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Archive for the ‘quantum physics’ category: Page 501

Nov 27, 2020

Unprecedented accuracy in quantum electrodynamics: Giant leap toward solving proton charge radius puzzle

Posted by in categories: particle physics, quantum physics

Physicists at the Max Planck Institute of Quantum Optics have tested quantum mechanics to a completely new level of precision using hydrogen spectroscopy, and in doing so they came much closer to solving the well-known proton charge radius puzzle.

Scientists at the Max Planck Institute of Quantum Optics (MPQ) have succeeded in testing quantum electrodynamics with unprecedented accuracy to 13 decimal places. The new measurement is almost twice as accurate as all previous hydrogen measurements combined and moves science one step closer to solving the proton size puzzle. This high accuracy was achieved by the Nobel Prize-winning frequency comb technique, which debuted here for the first time to excite atoms in high-resolution spectroscopy. The results are published today in Science.

Physics is said to be an exact science. This means that predictions of physical theories – exact numbers – can be verified or falsified by experiments. The experiment is the highest judge of any theory. Quantum electrodynamics, the relativistic version of quantum mechanics, is without doubt the most successful theory to date. It allows extremely precise calculations to be performed, for example, the description of the spectrum of atomic hydrogen to 12 decimal places. Hydrogen is the most common element in the universe and at the same time the simplest with only one electron. And still, it hosts a mystery yet unknown.

Nov 27, 2020

Ultracold atoms put high-temperature superconductors under the microscope

Posted by in categories: particle physics, quantum physics

Physicists use a Bose-Einstein condensate to study phase transitions in an iron pnictide superconductor.


Physicists have deployed a Bose-Einstein condensate (BEC) as a “quantum microscope” to study phase transitions in a high-temperature superconductor. The experiment marks the first time a BEC has been used to probe such a complicated condensed-matter phenomenon, and the results – a solution to a puzzle involving transition temperatures in iron pnictide superconductors – suggest that the technique could help untangle the complex factors that enhance and inhibit high-temperature superconductivity.

A BEC is a state of matter that forms when a gas of bosons (particles with integer quantum spin) is cooled to such low temperatures that all the bosons fall into the same quantum state. Under these conditions, the bosons are highly sensitive to tiny fluctuations in the local magnetic field, which perturb their collective wavefunction and create patches of greater and lesser density in the gas. These variations in density can then be detected using optical techniques.

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Nov 27, 2020

Apple Wins a Patent for Future Smart iPhone Cases and Watch Bands that use Quantum Tunneling Material

Posted by in categories: mobile phones, quantum physics

The U.S. Patent and Trademark Office officially published a series of 68 newly granted patents for Apple Inc. today. In this particular report we cover Apple’s invention that reveals breakthrough quantum tunneling touch sensitive materials for future iPhone smart cases and Apple Watch bands.

Nov 26, 2020

Direct Visualization of Quantum Dots Reveals Shape of Quantum Wave Function of the Trapped Electrons

Posted by in categories: materials, quantum physics

Researchers used a scanning tunneling microscope to visualize quantum dots in bilayer graphene, an important step toward quantum information technologies.

Trapping and controlling electrons in bilayer graphene quantum dots yields a promising platform for quantum information technologies. Researchers at UC Santa Cruz have now achieved the first direct visualization of quantum dots in bilayer graphene, revealing the shape of the quantum wave function of the trapped electrons.

The results, published on November 23, 2020, in Nano Letters, provide important fundamental knowledge needed to develop quantum information technologies based on bilayer graphene quantum dots.

Nov 25, 2020

Scientists discover how to use time crystals to power superconductors

Posted by in categories: computing, quantum physics

Physicists propose using time crystals to bring about a quantum computing revolution.

Nov 24, 2020

Quantum X-ray microscope “ghost images” molecules using entanglement

Posted by in category: quantum physics

Engineers at Brookhaven National Laboratory have designed a strange new X-ray microscope that takes advantage of the spooky world of quantum physics to “ghost image” biomolecules in high resolution but at a lower radiation dose.

X-ray microscopes are useful tools for imaging samples in high resolution, but the radiation involved can damage sensitive samples such as viruses, bacteria and some cells. Reducing the radiation dose is one way around that problem, but unfortunately that also reduces the resolution of the image.

Now, the Brookhaven team has found a way to maintain higher resolution with a lower radiation dose – and all they had to do was tap into the quirks of quantum physics that boggled minds like Einstein’s.

Nov 23, 2020

Scientists Create Electronic Gadget Powered by Quantum Tunneling

Posted by in categories: neuroscience, quantum physics

Tiny Dancer

Chakrabartty’s tunneling barrier was built in just such a way that “you can control the flow of electrons. You can make it reasonably slow, down to one electron every minute and still keep it reliable.”

The team is hoping the technology could one day power glucose or even brain activity monitors without the need for batteries.

Nov 23, 2020

Upcoming Video Game Will Generate New Levels Using Qiskit and a Quantum Simulator

Posted by in categories: computing, entertainment, quantum physics

By Christopher Sciacca

The first video games debuted in the1950s, later reaching mainstream popularity in the 1970s and 80s with arcades and home video systems like Atari and Commodore 64. Remember SpaceWar! and Pong? While limited by the capabilities of the hardware, they laid the foundation for the games we develop and play today, which by 2025 is expected to be a whopping $256 billion industry.

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Nov 21, 2020

This Weird, Cheap Quantum Device Can Run For a Year With a Single Kick of Energy

Posted by in categories: computing, quantum physics

As our need for electronic gadgets and sensors grows, scientists are coming up with new ways to keep devices powered for longer on less energy.

The latest sensor to be invented in the lab can go for a whole year on a single burst of energy, aided by a physics phenomenon known as quantum tunnelling.

The tunnelling aspect means that with the help of a 50-million-electron jumpstart, this simple and inexpensive device (made up of just four capacitors and two transistors) can keep going for an extended period of time.

Nov 20, 2020

Cracking the secrets of an emerging branch of physics

Posted by in categories: computing, quantum physics

This discovery opens the door to topological quantum computing. Current quantum computing systems, where the elemental units of calculation are qubits that perform superfast calculations, require superconducting materials that only function in extremely cold conditions. Fluctuations in heat can throw one of these systems out of whack.

“The properties inherent to materials such as TaP could form the basis of future qubits,” says Nguyen. He envisions synthesizing TaP and other topological semimetals — a process involving the delicate cultivation of these crystalline structures — and then characterizing their structural and excitational properties with the help of neutron and X-ray beam technology, which probe these materials at the atomic level. This would enable him to identify and deploy the right materials for specific applications.

“My goal is to create programmable artificial structured topological materials, which can directly be applied as a quantum computer,” says Nguyen. “With infinitely better heat management, these quantum computing systems and devices could prove to be incredibly energy efficient.”