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Archive for the ‘particle physics’ category: Page 466

Feb 8, 2019

Life on the edge in the quantum world

Posted by in categories: alien life, computing, particle physics, quantum physics

Quantum physics sets the laws that dominate the universe at a small scale. The ability to harness quantum phenomena could lead to machines like quantum computers, which are predicted to perform certain calculations much faster than conventional computers. One major problem with building quantum processors is that the tracking and controlling quantum systems in real time is a difficult task because quantum systems are overwhelmingly fragile: Manipulating these systems carelessly introduces significant errors in the final result. New work by a team at Aalto could lead to precise quantum computers.

The researchers report controlling in a custom-designed electrical circuit called a transmon. Chilling a transmon chip to within a few thousandths of a degree above absolute zero induces a , and the chip starts to behave like an artificial atom. One of the features that interests researchers is that the of the transmon can only take specific values, called . The energy levels are like steps on a ladder: A person climbing the ladder must occupy a step, and can’t hover somewhere between two steps. Likewise, the transmon energy can only occupy the set values of the energy levels. Shining microwaves on the circuit induces the transmon to absorb the energy and climb up the rungs of the ladder.

In work published 8 February in the journal Science Advances, the group from Aalto University led by Docent Sorin Paraoanu, senior university lecturer in the Department of Applied Physics, has made the transmon jump more than one energy level in a single go. Previously, this has been possible only by very gentle and slow adjustments of the microwave signals that control the device. In the new work, an additional microwave control signal shaped in a very specific way allows a fast, precise change of the energy level. Dr. Antti Vepsäläinen, the lead author, says, “We have a saying in Finland: ‘hiljaa hyvää tulee’ (slowly does it). But we managed to show that by continuously correcting the state of the system, we can drive this process more rapidly and at .”

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Feb 6, 2019

ANU successfully measures light for quantum internet data transfer

Posted by in categories: internet, particle physics, quantum physics

The quantum internet will require fast-moving data and the Australian National University believes it has found a way to measure information stored in light particles which will pave the way for a safe “data superhighway”.

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Feb 6, 2019

Quantum dot white LEDs achieve record efficiency

Posted by in categories: nanotechnology, particle physics, quantum physics, sustainability

Circa 2018


Researchers have demonstrated nanomaterial-based white-light-emitting diodes (LEDs) that exhibit a record luminous efficiency of 105 lumens per watt. Luminous efficiency is a measure of how well a light source uses power to generate light. With further development, the new LEDs could reach efficiencies over 200 lumens per watt, making them a promising energy-efficient lighting source for homes, offices and televisions.

“Efficient LEDs have strong potential for saving energy and protecting the environment,” said research leader Sedat Nizamoglu, Koç University, Turkey. “Replacing conventional lighting sources with LEDs with an of 200 lumens per watt would decrease the global electricity consumed for lighting by more than half. That reduction is equal to the electricity created by 230 typical 500-megawatt coal plants and would reduce greenhouse gas emissions by 200 million tons.”

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Feb 6, 2019

Femtosecond laser pulses push spintronics and magnonics to the limit

Posted by in categories: materials, particle physics

An international team composed by scientists of Radboud University and the University Politecnico di Milano has realized the ultimate speed limit of the control of spins in a solid state magnetic material.

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Feb 6, 2019

Move Over, Spintronics: Here Comes Magnonics to the Rescue of Electronics

Posted by in categories: electronics, particle physics

New type of logic gate promises to completely replace electricity with magnetic spin waves for computation.

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Feb 6, 2019

Electromagnetic Pulse (EMP) Attack: A Preventable Homeland Security Catastrophe

Posted by in categories: climatology, computing, government, particle physics, security

A major threat to America has been largely ignored by those who could prevent it. An electromagnetic pulse (EMP) attack could wreak havoc on the nation’s electronic systems-shutting down power grids, sources, and supply mechanisms. An EMP attack on the United States could irreparably cripple the country. It could simultaneously inflict large-scale damage and critically limit our recovery abilities. Congress and the new Administration must recognize the significance of the EMP threat and take the necessary steps to protect against it.

Systems Gone Haywire

An EMP is a high-intensity burst of electromagnetic energy caused by the rapid acceleration of charged particles. In an attack, these particles interact and send electrical systems into chaos in three ways: First, the electromagnetic shock disrupts electronics, such as sensors, communications systems, protective systems, computers, and other similar devices. The second component has a slightly smaller range and is similar in effect to lightning. Although protective measures have long been established for lightning strikes, the potential for damage to critical infrastructure from this component exists because it rapidly follows and compounds the first component. The final component is slower than the previous two, but has a longer duration. It is a pulse that flows through electricity transmission lines-damaging distribution centers and fusing power lines. The combination of the three components can easily cause irreversible damage to many electronic systems.

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Feb 4, 2019

Quantum Physics May Be Even Spookier Than You Think

Posted by in categories: particle physics, quantum physics

What actually occurs in a superposition—the strange condition in which entities seem to be in two or more places or states at the same? This is the root question in quantum mechanics, and the answer was unknown until now. In a new research paper, a joint team of researchers from Israel and Japan, has described a novel experiment that could finally shed light on the true nature of this puzzling phenomenon.

The researchers estimate that their experiment, that can be carried out within a few months, could possibly allow scientists a sneak peek at where an object like a particle of light i.e. a photon will actually be when it is positioned in a superposition. And as per their predictions, the answer can be even stranger and more baffling than “two places at once.”

The characteristic occurrence of a superposition involves firing photons at two parallel slits into a barrier. One fundamental aspect of quantum mechanics is that the tiny particles can behave like waves, so that those passing through one slit “interfere” with those passing through the other. These wavy ripples either boost or cancel one another to create a new characteristic pattern on a detector screen. The oddest fact is that this interference occurs even if only a single particle is fired at a time. The particle seems to somehow pass through both slits simultaneously and displays interference with itself. This is a true superposition.

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Feb 3, 2019

Plastics are being glued together in the ocean by bacteria, scientists find

Posted by in categories: chemistry, food, particle physics

Researchers at Heriot-Watt University in Edinburgh used water collected from the Faroe-Shetland Channel and the Firth of Forth to set up their experiments. Plastics were added to the seawater and then incubated in conditions simulating the ocean’s surface. Within minutes, the minuscule pieces of plastic grouped together with bacteria, algae and other organic particles. The scientists are said to have been surprised to discover large masses of biopolymers formed the bulk of these plastic agglomerates. Team member Stephen Summers said: “This is a first step towards understanding how nanoplastics interact with natural biopolymers throughout the world’s oceans. ”This is very important, as it is at this small scale that much of the world’s biogeochemistry occurs. ”We found that the biopolymers envelope or engulf the nanoplastic particles, which caused the plastics to agglomerate into clumps. ”The nanoplastics, which are 100–200 times smaller than a bacterial cell, were actually incorporated into the agglomerates, which became visible to the naked eye in our lab experiments. ”The fact that these agglomerates become large enough to see raises concern, as they are likely to be seen as a food source by small marine animals.” We found that the biopolymers envelope or engulf the nanoplastic particles, which caused the plastics to agglomerate into clumps.


Researchers said micro and nano plastic particles mix with the bacteria secretions within minutes, forming clumps.

Press Association

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Feb 3, 2019

The Search for New Physics & CERN’s FCC Future Circular Collider

Posted by in categories: astronomy, engineering, environmental, ethics, existential risks, particle physics, physics, quantum physics, science

It is a few years since I posted here on Lifeboat Foundation blogs, but with the news breaking recently of CERN’s plans to build the FCC [1], a new high energy collider to dwarf the groundbreaking engineering triumph that is the LHC, I feel obliged to write a few words.

The goal of the FCC is to greatly push the energy and intensity frontiers of particle colliders, with the aim of reaching collision energies of 100 TeV, in the search for new physics [2]. Below linked is a technical note I wrote & distributed last year on 100 TeV collisions (at the time referencing the proposed China supercollider [3][4]), highlighting the weakness of the White Dwarf safety argument at these energy levels, and a call for a more detailed study of the Neutron star safety argument, if to be relied on as a solitary astrophysical assurance. The argument applies equally to the FCC of course:

The Next Great Supercollider — Beyond the LHC : https://environmental-safety.webs.com/TechnicalNote-EnvSA03.pdf

The LSAG, and others including myself, have already written on the topic of astrophysical assurances at length before. The impact of CR on Neutron stars is the most compelling of those assurances with respect to new higher energy colliders (other analogies such as White Dwarf capture based assurances don’t hold up quite as well at higher energy levels). CERN will undoubtedly publish a new paper on such astrophysical assurances as part of the FCC development process, though would one anticipate it sooner rather than later, to lay to rest concerns of outsider-debate incubating to a larger audience?

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Feb 1, 2019

Scientists ‘hijack’ open-access quantum computer to tease out quantum secrets

Posted by in categories: computing, particle physics, quantum physics

The rules of quantum mechanics describe how atoms and molecules act very differently from the world around us. Scientists have made progress toward teasing out these rules—essential for finding ways to make new molecules and better technology—but some are so complex that they evade experimental verification.

With the advent of open-access computers, scientists at the University of Chicago saw an opportunity to do a very unusual experiment to test some of these quantum principles. Their study, which appeared Jan. 31 in Nature Communications Physics, essentially hijacks a quantum computer to discover fundamental truths about the quantum behavior of electrons in molecules.

“Quantum computing is a really exciting realm to explore fundamental questions. It allows us to observe aspects of quantum theory that are absolutely untouchable with classical computers,” said Prof. David Mazziotti, professor of chemistry and author on the paper.

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