A method was developed that enables information to be contained in simple plastic foils with a thickness of less than 50 μm, which is thinner than a human hair. Organic luminescent molecules are introduced into the transparent plastic foils. In the beginning, these molecules are in an inactive, dark state; by locally using ultraviolet irradiation, it is possible to turn this dark state into an active, luminescent one.
By mask illumination or laser writing, activated patterns can be printed onto the foil with a resolution that is comparable to common laser printers. Similar to glow-in-the-dark stickers, the patterns can be brought to shine and the imprinted information can be read. By illuminating with infrared light, the tag is erased completely and new data can be written into it.
The working principle of these programmable transparent tags is based on the well-known oxygen molecule. Oxygen is present in the plastic foil and steals the light energy from the glowing molecules. Ultraviolet radiation induces a chemical reaction that efficiently removes the oxygen from the layer. In consequence, the luminescent molecules are activated and are able to emit light. The deactivation process using infrared light is based on a temperature rise of the foil, leading to an increased oxygen permeability and therefore a refilling of the layer with oxygen.
These novel tags can be manufactured in any size. The low material costs per square meter promise a wide range of possible applications. Information such as barcodes, serial numbers, or addresses can be hidden for on-demand readout only. Also, these invisible tags could enhance document security and anti-counterfeiting.
For more information, contact Prof. Dr. Sebastian Reineke in the Institute of Applied Physics at