Direct Writing Unclonable Watermarks with an Electrochemical Jet

Counterfeit parts result in significant losses per annum and are often dangerous, therefore they represent a serious concern for manufacturers and end users alike. Easily written but unclonable watermarks undermine the proposition of the counterfeiter. Here, a rapid electrochemical jet engraving routine is presented to encode robust materials with self-organized dendritic structures at length scales that can be imaged with a smartphone. Surface defects act as stochastically distributed seeds from which discrete pitting events can be propagated by translating the electrochemical field. While the vascular pathways can be directly written at the macro scale, the formation and propagation of microscale dendritic arms is chaotic, caused by the implicit randomness of the defect seeds and the supply of ions to the surface. The latter is confounded by random perturbations in the flow condition. Each engraved dendrite is unique, stable at high temperature (>500 degrees C) and can be subjected to rapid image recognition to allow individual mark identification at any point during part production and delivery, or through part lifetime.

Automated summary

Counterfeit parts are a serious concern for manufacturers and end users, and preventing counterfeiting is of great importance. This article presents a rapid electrochemical jet engraving routine for encoding materials at lengths that can be imaged with a smartphone, in order to prevent counterfeiting. The encoded structures are stable and can withstand high temperatures, and individual identification can be achieved through rapid image recognition.