The discovery of the quantum world could rewrite the well-known laws of physics

This paradox is illustrated by the Greenberger–Horne–Zeilinger (GHZ) paradox, which shows that quantum theory cannot be explained in a locally realistic way. In some cases, mathematical descriptions lead to seemingly absurd conclusions, where classical logic entirely breaks down—sometimes even suggesting, mathematically, that 1 equals −1. Such paradoxes play a key role in understanding just how differently the quantum world operates.

37 dimensions in a single particle

One of the most recent studies aimed to explore the limits of non-classical behaviour in the quantum world. Scientists created photons that could be described along 37 different dimensions. These dimensions do not represent new physical worlds but rather different quantum states and reference parameters along which particle behaviour can be examined.

Just as human experience is built upon three spatial dimensions and one temporal dimension, these photons existed along multiple, parallel axes of description. The difference is that the quantum dimensions are abstract, tied to mathematical and physical parameters rather than directly perceivable directions.

In the experiment, a variant of the GHZ paradox was encoded into coherent light. The uniformity of the light’s colour and wavelength allowed the photons to be manipulated with extraordinary precision. As a result, researchers succeeded in reproducing the most unconventional quantum state observed to date.

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What does this reveal about the quantum world?

According to the researchers, the results suggest that quantum physics remains far from fully understood. Although the theory has existed for over a century, it is quite possible that we have only scratched the surface of how the quantum world truly operates.

Investigating high-dimensional quantum states could open up new avenues of research and help us better understand the principles underlying quantum phenomena. The scientists hope that these findings will pave the way for even more astonishing—and truly remarkable—discoveries in the future.