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In an article published in the PNAS scientific journal, researchers from Aalto University and the VTT Technical Research Centre of Finland showed experimentally that vacuum has properties not previously observed. According to the laws of quantum mechanics, it is a state with abundant potentials. Vacuum contains momentarily appearing and disappearing virtual pairs, which can be converted into detectable light particles.
The researchers conducted a mirror experiment to show that by changing the position of the mirror in a vacuum, virtual particles can be transformed into real photons that can be experimentally observed. In a vacuum, there is energy and noise, the existence of which follows the uncertainty principle in quantum mechanics.
’If we act fast enough, we can prevent the particles from recombining – they will then be transformed into real particles that can be detected’, says Dr. Sorin Paraoanu from the Aalto University School of Science.
Picture:Artist's impression of the creation of entangled photon pair, a process which is seeded by the vacuum fluctuations. The source of the pair is an actual microscope image of the chain of Superconducting Quantum Interference Devices of the metamaterial sample in which the dynamical Casimir effect was studied. The speed of light in this material could be varied by changing the magnetic field through the SQUID loops.
For the experiment, the researchers used an array of superconducting quantum-interference devices (SQUID). These parts resemble devices used in imaging small magnetic fields in the brain. By changing the magnetic field, the speed of light in the device can be changed. From the standpoint of the electromagnetic field of the vacuum, radiation reflecting from this kind of device experiences it as a moving mirror.
Picture: Optical microscope image of the chain of Superconducting Quantum Interference Devices of the metamaterial sample in which the dynamical Casimir effect was studied. The speed of light in this material could be varied by changing the magnetic field through the SQUID loops.
’By quickly varying the speed of light in the array, we can extract microwave photons out of the vacuum's quantum noise’, explains doctoral student Pasi Lähteenmäki.
Future research directions for these kinds of devices include the creation of an artificial event horizon and observation or Hawking radiation emanating from it. The present observation will help cosmologists to get closer to the riddle of the birth of the universe and advance the development of extremely powerful quantum computers.
Picture: Picture of open dry dilution fridge by BlueFors Cryogenics, similar to one where the measurements were made. This one is capable of reaching temperatures below 7 mK (-273.143 C). BlueFors Cryogenics is a company founded by former staff from O.V. Lounasmaa Laboratory and a supplier of low temperature research equipment.
A link to the research article published in the PNAS journal: http://www.pnas.org/content/early/2013/02/11/1212705110.abstract
A link to the news in the Nature journal:
Pasi Lähteenmäki, doctoral student
pasi.lahteenmaksi [at] aalto [dot] fi (email@example.com)
Tel. +358 (0)50 344 2306
O.V. Lounasmaa Laboratory
Low Temperature Laboratory Research Unit
Aalto University School of Science
Docent Sorin Paraoanu, leader of the research group
sorin.paraoanu [at] aalto [dot] fi
O.V. Lounasmaa Laboratory's
Kvantti research group,
Aalto University School of Science http://ltl.tkk.fi/wiki/LT/Kvantti
Page content by: viestinta-sci [at] aalto [dot] fi (School of Science Communications) | Last updated: 18.06.2014.