Physicists’ ‘light from darkness’ breakthrough named a top 2011 discovery
By By Nicole Casal Moore | 17 Dec 2011
They shook light from darkness. They coaxed something out of what we normally think of as nothing - the vacuum of space. And now their work has been named one of the top 10 breakthroughs of the year by Physics World, the international magazine announced today.
University of Michigan physics researcher Franco Nori is involved in the work, which was published in Nature in November.
The physicists directly observed, for the first time, light particles that flicker in and out of existence in the vacuum. They witnessed the long-predicted quantum mechanical phenomenon known as the dynamical Casimir effect.
"One of the profound consequences of quantum mechanics is that we know that something can come from nothing," Nori said. "The vacuum is actually teeming with activity, the question is how to harness it and observe it because the particles move in an out of existence in the blink of an eye."
This background activity of fleeting particles is known as quantum vacuum fluctuations. It's the impetus for what's known as the static Casimir effect, an attractive force that can pull two parallel mirrors together in a vacuum. That effect is caused by a pressure drop between the mirrors because more photons can exist on the outsides of them. It was measured in the late '90s.
Scientists theorised that a similar force could be created by accelerating one mirror to near light speed. This "dynamical Casimir effect" was thought to be capable of producing real, observable photons, or light particles, from these quantum vacuum fluctuations. That's just what these physicists observed.
Based at the Chalmers University of Technology in Sweden, they achieve this by building a special type of superconducting circuit that could simulate a mirrored surface without a physical device that would be difficult to speed up to such high speeds.
University of Michigan physics researcher Franco Nori is involved in the work, which was published in Nature in November.
The physicists directly observed, for the first time, light particles that flicker in and out of existence in the vacuum. They witnessed the long-predicted quantum mechanical phenomenon known as the dynamical Casimir effect.
"One of the profound consequences of quantum mechanics is that we know that something can come from nothing," Nori said. "The vacuum is actually teeming with activity, the question is how to harness it and observe it because the particles move in an out of existence in the blink of an eye."
This background activity of fleeting particles is known as quantum vacuum fluctuations. It's the impetus for what's known as the static Casimir effect, an attractive force that can pull two parallel mirrors together in a vacuum. That effect is caused by a pressure drop between the mirrors because more photons can exist on the outsides of them. It was measured in the late '90s.
Scientists theorised that a similar force could be created by accelerating one mirror to near light speed. This "dynamical Casimir effect" was thought to be capable of producing real, observable photons, or light particles, from these quantum vacuum fluctuations. That's just what these physicists observed.
Based at the Chalmers University of Technology in Sweden, they achieve this by building a special type of superconducting circuit that could simulate a mirrored surface without a physical device that would be difficult to speed up to such high speeds.