Tag Archives: breakthrough

In a pioneering study, Professor Menon and his team were able to discover half-light, half-matter particles in atomically thin semiconductors (thickness ~ a millionth of a single sheet of paper) consisting of two-dimensional (2D) layer of molybdenum and sulfur atoms arranged similar to graphene. They sandwiched this 2D material in a light trapping structure to realize these composite quantum particles.

Credit: CCNY

Study Unveils New Half-Light Half-Matter Quantum Particles

Prospects of developing computing and communication technologies based on quantum properties of light and matter may have taken a major step forward thanks to research by City College of New York physicists led by Dr. Vinod Menon.

In a pioneering study, Professor Menon and his team were able to discover half-light, half-matter particles in atomically thin semiconductors (thickness ~ a millionth of a single sheet of paper) consisting of two-dimensional (2D) layer of molybdenum and sulfur atoms arranged similar to graphene. They sandwiched this 2D material in a light trapping structure to realize these composite quantum particles.

“Besides being a fundamental breakthrough, this opens up the possibility of making devices which take the benefits of both light and matter,” said Professor Menon.  

In a pioneering study, Professor Menon and his team were able to discover half-light, half-matter particles in atomically thin semiconductors (thickness ~ a millionth of a single sheet of paper) consisting of two-dimensional (2D) layer of molybdenum and sulfur atoms arranged similar to graphene. They sandwiched this 2D material in a light trapping structure to realize these composite quantum particles. Credit: CCNY
In a pioneering study, Professor Menon and his team were able to discover half-light, half-matter particles in atomically thin semiconductors (thickness ~ a millionth of a single sheet of paper) consisting of two-dimensional (2D) layer of molybdenum and sulfur atoms arranged similar to graphene. They sandwiched this 2D material in a light trapping structure to realize these composite quantum particles.
Credit: CCNY

For example one can start envisioning logic gates and signal processors that take on best of light and matter. The discovery is also expected to contribute to developing practical platforms for quantum computing. 

Dr. Dirk Englund, a professor at MIT whose research focuses on quantum technologies based on semiconductor and optical systems, hailed the City College study.

“What is so remarkable and exciting in the work by Vinod and his team is how readily this strong coupling regime could actually be achieved. They have shown convincingly that by coupling a rather standard dielectric cavity to exciton–polaritons in a monolayer of molybdenum disulphide, they could actually reach this strong coupling regime with a very large binding strength,” he said. 

Professor Menon’s research team included City College PhD students, Xiaoze Liu, Tal Galfsky and Zheng Sun, and scientists from Yale University, National Tsing Hua University (Taiwan) and Ecole Polytechnic -Montreal (Canada).

The study appears in the January issue of the journal “Nature Photonics.” It was funded by the U.S. Army Research Laboratory’s Army Research Office and the National Science Foundation through the Materials Research Science and Engineering Center – Center for Photonic and Multiscale Nanomaterials. 

Source: The City College New of York

Quantum physics breakthrough: Scientists solve 100-year-old puzzle

Two fundamental concepts of the quantum world are actually just different manifestations of the same thing, says Waterloo researcher.

By Jenny Hogan

Centre for Quantum Technologies


A Waterloo researcher is part of an international team that has proven that two peculiar features of the quantum world – long thought to be distinct – are actually different manifestations of the same thing.

The breakthrough findings are published today inNature Communications. The two distinct ideas in question have been fundamental concepts in quantum physics since the early 1900s. They are what is known as the wave-particle duality and the uncertainty principle.

“We were guided by a gut feeling, and only a gut feeling, that there should be a connection,” says Patrick Coles, now a postdoctoral fellow at the Institute for Quantum Computing and the Department of Physics and Astronomy at the University of Waterloo.

  • Wave-particle duality is the idea that a quantum particle can behave like a wave, but that the wave behavior disappears if you try to locate the object.
  • The uncertainty principle is the idea that it’s impossible to know certain pairs of things about a quantum particle at once. For example, the more precisely you know the position of an atom, the less precisely you can know the speed with which it’s moving.

Coles was part of the research team at the National University of Singapore that made the discovery that wave-particle duality is simply the quantum uncertainty principle in disguise.

Like discovering the Rosetta Stone of quantum physics

“It was like we had discovered the ‘Rosetta Stone’ that connected two different languages,” says Coles. “The literature on wave-particle duality was like hieroglyphics that we could translate into our native tongue. We had several eureka moments when we finally understood what people had done.”

The research team at Singapore’s Centre for Quantum Technologies, included Jedrzej Kaniewski and Stephanie Wehner, now both researchers at the Netherlands’ Delft University of Technology.

“The connection between uncertainty and wave-particle duality comes out very naturally when you consider them as questions about what information you can gain about a system. Our result highlights the power of thinking about physics from the perspective of information,” says Wehner.

The wave-particle duality is perhaps most simply seen in a double slit experiment, where single particles, electrons, say, are fired one by one at a screen containing two narrow slits. The particles pile up behind the slits not in two heaps as classical objects would, but in a stripy pattern like you’d expect for waves interfering. At least this is what happens until you sneak a look at which slit a particle goes through – do that and the interference pattern vanishes.

The discovery deepens our understanding of quantum physics and could prompt ideas for new applications of wave-particle duality.

New protocols for quantum cryptography possible

Coles, Kaniewski and Wehner are experts in a form of mathematical equations known as ‘entropic uncertainty relations.’ They discovered that all the maths previously used to describe wave-particle duality could be reformulated in terms of these relations.

Because the entropic uncertainty relations used in their translation have also been used in proving the security of quantum cryptography – schemes for secure communication using quantum particles – the researchers suggest the work could help inspire new cryptography protocols.

How is nature itself constructed?

In earlier papers, the researchers found connections between the uncertainty principle and other physics, namely quantum ‘non-locality’ and the second law of thermodynamics. The tantalizing next goal for the researchers is to think about how these pieces fit together and what bigger picture that paints of how nature is constructed.

Source: University of WaterLoo