This inherent identity code is virtually impossible to modify and can be easily read using a low-cost portable laser scanner, according to research carried out at Imperial College London and Durham University, and published in Nature today.
Researchers believe the technology could also prove valuable in the fight against terrorism through the ability to secure passports, ID cards and 'breeder' documents such as birth certificates used to obtain genuine passports.
All non-reflective surfaces have naturally occurring roughness that is a source of physical randomness. This could provide in-built security for a range of objects such as passports, ID and credit cards and pharmaceutical packaging, replacing more costly measures such as holograms or security inks. Lead author Russell Cowburn, Professor of Nanotechnology in the Department of Physics, Imperial College London, says:
"Our findings open the way to a new and much simpler approach to authentication and tracking. This is a system so secure that not even the inventors would be able to crack it since there is no known manufacturing process for copying surface imperfections at the necessary level of precision."
Using the optical phenomenon of 'laser speckle', researchers examined the fine structure of different surfaces using a focused laser, and recorded the intensity of the reflection. The technique was tried on a variety of materials including matt-finish plastic cards, identity cards and coated paperboard packaging and resulted in clear recognition between the samples. This continued even after they were subjected to rough handling including submersion in water, scorching, scrubbing with an abrasive cleaning pad and being scribbled on with thick black marker.
Professor Cowburn adds: "The beauty of this system is that there is no need to modify the item being protected in any way with tags, chips or inks - it's as if documents and packaging have their own unique DNA. This makes protection covert, low-cost, simple to integrate into the manufacturing process and immune to attacks against the security feature itself."
Professor Cowburn and his colleagues are now working with the spin-out company Ingenia Technology to take this product to market.
Notes to editors:
'Fingerprinting' documents and packaging, Nature 28 July 2005, Vol 436
James Buchanan 1, Russell Cowburn 1, Ana-Vanessa Jausovec 1, Dorothee Petit 1, Peter Seem 1, Gang Xiong 1, Del Atkinson 2, Kate Fenton 2, Dan Allwood 3, Matthew Bryan 3.
1. Imperial College London
2. Durham University
3. University of Sheffield
More information about Professor Russell Cowburn is at www.imperial.ac.uk/people/r.cowburn
More information on Ingenia Technology is at www.ingeniatechnology.com/
About Imperial College London
Consistently rated in the top three UK university institutions, Imperial College London is a world leading science-based university whose reputation for excellence in teaching and research attracts students (10,000) and staff (5,000) of the highest international quality. Innovative research at the College explores the interface between science, medicine, engineering and management and delivers practical solutions that enhance the quality of life and the environment - underpinned by a dynamic enterprise culture. Website: www.imperial.ac.uk