A New Form of Light Discovered –“Enables Strange Possibilities”

 

 

Dark-energy

 

“We’re interested in finding out how we can change the way light behaves, and how that could be useful,” says Trinity College professor Paul Eastham. “What I think is so exciting about this result is that even this fundamental property of light, that physicists have always thought was fixed, can be changed.”


Theoretical physicists since the 1980s have speculated how quantum mechanics works for particles that are free to move in only two of the three dimensions of space. They discovered that this would enable strange new possibilities, including particles whose quantum numbers were fractions of those expected. New research from Trinity College, Dublin shows, for the first time, that these speculations can be realized with light.

 

One of the measurable characteristics of a beam of light is known as angular momentum. Until now, it was thought that in all forms of light the angular momentum would be a multiple of Planck’s constant (the physical constant that sets the scale of quantum effects). Now, physicists from Trinity College Dublin’s School of Physics and the CRANN Institute, Trinity College, have discovered a new form of light, which will impact our understanding of the fundamental nature of light.

The team from Trinity College Dublin’s School of Physics, along with Professor John Donegan from CRANN, have demonstrated a new form of light where the angular momentum of each photon (a particle of visible light) takes only half of this value. This difference, though small, is profound.

“My research focuses on nanophotonics, which is the study of the behaviour of light on the nanometer scale,” said
professor John Donegan. “A beam of light is characterised by its colour or wavelength and a less familiar quantity known as angular momentum. Angular momentum measures how much something is rotating. For a beam of light, although traveling in a straight line it can also be rotating around its own axis. So when light from the mirror hits your eye in the morning, every photon twists your eye a little, one way or another.”

“Our discovery will have real impacts for the study of light waves in areas such as secure optical communications.”

“The topic of light has always been one of interest to physicists, while also being documented as one of the areas of physics that is best understood,” said Stefano Sanvito, Director of CRANN. “This discovery is a breakthrough for the world of physics and science alike. I am delighted to once again see CRANN and Physics in Trinity producing fundamental scientific research that challenges our understanding of light.”

To make this discovery, the team involved used an effect discovered in the same institution almost 200 years before. In the 1830s, mathematician William Rowan Hamilton and physicist Humphrey Lloyd found that, upon passing through certain crystals, a ray of light became a hollow cylinder. The team used this phenomenon to generate beams of light with a screw-like structure.

Analyzing these beams within the theory of quantum mechanics they predicted that the angular momentum of the photon would be half-integer, and devised an experiment to test their prediction. Using a specially constructed device they were able to measure the flow of angular momentum in a beam of light. They were also able, for the first time, to measure the variations in this flow caused by quantum effects. The experiments revealed a tiny shift, one-half of Planck’s constant, in the angular momentum of each photon.

The image at the top of the page shows a type Ia supernovae, which are brighter than whole galaxies and visible billions of light-years away. In recent years, The Supernova Cosmology Project devised ways of finding Type Ia supernovae “on demand,” then measured the expansion of the universe with a precision that led to the discovery of dark energy.

The Science Advances journal article can be viewed here.

The Daily Galaxy via Trinity College, Dublin

Image credit: lbl.gov

 

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