Researchers at the Würzburg site of the Cluster of Excellence ctd.qmat have succeeded in transferring the topological quantum Hall and spin Hall effects to a hybrid light-matter system by harnessing targeted material design. The team led by Professor Sebastian Klembt generated this optical quantum phenomenon by using polaritons—hybrid light-matter particles. This advance paves the way for optical information processing. The results have been published in Nature Communications.

Back in 1980, Nobel laureate Klaus von Klitzing, then working in Würzburg, first demonstrated topological charge transport with the quantum Hall effect.

In 2006, Professor Laurens Molenkamp at JMU Würzburg provided the world’s first experimental evidence of the quantum spin Hall effect as an intrinsic property of a topological insulator. Both phenomena protect electrons from scattering.

In a world-first, quantum physicists at ANU have observed atoms entangled in motion. Their experiment using helium atoms, represents a major advancement on similar experiments using photons, which are particles of light.

But unlike photons, helium atoms have mass and experience gravity.

Read the full article in Nature Communications:
https://www.nature.com/articles/s4146… development unlocks new ways to examine one of the biggest unanswered questions about the universe: how does the small-scale physics of quantum mechanics interact with gravity and general relativity at the universal scale? By observing quantum entanglement in atoms for the first time, are we one small step closer to finding out whether the “Theory of Everything” is not just hot air?

This development unlocks new ways to examine one of the biggest unanswered questions about the universe: how does the small-scale physics of quantum mechanics interact with gravity and general relativity at the universal scale?

By observing quantum entanglement in atoms for the first time, are we one small step closer to finding out whether the “Theory of Everything” is not just hot air?

For more visit https://science.anu.edu.au/

For the first time, a team of physicists in Austria has carried out an experiment that appears to verify the principle of indefinite causal order: an idea that suggests that timelines of events can exist in multiple orders at the same time. Led by Carla Richter at the Vienna Center for Quantum Science and Technology, the researchers hope their result could finally allow physicists to verify a key prediction of quantum theory. The results have been published in PRX Quantum.

The basic principle of cause and effect underpins everything that happens in the classical world: for an event to occur, it must be triggered by another event in its past. Yet in the quantum world, physicists have long suspected that these rules may not always apply.

Just as quantum particles can exist in superpositions of multiple states which collapse to a single outcome when measured, indefinite causal order suggests something similar may apply to entire sequences of events. Until a measurement is made, multiple orders of cause and effect can exist in superposition.