit coupled system A magnet (ytterium iron garnet; YIG) and a superconducting qubit are placed with a separation of 4 cm. The electric field in the cavity interacts with the qubit, while the magnetic field interacts with the magnet. At an extremely low temperature of around -273 degrees centigrade, magnons, i.e., quanta of the fluctuations in the magnet, coherently couple with the qubit through the electromagnetic field of the cavity.

 

Magnets, often used in our daily life, exert a magnetic force produced by a large number of microscopic magnets – the spins of individual electrons – that are aligned in the same orientation. The collective motions of the ensemble of spins are called spin waves. A magnon is a quantum of such excitations, similar to a photon as a quantum of light, i.e., the electromagnetic wave. At room temperature the motions of electron spins can be largely affected by heat. The properties of individual magnons have not been studied at low temperatures corresponding to the “quantum limit” where all thermally-induced spin fluctuations vanish.

The research group of Professor Yasunobu Nakamura at the University of Tokyo Research Center for Advanced Science and Technology has succeeded for the first time to couple a magnon in a magnet to a photon in a microwave cavity at an ultralow temperature near absolute zero (-273.14 degrees centigrade). They observed coherent interaction between a magnon and a microwave photon by placing a millimeter-sized ferromagnetic sphere made of yttrium iron garnet in a centimeter-scale microwave cavity.

The research group furthermore demonstrated coherent coupling of a magnon to a superconducting quantum-bit circuit. The latter is known as a well-controllable quantum system and as one of the most promising building blocks for quantum processors. The group placed the magnet together with the superconducting qubit in a cavity and demonstrated exchange of information between the magnon and superconducting qubit mediated by the microwave cavity.

The results will stimulate research on the quantum behavior of magnons in spintronics devices and open a path toward realization of quantum interfaces and quantum repeaters.

Paper

Yutaka Tabuchi, Seiichiro Ishino, Atsushi Noguchi, Toyofumi Ishikawa, Rekishu Yamazaki, Koji Usami, Yasunobu Nakamura, "Coherent coupling between a ferromagnetic magnon and a superconducting qubit", Science Online Edition: 2015/7/10 (Japan time), doi: 10.1126/science.aaa3693.
Article link (Publication)

News Release Source : Superconducting qubit and magnetic sphere hybrid

Image Credit : Copyright 2015 Yutaka Tabuchi

After 85 years search Massless Particle Finally Discovered with Promise for Next Generation Electronics

After 85-year search, massless particle with promise for next-generation electronics found

PRINCETON UNIVERSITY

16 -July-2015

An international team led by Princeton University scientists has discovered Weyl fermions, an elusive massless particle theorized 85 years ago. The particle could give rise to faster and more efficient electronics because of its unusual ability to behave as matter and antimatter inside a crystal, according to new research.

[caption id="attachment_594" align="alignleft" width="510"] After 85 years search Massless Particle Finally Discovered with Promise for Next Generation Electronics[/caption]

The researchers report in the journal ScienceJuly 16 the first observation of Weyl fermions, which, if applied to next-generation electronics, could allow for a nearly free and efficient flow of electricity in electronics, and thus greater power, especially for computers, the researchers suggest.

Proposed by the mathematician and physicist Hermann Weyl in 1929, Weyl fermions have been long sought by scientists because they have been regarded as possible building blocks of other subatomic particles, and are even more basic than the ubiquitous, negative-charge carrying electron (when electrons are moving inside a crystal). Their basic nature means that Weyl fermions could provide a much more stable and efficient transport of particles than electrons, which are the principle particle behind modern electronics. Unlike electrons, Weyl fermions are massless and possess a high degree of mobility; the particle's spin is both in the same direction as its motion -- which is known as being right-handed -- and in the opposite direction in which it moves, or left-handed.

"The physics of the Weyl fermion are so strange, there could be many things that arise from this particle that we're just not capable of imagining now," said corresponding author M. Zahid Hasan, a Princeton professor of physics who led the research team.

The researchers' find differs from the other particle discoveries in that the Weyl fermion can be reproduced and potentially applied, Hasan said. Typically, particles such as the famous Higgs boson are detected in the fleeting aftermath of particle collisions, he said. The Weyl fermion, however, was discovered inside a synthetic metallic crystal called tantalum arsenide that the Princeton researchers designed in collaboration with researchers at the Collaborative Innovation Center of Quantum Matter in Beijing and at National Taiwan University.

The Weyl fermion possesses two characteristics that could make its discovery a boon for future electronics, including the development of the highly prized field of efficient quantum computing, Hasan explained.

For a physicist, the Weyl fermions are most notable for behaving like a composite of monopole- and antimonopole-like particles when inside a crystal, Hasan said. This means that Weyl particles that have opposite magnetic-like charges can nonetheless move independently of one another with a high degree of mobility.

The researchers also found that Weyl fermions can be used to create massless electrons that move very quickly with no backscattering, wherein electrons are lost when they collide with an obstruction. In electronics, backscattering hinders efficiency and generates heat. Weyl electrons simply move through and around roadblocks, Hasan said.

"It's like they have their own GPS and steer themselves without scattering," Hasan said. "They will move and move only in one direction since they are either right-handed or left-handed and never come to an end because they just tunnel through. These are very fast electrons that behave like unidirectional light beams and can be used for new types of quantum computing."

Prior to the Science paper, Hasan and his co-authors published a report in the journal Nature Communications in June that theorized that Weyl fermions could exist in a tantalum arsenide crystal. Guided by that paper, the researchers used the Princeton Institute for the Science and Technology of Materials (PRISM) and Laboratory for Topological Quantum Matter and Spectroscopy in Princeton's Jadwin Hall to research and simulate dozens of crystal structures before seizing upon the asymmetrical tantalum arsenide crystal, which has a differently shaped top and bottom.

The crystals were then loaded into a two-story device known as a scanning tunneling spectromicroscope that is cooled to near absolute zero and suspended from the ceiling to prevent even atom-sized vibrations. The spectromicroscope determined if the crystal matched the theoretical specifications for hosting a Weyl fermion. "It told us if the crystal was the house of the particle," Hasan said.

The Princeton team took the crystals passing the spectromicroscope test to the Lawrence Berkeley National Laboratory in California to be tested with high-energy accelerator-based photon beams. Once fired through the crystal, the beams' shape, size and direction indicated the presence of the long-elusive Weyl fermion.

First author Su-Yang Xu, a postdoctoral research associate in Princeton's Department of Physics, said that the work was unique for encompassing theory and experimentalism.

"The nature of this research and how it emerged is really different and more exciting than most of other work we have done before," Xu said. "Usually, theorists tell us that some compound might show some new or interesting properties, then we as experimentalists grow that sample and perform experiments to test the prediction. In this case, we came up with the theoretical prediction ourselves and then performed the experiments. This makes the final success even more exciting and satisfying than before."

In pursuing the elusive particle, the researchers had to pull from a number of disciplines, as well as just have faith in their quest and scientific instincts, Xu said.

"Solving this problem involved physics theory, chemistry, material science and, most importantly, intuition," he said. "This work really shows why research is so fascinating, because it involved both rational, logical thinking, and also sparks and inspiration."

Weyl, who worked at the Institute for Advanced Study, suggested his fermion as an alternative to the theory of relativity proposed by his colleague Albert Einstein. Although that application never panned out, the characteristics of his theoretical particle intrigued physicists for nearly a century, Hasan said. Actually observing the particle was a trying process -- one ambitious experiment proposed colliding high-energy neutrinos to test if the Weyl fermion was produced in the aftermath, he said.

The hunt for the Weyl fermion began in the earliest days of quantum theory when physicists first realized that their equations implied the existence of antimatter counterparts to commonly known particles such as electrons, Hasan said.

"People figured that although Weyl's theory was not applicable to relativity or neutrinos, it is the most basic form of fermion and had all other kinds of weird and beautiful properties that could be useful," he said.

"After more than 80 years, we found that this fermion was already there, waiting. It is the most basic building block of all electrons," he said. "It is exciting that we could finally make it come out following Weyl's 1929 theoretical recipe."

Ashvin Vishwanath, a professor of physics at the University of California-Berkeley who was not involved in the study, commented, "Professor Hasan's experiments report the observation of both the unusual properties in the bulk of the crystal as well as the exotic surface states that were theoretically predicted. While it is early to say what practical implications this discovery might have, it is worth noting that Weyl materials are direct 3-D electronic analogs of graphene, which is being seriously studied for potential applications."

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Other co-authors were Chenglong Zhang, Zhujun Yuan and Shuang Jia from Peking University; Raman Sankar and Fangcheng Chou from the National Taiwan University; Guoqing Chang, Chi-Cheng Lee, Shin-Ming Huang, BaoKai Wang and Hsin Lin from the National University of Singapore; Jie Ma from Oak Ridge National Laboratory; and Arun Bansil from Northeastern University. BaoKai Wang is also affiliated with Northeastern University, and Shuang Jia is affiliated with the Collaborative Innovation Center of Quantum Matter in Beijing.

The paper, "Discovery of Weyl fermions and topological Fermi arcs," was published online byScience on July 16. The work was supported by the Gordon and Betty Moore Foundations Emergent Phenomena in Quantum Systems (EPiQS) Initiative (grant no. GBMF4547); the Singapore National Research Foundation (grant no. NRF-NRFF2013-03); the National Basic Research Program of China (grant nos. 2013CB921901 and 2014CB239302); the U.S. Department of Energy (grant no. DE-FG-02-05ER462000); and the Taiwan Ministry of Science and Technology (project no. 102-2119-M- 002-004).

News Release Source : After 85-year search, massless particle with promise for next-generation electronics found

Image Credit : Image by Su-Yang Xu and M. Zahid Hasan, Princeton Department of Physics

Australian Quantum Physicist Michelle Simmons to Head New Quantum Journal

Education Minister launches first Nature Partner Journal in Australia

University of New South Wales (UNSW)

04 November 2014

A new scientific journal focusing on the rapidly developing areas of quantum research that promise to revolutionise the processing and transmission of information has been launched today at UNSW by the Federal Minister for Education Christopher Pyne.

[caption id="attachment_471" align="aligncenter" width="650"] Australian Quantum Physicist Michelle Simmons to Head New Quantum Journal[/caption]

npj Quantum Information is an international open-access journal and the first Nature Partner Journal based in Australia.

Professor Michelle Simmons, Director of the Australian Research Council Centre of Excellence for Quantum Computation and Communication Technology at UNSW, has been appointed to the prestigious role of Editor-in-Chief of the journal.

npj Quantum Information will combine research at the forefront of quantum computing, quantum communication and quantum information theory, covering topics including optics, atomic physics, semiconductor physics, superconducting physics and computer science.

Recent advances in instrumentation mean matter can be manipulated at the smallest scales – at the level of single atoms of matter or single photons of light. Scientists predict these areas of research will bring dramatic increases in computational power, and the ability to transmit information absolutely securely.

Professor Simmons said: “The 21st century will be the quantum information century, as the properties of quantum physics are exploited to develop powerful new, secure technologies for transmitting and processing information. New commercial and intellectual opportunities are emerging for nations that are able to discover, patent and exploit technologies in these areas.”

She highlighted the importance of the open access model for scientific journals: “While discovery is converging across fields, advances are still reported in disparate journals.

npj Quantum Information aims to change that, providing an open-access home for all aspects of this rapidly developing discipline.”

“The ARC plays an important role in the global research effort – the race to develop the quantum computer could be the space race of the 21st century,” said Federal Education Minister, the Hon Christopher Pyne MP, who toured the ARC Centre of Excellence laboratories at UNSW.

“Australia has a reputation for excellent research of international standing. The ARC Centre of Excellence for Quantum Computation and Communication Technology is strengthening this reputation and the new Nature Partner Journal will provide an important focus on this rapidly changing and exciting area of research,” he said.

David Swinbanks, Managing Director of Macmillan Science and Education, Australia and New Zealand said: “This launch is particularly exciting because it is our first partner journal partnered with an Australian institution.

“npj Quantum Information will be open access, free immediately upon publication for anyone who wants to read it. The open access model is especially important in the field of quantum information where the research is growing rapidly but has historically been fragmented. Our hope is that open access will stimulate sharing of ideas across these communities. Additionally, it will facilitate knowledge transfer to up and coming entrepreneurial businesses that are springing up in this area,” Mr Swinbanks said.

npj Quantum Information is now accepting submissions. Professor Simmons anticipates that the journal willpublish papers from both fundamental and applied areas, which could include reports about the fundamental relationship between quantum mechanics and information, the practical steps that are being taken to realise a quantum computer, algorithms opening new pathways for quantum information processing, exquisitely sensitive quantum sensors, the development of secure quantum communications across a global scale and emerging applications of quantum entanglement such as teleportation.

Professor Simmons is a world leader in the field of quantum computing and holds an ARC Laureate Fellowship at UNSW. She has published more than 350 papers in refereed journals including Nature, Nature Nanotechnology, Nature Physics, Nature Materials and Nature Communications. In 2012, her research group developed the world’s smallest transistor, marking a technological achievement 10 years ahead of industry predictions. Her laboratory is the only one in the world able to make atomically precise devices in silicon, including the thinnest conducting wires yet produced, which are 1000 times narrower than a human hair. A member of the Australian Academy of Science since 2006, she was named NSW Scientist of the Year in 2012. In 2014, she became an elected member of the American Academy of Arts and Sciences.

For more on the journal check the website: www.nature.com/npjqi/

News Release Source : Education Minister launches first Nature Partner Journal in Australia

Quantum environmentalism

Quantum environmentalism

Putting a qubit's surroundings to good use

Where are the quantum computers? Aren't they supposed to be speeding up decryption and internet searches? After two decades of research, you still can't find them in stores. Well, it took two decades or more of research dedicated to semiconductors and circuit integration before we had digital computers. For quantum computers too it will take technology more time to catch up to the science

[caption id="attachment_436" align="aligncenter" width="512" class=" "] The electron spin (black arrow) inside a quantum dot interacts magnetically with the effective magnetic field (orange arrow) of the nuclei of the atoms forming the atomic environment of the electron.[/caption]

Meanwhile, research devoted to exploring bizarre quantum phenomena must continue to overcome or reduce a litany of practical obstacles before quantum computing can be realized. Not the least of these obstacles remains the isolation of qubits---the repository of quantum information---from their surroundings. A qubit, or better yet an ensemble of qubits, exists in a superposition of two or more possible states. The trouble is that superposition is a fragile condition, and the manipulation and final readout of those states are in danger of being undone if a qubit interacts with its environment. A new paper, published in Nature Physics (1) addresses this problem by demonstrating a new type of qubit control, one that actually makes productive use of a qubit's proximity to its surroundings.

The experimental work was performed at the Cavendish Laboratory at Cambridge University in the UK. JQI (2) scientist Jacob Taylor provided the theoretical input to the work over the course of five years of cross-Atlantic collaboration.

ENVIRONMENTAL-ASSISTED CONTROL Qubits come in many forms but have one essential thing in common: they all embody a physical system---whether in the form of a photon or atom or electron or electrical current---which exists in two quantum states simultaneously. In the Cambridge experiment the qubit is a single electron trapped in a semiconductor. The two quantum states, in this case, consist of the two orientations for the electron's tiny spin, either up or down.

The electron's trap is a tiny region of the semiconductor called a quantum dot, essentially a zero-dimensional volume housing a single active electron. When studied at a temperature of about 4 K, the electron spreads as a wave across the 10 nanometer length of the quantum dot. The dot can be considered to be an artificial atom in which the electron (instead of orbiting a single nucleus) is confined in the crystalline lattice of millions of atoms. And like electrons in regular atoms, the select electron in a quantum dot possesses an energy spectrum of discrete energies.

The dot is fabricated using existing nanotechology. In substance it is a tiny lump of indium arsenide (InAs) grown amidst surrounding thicker layers of gallium arsenide (GaAs). Recall the story of the princess and the pea; a girl confirms her status as a princess by detecting a very faint lumpiness created by the presence of a single pea sandwiched between much larger mattresses.

Here the pea is the InAs quantum dot and the mattresses are the GaAs layers. The two species of semiconductor blend, InAs and GaAs, are incommensurate, meaning that their natural atomic spacings are slightly different. In practice this ensures that the atoms in the InAs dot are under some stress amid the surrounding GaAs atom layers. This stress, in turn, leads to the growth of such small 'pea'-like dots, confining the electron inside. Fortunately, one can probe the properties of these buried quantum dots via light, as the materials are transparent, allowing experimentalists to control and manipulate the electron using lasers.

The electron's energy spectrum is made still more complicated by the faint magnetic interaction between it and the nuclei of all those indium and arsenic atoms. Each of those nuclei has a net magnetic field and behaves as if it were a tiny magnet. Those nuclei, in the absence of an external magnetic field, are pointing in all different directions. But at any one moment, the totality of the nuclei exert a single, effective field, which the electron senses. The collective nuclei form a magnetic "environment" for the electron. In just a moment we'll see how the electron is employed as a qubit and how its environment---usually viewed as a threat to maintaining the quantum integrity of the qubit---is actually put to use in the process of manipulating and reading out the qubit.

QUANTUM DARK STATES If a laser strikes the quantum dot at certain wavelengths corresponding to allowed electron energies, the dot will absorb and then reemit light. It will fluoresce. Things get more interesting, however, if the electron can be coaxed into not absorbing light. To do this a dark state must be created. Generally, if a laser beam is tuned to the energy difference between two quantum levels, the atom can absorb laser light and be promoted to the more excited of the two states. The continued presence of the laser light will later stimulate the atom to re-emit the light and return to its lower (ground) state. In some circumstances this absorption/emission process can be stymied if there are closely spaced ground states.

Two laser beams, one tuned to promote the atom from state 1 to state 3 and one tuned to promote the atom from state 2 to state 3, can interfere with each other, leaving state 3 unreachable. This destructive interference can be turned on and off by changing the relative phase of the two laser beams.

This method is employed in the Cambridge experiment. The quantum dot qubit consists of the lone electron being maintained in a state of superposition (spin up and spin down) by laser light. Moreover, the presence of the underlying nuclear magnetic field forming the electron's "environment" helps establish a two-part ground state. Thereafter, the combination of the environment, plus the presence of two carefully-tuned laser beams allows the state of the qubit to be controlled (swiveled around in space) and even to be read out when detectors glimpse the electron as a bright (fluorescent) or a dark object.

In quantum computing, the explicit state of the qubit is unknown (spin up or spin down); this is positively a necessary condition---a required indeterminacy---for the quantum computation to continue. The only thing required is that one knows the relative change in the qubit, such as whether it was swiveled through an angle of 90 or 180 degrees. In conventional computing an example would be a NOT gate, which changes a bit from a 1 state into a 0 state or vice versa. It's only important to know the relative change in the bit, not its actual value. "What is profound is that the electron spin is always in the same quantum superposition, but the physical state evolves with the nuclear field," notes Mete Atature, the Cambridge researcher leading the experimental study.

"Usually you need an external magnetic field to manipulate qubits," says Jacob Taylor, "but this single field can't be used also to read out the final state of a qubit. In our all-optical approach we don't use a field so we can perform manipulation and readout with a single setup."

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1. "Environment-assisted quantum control of a solid-state spin via coherent dark states," Jack Hansom, Carsten H. H. Schulte, Claire Le Gall, Clemens Matthiesen, Edmund Clarke, Maxime Hugues, Jacob M. Taylor, Mete Atatüre, Nature Physics, Nature Physics 10, 725–730 (2014), doi:10.1038/nphys3077; published online 7 September 2014

2. The Joint Quantum Institute (JQI) is operated by the National Institute for Standards and Technology and the University of Maryland (http://jqi.umd.edu/)

3. Previous press release about 3-electron quantum dot qubits: http://jqi.umd.edu/news/resonant-exchange-qubits.

4. Previous press release about reducing noise in quantum-dot qubits: http://jqi.umd.edu/news/reducing-noise-qubit-arrays

5. Previous press release about Bloch spheres and how to manipulate qubits: http://jqi.umd.edu/news/quantum-longitude

Jacob Taylor, jmtaylor@umd.edu

Press contact at JQI: Phillip F. Schewe, pschewe@umd.edu, 301-405-0989. http://jqi.umd.edu/

 

News Release Source :  Quantum environmentalism

Fluid Mechanics Shows Alternative View of Quantum Mechanics

Fluid mechanics suggests alternative to quantum orthodoxy

The central mystery of quantum mechanics is that small chunks of matter sometimes seem to behave like particles, sometimes like waves. For most of the past century, the prevailing explanation of this conundrum has been what's called the "Copenhagen interpretation" — which holds that, in some sense, a single particle really is a wave, smeared out across the universe, that collapses into a determinate location only when observed.

[caption id="attachment_432" align="aligncenter" width="500"] Fluid Mechanics Shows Alternative View of Quantum Mechanics[/caption]

But some founders of quantum physics — notably Louis de Broglie — championed an alternative interpretation, known as "pilot-wave theory," which posits that quantum particles are borne along on some type of wave. According to pilot-wave theory, the particles have definite trajectories, but because of the pilot wave's influence, they still exhibit wavelike statistics.

John Bush, a professor of applied mathematics at MIT, believes that pilot-wave theory deserves a second look. That's because Yves Couder, Emmanuel Fort, and colleagues at the University of Paris Diderot have recently discovered a macroscopic pilot-wave system whose statistical behavior, in certain circumstances, recalls that of quantum systems.

Couder and Fort's system consists of a bath of fluid vibrating at a rate just below the threshold at which waves would start to form on its surface. A droplet of the same fluid is released above the bath; where it strikes the surface, it causes waves to radiate outward. The droplet then begins moving across the bath, propelled by the very waves it creates.

"This system is undoubtedly quantitatively different from quantum mechanics," Bush says. "It's also qualitatively different: There are some features of quantum mechanics that we can't capture, some features of this system that we know aren't present in quantum mechanics. But are they philosophically distinct?"

Tracking trajectories

Bush believes that the Copenhagen interpretation sidesteps the technical challenge of calculating particles' trajectories by denying that they exist. "The key question is whether a real quantum dynamics, of the general form suggested by de Broglie and the walking drops, might underlie quantum statistics," he says. "While undoubtedly complex, it would replace the philosophical vagaries of quantum mechanics with a concrete dynamical theory."

Last year, Bush and one of his students — Jan Molacek, now at the Max Planck Institute for Dynamics and Self-Organization — did for their system what the quantum pioneers couldn't do for theirs: They derived an equation relating the dynamics of the pilot waves to the particles' trajectories.

In their work, Bush and Molacek had two advantages over the quantum pioneers, Bush says. First, in the fluidic system, both the bouncing droplet and its guiding wave are plainly visible. If the droplet passes through a slit in a barrier — as it does in the re-creation of a canonical quantum experiment — the researchers can accurately determine its location. The only way to perform a measurement on an atomic-scale particle is to strike it with another particle, which changes its velocity.

The second advantage is the relatively recent development of chaos theory. Pioneered by MIT's Edward Lorenz in the 1960s, chaos theory holds that many macroscopic physical systems are so sensitive to initial conditions that, even though they can be described by a deterministic theory, they evolve in unpredictable ways. A weather-system model, for instance, might yield entirely different results if the wind speed at a particular location at a particular time is 10.01 mph or 10.02 mph.

The fluidic pilot-wave system is also chaotic. It's impossible to measure a bouncing droplet's position accurately enough to predict its trajectory very far into the future. But in a recent series of papers, Bush, MIT professor of applied mathematics Ruben Rosales, and graduate students Anand Oza and Dan Harris applied their pilot-wave theory to show how chaotic pilot-wave dynamics leads to the quantumlike statistics observed in their experiments.

What's real?

In a review article appearing in the Annual Review of Fluid Mechanics, Bush explores the connection between Couder's fluidic system and the quantum pilot-wave theories proposed by de Broglie and others.

The Copenhagen interpretation is essentially the assertion that in the quantum realm, there is no description deeper than the statistical one. When a measurement is made on a quantum particle, and the wave form collapses, the determinate state that the particle assumes is totally random. According to the Copenhagen interpretation, the statistics don't just describe the reality; they are the reality.

But despite the ascendancy of the Copenhagen interpretation, the intuition that physical objects, no matter how small, can be in only one location at a time has been difficult for physicists to shake. Albert Einstein, who famously doubted that God plays dice with the universe, worked for a time on what he called a "ghost wave" theory of quantum mechanics, thought to be an elaboration of de Broglie's theory. In his 1976 Nobel Prize lecture, Murray Gell-Mann declared that Niels Bohr, the chief exponent of the Copenhagen interpretation, "brainwashed an entire generation of physicists into believing that the problem had been solved." John Bell, the Irish physicist whose famous theorem is often mistakenly taken to repudiate all "hidden-variable" accounts of quantum mechanics, was, in fact, himself a proponent of pilot-wave theory. "It is a great mystery to me that it was so soundly ignored," he said.

Then there's David Griffiths, a physicist whose "Introduction to Quantum Mechanics" is standard in the field. In that book's afterword, Griffiths says that the Copenhagen interpretation "has stood the test of time and emerged unscathed from every experimental challenge." Nonetheless, he concludes, "It is entirely possible that future generations will look back, from the vantage point of a more sophisticated theory, and wonder how we could have been so gullible."

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News Release Source : Fluid mechanics suggests alternative to quantum orthodoxy

Quantum Transformations Found Near Absolute Zero

Elusive quantum transformations found near absolute zero

 

Brookhaven Lab and Stony Brook University researchers measured the quantum fluctuations behind a novel magnetic material's ultra-cold ferromagnetic phase transition

UPTON, NY—Heat drives classical phase transitions—think solid, liquid, and gas—but much stranger things can happen when the temperature drops. If phase transitions occur at the coldest temperatures imaginable, where quantum mechanics reigns, subtle fluctuations can dramatically transform a material.

[caption id="attachment_424" align="aligncenter" width="400"] Quantum Transformations Found Near Absolute Zero[/caption]

Scientists from the U.S. Department of Energy's Brookhaven National Laboratory and Stony Brook University have explored this frigid landscape of absolute zero to isolate and probe these quantum phase transitions with unprecedented precision.

"Under these cold conditions, the electronic, magnetic, and thermodynamic performance of metallic materials is defined by these elusive quantum fluctuations," said study coauthor Meigan Aronson, a physicist at Brookhaven Lab and professor at Stony Brook. "For the first time, we have a picture of one of the most fundamental electron states without ambient heat obscuring or complicating those properties."

The scientists explored the onset of ferromagnetism—the same magnetic polarization exploited in advanced electronic devices, electrical motors, and even refrigerator magnets—in a custom-synthesized iron compound as it approached absolute zero.

The research provides new methods to identify and understand novel materials with powerful and unexpected properties, including superconductivity—the ability to conduct electricity with perfect efficiency. The study will be published online Sept. 15, 2014, in the journal Proceedings of the National Academy of Sciences.

"Exposing this quantum phase transition allows us to predict and potentially boost the performance of new materials in practical ways that were previously only theoretical," said study coauthor and Brookhaven Lab physicist Alexei Tsvelik.

Mapping Quantum Landscapes

The presence of heat complicates or overpowers the so-called quantum critical fluctuations, so the scientists conducted experiments at the lowest possible temperatures.

"The laws of thermodynamics make absolute zero unreachable, but the quantum phase transitions can actually be observed at nonzero temperatures," Aronson said. "Even so, in order to deduce the full quantum mechanical nature, we needed to reach temperatures as low as 0.06 Kelvin—much, much colder than liquid helium or even interstellar space."

The researchers used a novel compound of yttrium, iron, and aluminum (YFe2Al10), which they discovered while searching for new superconductors. This layered, metallic material sits poised on the threshold of ferromagnetic order, a key and very rare property.

"Our thermodynamic and magnetic measurements proved that YFe2Al10 becomes ferromagnetic exactly at absolute zero—a sharp contrast to iron, which is ferromagnetic well above room temperature," Aronson said. "Further, we used magnetic fields to reverse this ferromagnetic order, proving that quantum fluctuations were responsible."

The collaboration produced near-perfect samples to prove that material defects could not impact the results. They were also the first group to prepare YFe2Al10 in single-crystal form, which allowed them to show that the emergent magnetism resided within two-dimensional layers.

"As the ferromagnetism decayed with heat or applied magnetic fields, we used theory to identify the spatial and temporal fluctuations that drove the transition," Tsvelik said. "That fundamental information provides insight into countless other materials."

Quantum Clues to New Materials

The scientists plan to modify the composition of YFe2Al10 so that it becomes ferromagnetic at nonzero temperatures, opening another window onto the relationship between temperature, quantum transitions, and material performance.

"Robust magnetic ordering generally blocks superconductivity, but suppressing this state might achieve the exact balance of quantum fluctuations needed to realize unconventional superconductivity," Tsvelik said. "It is a matter of great experimental and theoretical interest to isolate these competing quantum interactions that favor magnetism in one case and superconductivity on the other."

Added Aronson, "Having more examples displaying this zero-temperature interplay of superconductivity and magnetism is crucial as we develop a holistic understanding of how these phenomena are related and how we might ultimately control these properties in new generations of materials."

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Other authors on this study include Liusuo Wu, Moosung Kim, and Keeseong Park, all of Stony Brook University's Department of Physics and Astronomy.

The research was conducted at Brookhaven Lab's Condensed Matter Physics and Materials Science Department and supported by the U.S. Department of Energy's Office of Science (BES).

Brookhaven National Laboratory is supported by the Office of Science of the U.S. Department of Energy. The Office of Science is the single largest supporter of basic research in the physical sciences in the United States, and is working to address some of the most pressing challenges of our time. For more information, please visit science.energy.gov.

One of ten national laboratories overseen and primarily funded by the Office of Science of the U.S. Department of Energy (DOE), Brookhaven National Laboratory conducts research in the physical, biomedical, and environmental sciences, as well as in energy technologies and national security. Brookhaven Lab also builds and operates major scientific facilities available to university, industry and government researchers. Brookhaven is operated and managed for DOE's Office of Science by Brookhaven Science Associates, a limited-liability company founded by the Research Foundation for the State University of New York on behalf of Stony Brook University, the largest academic user of Laboratory facilities, and Battelle, a nonprofit applied science and technology organization.

News Release Source : Elusive quantum transformations found near absolute zero

'NV Centers' at Specific Spots within a Diamond Lattice could Advance Quantum Computing

Diamond Defect Interior Design

Planting imperfections called 'NV centers' at specific spots within a diamond lattice could advance quantum computing and atomic-scale measurement

WASHINGTON, D.C., August 5, 2014 – By carefully controlling the position of an atomic-scale diamond defect within a volume smaller than what some viruses would fill, researchers have cleared a path toward better quantum computers and nanoscale sensors. They describe their technique in a paper published in the journal Applied Physics Letters, from AIP Publishing.

[caption id="attachment_402" align="alignleft" width="400"] 'NV Centers' at Specific Spots within a Diamond Lattice could Advance Quantum Computing[/caption]

David Awschalom, a physicist at the Institute for Molecular Engineering at the University of Chicago, and his colleagues study a technologically useful diamond defect called a nitrogen vacancy (NV) center. NV centers consist of a nitrogen atom adjacent to a vacant spot that replaces two carbon atoms in the diamond crystal, leaving an unpaired electron. Researchers can use a property of the unpaired electron known as its spin to store and transmit quantum information at room temperature.

Qubits and Quantum Sensors

NV centers are attractive candidates for qubits, the quantum equivalent of a classical computing bit. A single NV center can also be used for completely different applications, such as measuring temperature, as well as to image electric and magnetic fields on the nanometer-scale by placing it at the tip of a diamond-based scanning probe.

A primary obstacle to further exploiting NV centers for practical quantum computing and nanoscale sensing devices lies in the difficulty of placing the centers within what Awschalom calls the functional "sweet spots" of the devices. Another challenge is increasing the NV center density without sacrificing their spin lifetimes, which must remain long in order to extract the most useful information from the system.

Awschalom and his colleagues have developed a new way to create NV centers that could help overcome both these challenges.

That's the Spot

The key to the team's new approach is to create the nitrogen and vacancy defects separately, Awschalom said. First, the team grew a layer of nitrogen-doped crystal within a diamond film. The researchers kept the nitrogen layer extremely thin by reducing the growth rate of the film to approximately 8 nanometers/hour. The nanometer-scale nitrogen-doped layer constrains the possible location of the NV centers in the depth direction.

Secondly, the researchers created a mask to cover the film, leaving only pinprick holes. They blasted carbon ions through the holes to create vacancies and heated the diamond to make the vacancies mobile within the crystal. NV centers could form in the nitrogen-doped layer below where the holes were placed.

Using this approach the team successfully localized NV centers within a cavity approximately 180 nanometers across -- a volume small enough to be compatible with many diamond-based nanostructures used in sensing devices and experimental quantum information systems.

The localized NV centers could also hold a specific spin for longer than 300 microseconds. This so-called spin coherence time was an order of magnitude better than that achieved by other 3-D localization methods. The longer spin lifetime means the NV centers can detect smaller magnetic signals and hold quantum information for longer.

One of the team's goals for using their new technique is to measure the nuclear spins of hydrogen atoms – one of the tiniest magnetic signals – within a biological molecule. The research could reveal new insights into how important biological functions like photosynthesis work. "Our research impacts diverse fields of science and technology," Awschalom said. "Technological advancements always open new avenues of scientific research."

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The article, "Three-dimensional localization of spins in diamond using 12C implantation," is authored by Kenichi Ohno, F. Joseph Heremans, Charles F. de las Casas, Bryan A. Myers, Benjamín J. Alemán, Ania C. Bleszynski Jayich, and David D. Awschalom. It will be published in the journal Applied Physics Letters on August 5, 2014 (DOI: 10.1063/1.4890613). After that date, it can be accessed at: http://scitation.aip.org/content/aip/journal/apl/105/5/10.1063/1.4890613

The authors of this paper are affiliated with the University of California, Santa Barbara and the University of Chicago.

ABOUT THE JOURNAL

Applied Physics Letters features concise, rapid reports on significant new findings in applied physics. The journal covers new experimental and theoretical research on applications of physics phenomena related to all branches of science, engineering, and modern technology. See: http://apl.aip.org

Image Credit: F.J. Heremans and D. Awschalom/U. Chicago and K. Ohno/UCSB

News Release Source : Diamond Defect Interior Design

Quantum manipulation: Filling the gap between quantum and classicalworld

Quantum manipulation: Filling the gap between quantum and classical world

Quantum superposition is a fundamental and also intriguing property of the quantum world. Because of superposition, a quantum system can be in two different states simultaneously, like a cat that can be both "dead" and "alive" at the same time. However, this anti-intuitive phenomenon cannot be observed directly, because whenever a classical measuring tool touches a quantum system, it immediately collapse into a classical state. On the other hand, quantum superposition is also the core of quantum computer's enormous computational power. A quantum computer can easily break the widely used RSA (Rivest, Shamir and Adleman) security system with Shor's algorithm. But for now, quantum computation still suffers from the decoherence induced by environment. Obviously, the key to manipulate a quantum system is to make it stay coherent as long as possible, to achieve this, one need to isolate the system from its environment. "For ground-breaking experimental methods that enable measuring and manipulation of individual quantum systems", Serge Haroche and David Wineland won the 2012 Nobel Prize in Physics.

                                          Quantum manipulation - Filling the gap                                        
between quantum and classical world

This review begins by introducing the interesting property of quantum superposition, explaining its physical meaning, potential applications and main obstacles ahead. Then the author goes on to introduce the work of the two 2012 Nobel Prize Laureates – Serge Haroche and David Wineland. Instead of manipulating a neutral atom or a photon, Wineland and his team focused on controlling a charged atom, the ion, in an electromagnetic well. In order to break the limit of Doppler cooling, a new cooling technique – Side-Band cooling was used to reach extreme low temperature. The well cooled ions made an ideal platform for building optical clock and quantum computer. Since 2001, Wineland and his team had realized several optical clocks with very high precision. They had also realized basic quantum logic gate in ion trap and demonstrated the scalability of ion system, proving their system is promising for practical quantum computation. This article covers the above topics and gives detailed review.

In the fourth section, the author introduces the work of Haroche and his collaborators. Haroche et al managed to build a high-Q microwave cavity with superconducting materials and cooled it down to superconducting phase. According to Meissner effect, photons in the cavity cannot penetrate the superconducting mirror and will be trapped inside, thus isolate the photons from its environment. Since the cavity has extremely high-Q, the Rydberg atoms inside the cavity are strongly correlated to the photon field, which makes a perfect platform for testing the fundamental principles of quantum mechanics. With the aid of quantum non-demolition measurement, quantum processes can be observed without destroying the state. Using this platform, Haroche et al had directly observed decoherence, quantum jump and several other quantum information processes.

Finally, the review introduces recent developments and further applications of quantum manipulation, and then ends with a discussion of the relationship between quantum and classical world. With advanced quantum manipulation techniques, people are able to investigate fundamental quantum mechanics. In return, a better understanding of quantum mechanics makes it possible to develop new technologies that will change our classical world.

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Publication:

A new epoch of quantum manipulation. Yongjian Han, Zhen Wang, and Guang-Can Guo Natl Sci Rev (March 2014) 1 (1): 91-100 DOI:10.1093/nsr/nwt024

[http://nsr.oxfordjournals.org/content/1/1/91.abstract]

News Release Source : Quantum manipulation: Filling the gap between quantum and classical world

New quantum dots herald a new era of electronics operating on asingle-atom level

New quantum dots herald a new era of electronics operating on a single-atom level

New types of solotronic structures, including the world's first quantum dots containing single cobalt ions, have been created and studied at the Faculty of Physics at the University of Warsaw. The materials and elements used to form these structures allow us forecast new trends in solotronics – a field of experimental electronics and spintronics of the future, based on operations occurring on a single-atom level.

New quantum dots herald a new era of electronics operating on a single-atom level

Electronic systems operating on the level of individual atoms would seem to be the natural consequence of efforts to achieve ever-greater miniaturization. Already now, we are able to control the behavior of individual atoms by situating them within special semiconductor structures – this is the method used to form quantum dots that contain single magnetic ions. Until recently, only two variants of such structures were known. However, physicists from the Institute of Experimental Physics at the Faculty of Physics at the University of Warsaw (FUW) have successfully created and studied two completely new types of the structures. The materials and elements used in the process make it wholly likely that solotronic devices may come into widespread use in the future.

The results, the Warsaw physicists have just published in Nature Communications, pave the way for developing the field of solotronics.

"Quantum dots are semiconductor crystals on a nanometer scale. They are so tiny that the electrons within them exist only in states with specific energies. As such, quantum dots exhibit similar characteristics to atoms, and – just like atoms – they can be stimulated with light to reach higher energy levels. Conversely, this means they emit light as they return to states with lower energy levels," says Prof. Piotr Kossacki (FUW).

The University laboratory creates quantum dots using molecular beam epitaxy. The process involves precision-heating crucibles containing elements placed in a vacuum chamber. Beams of elements are deposited on the sample. By carefully selecting materials and experimental conditions, the atoms assemble into tiny islands, known as quantum dots. The process is similar to how water vapor condenses on a hydrophobic surface.

While the dots settle, a small quantity of other atoms (for example magnetic ones) can be introduced into the vacuum chamber, with some becoming a part of the emerging dots. Once the sample is removed, it can be examined under a microscope to detect quantum dots containing a single magnetic atom at the center.

"Atoms with magnetic properties disrupt the energy levels of electrons in a quantum dot, which affects how they interact with light. As a result, the quantum dot becomes a detector of such an atom's state. The relationship also works the other way: by changing energy states of electrons in quantum dots, we can affect the respective magnetic atoms," explains Michał Papaj, a student at the UW Faculty of Physics, awarded the Gold Medal in Chemistry during last year's national competition for the best B.Sc. thesis held by the Institute of Physical Chemistry of the Polish Academy of Sciences for his work on quantum dots containing single cobalt ions.

The most powerful magnetic properties are observed in manganese atoms stripped of two electrons (Mn2+). In experiments conducted thus far, the ions have been mounted in quantum dots made of cadmium telluride (CdTe) or indium arsenide (InAs). Using CdTe dots prepared by Dr. Piotr Wojnar at the PAS Institute of Physics, in 2009 Mateusz Goryca from the University of Warsaw demonstrated the first magnetic memory operating on a single magnetic ion.

"It was commonly believed that other magnetic ions, such as cobalt (Co2+), cannot be used in quantum dots. We decided to verify this, and nature gave us a pleasant surprise: the presence of a new magnetic ion turned out not to destroy the properties of the quantum dot," says Jakub Kobak, doctoral student at the University of Warsaw.

Researchers from the University of Warsaw have presented two new systems with single magnetic ions: CdTe quantum dots with a cobalt atom, and cadmium selenide (CdSe) dots with a manganese atom.

As already stated, manganese atoms exhibit the most powerful magnetic properties. Unfortunately, they are caused by the atomic nucleus as well as the electrons, which means that quantum dots containing manganese ions are complex quantum systems. The discovery made by physicists at the University of Warsaw demonstrates that other magnetic elements – such as chromium, iron and nickel – can be used in place of manganese. These elements do not have nuclear spin, which should make quantum dots that contain them easier to manipulate.

In quantum dots where tellurium is replaced by the lighter selenium, researchers observed that the duration for which information was remembered increased by an order of magnitude. This finding suggests that using lighter elements should prolong the time quantum dots containing single magnetic ions store information, perhaps even by several orders of magnitude.

"We have demonstrated that two quantum systems that were believed not to be viable in fact worked very effectively. This opens up a broad field in our search for other, previously rejected combinations of materials for quantum dots and magnetic ions," concludes Dr. Wojciech Pacuski (FUW).

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The research into quantum dots containing single magnetic ions was funded with grants from the Polish National Science Centre and the Polish National Centre for Research and Development, as well as project funds from the Centre for Preclinical Research and Technology.

Physics and Astronomy were first taught at the University of Warsaw (UW) in 1816, at what was then the Faculty of Philosophy. The UW Astronomical Observatory was founded in 1825. Currently, the UW Faculty of Physics consists of the Institute of Experimental Physics, the Institute of Theoretical Physics, the Institute of Geophysics, the Faculty of Mathematical Methods, and the Astronomical Observatory. Research is conducted into most fields of modern physics, on scales ranging from the quantum to the cosmological. The UW Faculty of Physics has over 200 research and teaching staff, including 80 with the title of professor. The Faculty is attended by approx. 1,000 undergraduates and more than 140 doctoral students.

SCIENTIFIC PAPERS:

"Designing quantum dots for solotronics"; J. Kobak, T. Smoleński, M. Goryca, M. Papaj, K. Gietka, A. Bogucki, M. Koperski, J.-G. Rousset, J. Suffczyński, E. Janik, M. Nawrocki, A. Golnik, P. Kossacki & W. Pacuski; Nature Communications5:3191, 27 January 2014; DOI: 10.1038/ncomms4191

CONTACTS:

Prof. Piotr Kossacki
The Institute of Experimental Physics, Faculty of Physics, University of Warsaw
tel. +48 22 5532217, +48 22 5503232
email: piotr.kossacki@fuw.edu.pl

Dr Wojciech Pacuski
The Institute of Experimental Physics, Faculty of Physics, University of Warsaw
tel. +48 22 5532217, +48 22 5532329
email: wojciech.pacuski@fuw.edu.pl

LINKS:

http://www.fuw.edu.pl/

Faculty of Physics at the University of Warsaw website.

http://www.fuw.edu.pl/informacje-prasowe.html

Press Office for the Faculty of Physics at the University of Warsaw.

IMAGES:

FUW140127b_fot01s.jpg

HR: http://www.fuw.edu.pl/press/images/2014/FUW140127b_fot01.jpg

A cross-section of the quantum dots developed, constructed and tested by the Institute of Experimental Physics at the Faculty of Physics at the University of Warsaw. The color red marks an ion (cobalt or manganese) with magnetic properties (symbolized by the arrow). Yellow represents a quantum dot (cadmium telluride or indium arsenide, respectively). Blue shows the semiconductor layer securing the quantum dot. (Source: Faculty of Physics, University of Warsaw)

FUW140127b_fot02s.jpg

HR: http://www.fuw.edu.pl/press/images/2014/FUW140127b_fot02.jpg

Researchers from the Institute of Experimental Physics at the Faculty of Physics at the University of Warsaw have developed, constructed and tested groundbreaking new quantum dots containing single cobalt ions. Here Wojciech Pacuski, PhD, is shown with the molecular beam epitaxy device used to construct the quantum dots. (Source: Faculty of Physics, University of Warsaw)

News Relese Source: New quantum dots herald a new era of electronics operating on a single-atom level