In a recent study, researchers have discovered that silicon can display chirality, a form of asymmetry between two objects. The research group, led by Professor Keiichi Edamoto from the National Institute for Materials Science in Japan, used a technique called Mie scattering to demonstrate that the loss of chirality in silicon was not absolute.

This groundbreaking discovery could have a significant impact on the field of nanophotonics. According to the researchers, this research could provide a new pathway to manipulate light on the nanoscale level.

In this study, researchers revealed that chirality in silicon can be restored through the use of Mie scattering. This technique involves the interference of light waves passing through a medium, such as silicon, and the resulting wave interference creates an asymmetry in the medium. This asymmetry causes the light to scatter in two different directions. The research team was able to successfully demonstrate the loss and restoration of chirality in silicon using Mie scattering.

This study is the first to demonstrate the potential for manipulating light on the nanoscale level using chirality in silicon. The research has opened the door for further investigation into the effects of chirality on other materials, as well as its potential

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source: Phys.org