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Finding quvigints in a quantum treasure map

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Credit: Markus Rambach
Researchers have struck quantum gold and created a new word by enlisting machine learning to efficiently navigate a 20-dimensional quantum treasure map.
Physicist Dr Markus Rambach from the ARC Centre of Excellence for Engineered Quantum Systems (EQUS) at The University of Queensland said the team was able to find unknown quantum states more quickly and accurately, using a technique called self-guided tomography.
The team also introduced the quvigint , which is like a qubit (the quantum version of a classical bit that takes on the values 0 or 1 ) except that it takes on not two, but 20 possible values. ....

Markus Rambach , Jacq Romero , Centre Of Excellence , University Of Queensland , Engineered Quantum Systems , Chemistry Physics Materials Sciences , Atomic Physics , Particle Physics , ஜாக் ரொமெரோ , மையம் ஆஃப் சிறப்பானது , பல்கலைக்கழகம் ஆஃப் குயின்ஸ்லாந்து , பொறியியலாளர் குவாண்டம் அமைப்புகள் , வேதியியல் இயற்பியல் பொருட்கள் அறிவியல் , அணு இயற்பியல் , துகள் இயற்பியல் ,

New technology to improve worlds most sensitive scientific instruments

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New technology to improve worlds most sensitive scientific instruments
A new technology that can improve gravitational-wave detectors, one of the most sensitive instruments used by scientific researchers, has been pioneered by physicists at The University of Western Australia in collaboration with an international team of researchers.
The new technology allows the world’s existing gravitational wave detectors to achieve a sensitivity that was previously thought only to be achievable by building much bigger detectors.
The paper, published in Communications Physics, was led by the ARC Centre of Excellence for Gravitational Wave Discovery (OzGrav) at UWA, in collaboration with the ARC Centre of Excellence for Engineered Quantum Systems, the Niels Bohr Institute in Copenhagen and the California Institute of Technology in Pasadena. ....

Carl Knox , David Blair , California Institute Of Technology , Centre Of Excellence , Department Of Physics , Niels Bohr Institute , Communications Physics , University Of Western Australia , Western Australia , Gravitational Wave Discovery , Engineered Quantum Systems , California Institute , Professor David Blair , Professor Blair , Gravitational Wave , Prime Minister , Big Bang , Black Hole , கார்ல் நாக்ஸ் , டேவிட் பிளேயர் , கலிஃபோர்னியா நிறுவனம் ஆஃப் தொழில்நுட்பம் , மையம் ஆஃப் சிறப்பானது , துறை ஆஃப் இயற்பியல் , நியீல்ஸ் போஹ்ர் நிறுவனம் , தகவல்தொடர்புகள் இயற்பியல் , பல்கலைக்கழகம் ஆஃப் மேற்கு ஆஸ்திரேலியா ,

Tiny Crystal Device Could Boost Gravitational Wave Detectors and Help Discover Black Hole Births

Tiny Crystal Device Could Boost Gravitational Wave Detectors and Help Discover Black Hole Births
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NSF / LIGO / Sonoma State University / A Simonnet, Author provided
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In 2017, astronomers witnessed the birth of a black hole for the first time. Gravitational wave detectors picked up the ripples in spacetime caused by two neutron stars colliding to form the black hole, and other telescopes then observed the resulting explosion. ....

United States , Albert Einstein , David Blair , Centre Of Excellence , Carl Knox Ozgrav Swinburne University , Niels Bohr Institute , Communications Physics , University Of Western Australia , Australian Centre Of Excellence , Big Bang , Swinburne University , Australian Centre , Engineered Quantum Systems , Emeritus Professor , Gravitational Wave Discovery , Creative Commons , ஒன்றுபட்டது மாநிலங்களில் , ஆல்பர்ட் ஐன்ஸ்டீன் , டேவிட் பிளேயர் , மையம் ஆஃப் சிறப்பானது , நியீல்ஸ் போஹ்ர் நிறுவனம் , தகவல்தொடர்புகள் இயற்பியல் , பல்கலைக்கழகம் ஆஃப் மேற்கு ஆஸ்திரேலியா , ஆஸ்திரேலிய மையம் ஆஃப் சிறப்பானது , பெரியது இடி , ஸ்வின்பர்ன் பல்கலைக்கழகம் ,

A tiny crystal device could boost gravitational wave detectors to reveal the birth cries of black holes

In 2017, astronomers witnessed the birth of a black hole for the first time. Gravitational wave detectors picked up the ripples in spacetime caused by two neutron stars colliding to form the black hole, and other telescopes then observed the resulting explosion.
But the real nitty-gritty of how the black hole formed, the movements of matter in the instants before it was sealed away inside the black hole’s event horizon, went unobserved. That’s because the gravitational waves thrown off in these final moments had such a high frequency that our current detectors can’t pick them up.
If you could observe ordinary matter as it turns into a black hole, you would be seeing something similar to the Big Bang played backwards. The scientists who design gravitational wave detectors have been hard at work to figure out how improve our detectors to make it possible. ....

United States , Albert Einstein , Carl Knox Ozgrav Swinburne University Author , Niels Bohr Institute , Communications Physics , Australian Centre Of Excellence , Big Bang , Carl Knox , Swinburne University , Australian Centre , Engineered Quantum Systems , Black Holes , Gravitational Waves , Neutron Stars , Quantum Mechanics , ஒன்றுபட்டது மாநிலங்களில் , ஆல்பர்ட் ஐன்ஸ்டீன் , நியீல்ஸ் போஹ்ர் நிறுவனம் , தகவல்தொடர்புகள் இயற்பியல் , ஆஸ்திரேலிய மையம் ஆஃப் சிறப்பானது , பெரியது இடி , கார்ல் நாக்ஸ் , ஸ்வின்பர்ன் பல்கலைக்கழகம் , ஆஸ்திரேலிய மையம் , பொறியியலாளர் குவாண்டம் அமைப்புகள் , கருப்பு துளைகள் ,

New device for scaling up quantum computers

New device for scaling up quantum computers
Australian scientists have developed a new cryogenic computer system called
Gooseberry which has potential for scaling up quantum computers from dozens to thousands of qubits.

Quantum computing – as opposed to traditional (or classical ) computing – has been around for many years now. This area of computer science involves the exploitation of physical phenomena such as superposition and entanglement to perform calculations. Unlike the bits of classical computers, which are based on binary ones and zeros, quantum computer qubits can work with multiple values simultaneously. By combining qubits in this way, it quickly becomes possible to work with exponentially larger numbers, with potentially revolutionary applications. If fully realised, quantum computers could solve problems in fields as diverse as cryptography, medicine, finance, artificial intelligence and logistics. ....

United States , New South Wales , Los Alamos National Laboratory , New Mexico , David Reilly , Kushal Das , Sebastian Pauka , Andrew White , University Of California , Centre Of Excellence , Nature Electronics , Australian Research Council , University Of Sydney , Munich Technical University , Centre For Engineered Quantum Systems , Technical University , Chief Investigator , Engineered Quantum Systems , Microsoft Senior Hardware Engineer , Future Timeline , 21st Century , 22nd Century , 23rd Century , 24th Century , 25th Century , Nano Technology ,