Researchers at the Singapore University of Technology and Design (SUTD) are constantly coming up with new discoveries and 3D printing applications, from 3D printed light shows to biocompatible hydrodgels. Now scientists at SUTD have used 3D printing to develop something that not only looks really cool, but can also be used to deter counterfeiting.
The device, which the scientists call “holographic color prints,” creates images that appear as a regular color print under white light. Under red, green or blue laser illumination, the device projects up to three different holograms. It is capable of modulating both the phase and the amplitude of light. The research is documented in a paper entitled “Holographic colour prints for enhanced optical security by combined phase and amplitude control.”
Conventional optical security devices provide authentication by manipulating a specific property of light to produce a distinctive optical signature. Microscopic color prints modulate the amplitude and holograms modulate the phase of light, but the researchers believe that this structure can be easily imitated. So they designed a pixel that overlays a structural color element onto a phase plate to control both the phase and amplitude of light. They then arrayed the pixels into monolithic prints, with each pixel strategically arranged on a plane. Nanostructured posts with different heights were used as structural colored filters to modulate the amplitude of light.
The researchers also created an algorithm that takes multiple images as its input and generates an output file to determine the positions of different phase and colored filter elements. They then used a nanoscale 3D printer to create a holoscopic print of painter Luigi Russolo’s 1910 painting “Perfume.” The color print is visible under ambient white light. Different thicknesses of polymerized cuboid were used to modulate the phase plates and form three multiplexed holograms, projected as a red thumbprint, a green key, and blue letters that read “SECURITY.” The images were embedded within the print.
The holographic color prints can be easily verified, according to the researchers, but are difficult to imitate.
“The relationship of holograms in combating counterfeiting is analogous to antibiotics against infections,” said professor Joel Yang. “Every so often, new technology is needed to deter counterfeiters as the old-fashioned holograms become easier to copy.”
The prints consist of nano 3D printed polymer structures and can be used in optical document security. Information in the prints is encoded only in the surface relief of a single polymeric material, so nanoscale 3D printing could then be used to mass manufacture customized masters by nanoimprint lithography.
“For the first time, multiple holograms that are color selective are ‘woven’ into a colorful image using advanced nanofabrication techniques,” Yang said. “We are hopeful that these new holographic color prints are user friendly but counterfeiter unfriendly: They are readily verified but challenging to copy, and can provide enhanced security in anticounterfeiting applications.”
Authors of the paper include Kevin T.P. Lim, Hailong Liu, Yejing Liu and Joel K.W. Yang.
Discuss this and other 3D printing topics at 3DPrintBoard.com or share your thoughts below.[Source: Photonics.com]
You May Also Like
A Guide to Bioprinting: Understanding a Booming Industry
The success of bioprinting could become the key enabler that personalized medicine, tissue engineering, and regenerative medicine need to become a part of medical arsenals. Breakthroughs in bioprinting will enable...
Cell Culture Bioreactor for Tissue Engineering
Researchers from the US and Portugal are refining tissue engineering applications further, releasing the findings of their study in the recently published ‘A Multimodal Stimulation Cell Culture Bioreactor for Tissue...
3D Printing for Nerve Regeneration: Gelatin Methacrylate-Based Nerve Guidance Conduits
Chinese researchers delve deeply into tissue engineering, releasing the findings of their recent study in ‘3D printing of gelatin methacrylate-based nerve guidance conduits with multiple channels.’ While there have been...
China: Bioprinting Polycaprolactone/Silk Fibroin Scaffolds to Improve Meniscus Regeneration
Researchers from China are hoping to improve medical outcomes for patients dealing with knee joint issues. Their recent study, ‘Biomechanically, structurally and functionally meticulously tailored polycaprolactone/silk fibroin scaffold for meniscus...
View our broad assortment of in house and third party products.