Playing with light and symmetry

Playing with light and symmetry
In a recent study at the University of Twente, researchers discovered a way to scatter light in a special, symmetrical way using nanotechnology. This has potential for future technologies such as anti-counterfeiting.

For the study, the researchers printed cubes about five times smaller than the diameter of a human hair, which consisted of rods in random directions. But by deliberately applying mirror symmetry to the cubes, something surprising happened. There was a huge increase or decrease in light intensity right on the symmetry line.

Symmetrical light scattering

Depending on the direction of vibration (polarisation) of the incident light on the random rods, a bright line or an extra dark line could be seen on the cubes. This effect could be seen in the experimental design, but also calculated in advance. "Calculating light scattering in such complex 3D structures was only possible with special software, developed at UT by (the team of) Ivo Vellekoop. It was therefore fantastic to see the effect in the real cubes as well," says researcher Pepijn Pinkse.

Controlling light in a mirror-symmetrical environment offers opportunities for anti-counterfeiting, where you can create unique light patterns to check the authenticity of your passport, for example. The multiple scattering of light that occurs is very difficult to falsify. This could help to combat counterfeit products in the future.

Research at the smallest level

In addition, the research is mainly done to gain more insight into the behaviour of light at the smallest level. The precise behaviour of light can provide insight into the smallest deviations during the production of microchips, for example. This allows errors to be detected at an early stage, without physically damaging the product.

Learn more

The research was carried out by researchers from the MESA+ Institute for Nanotechnology and the TechMed Centre of the University of Twente, in collaboration with the Institute of Electronic Structure and Laser in Greece. The researchers published their results in a publication entitled Mirror Symmetry in three-dimensional Multiple-Scattering Media in the scientific journal Physical Review Letters.

Pepijn Pinkse is Professor Adaptive Quantum Optics ( Faculty of S&T/ MESA+ ). He is also director of the Centre for QUAntum NanoTechnology Twente (QUANT). This research resulted from the NWO project ’Free form scattering optics’.

10.1103/PhysRevLett.­133.223802

Prospective students
Current students
Employees (Service Portal)
Alumni
Journalists
Employers

Contact People Pages: find employees
Careers
Library
Logo & visual identity
Webshop merchandise

Business space on campus Industrial doctoral degree places Support by Novel-T Submit internship/Find talent DesignLab

Contact People pages (UT phone directory) Press information Faculties/schools Research institutes