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Report

Teaser, summary, work performed and final results

Periodic Reporting for period 1 - SUN-PILOT (Subwavelength Nanostructure Pilot (Sun-Pilot))

Teaser

Summary

The SUN-PILOT Project

The aim of SUN-PILOT is to develop a novel and cost-effective platform for up-scaling the fabrication of sub-wavelength nanostructures across large and non-planar surfaces. This will be achieved using state-of-the-art block copolymer chemistry and highly scaleable etching and injection moulding methods. Specific outcomes will include the demonstration of a clean and sustainable nano-patterning technology capable of reducing the maintenance and capital investment costs for optical component users whilst enhancing the lifetime of anti-reflection parts.

Context

Nanostructured surfaces that engineer the interaction between an object and its surroundings are a subject of scientific and manufacturing importance. Nature routinely creates nanostructured surfaces with fascinating properties, such as antireflective moth eyes, self-cleaning lotus leaves, colourful butterfly wings, and water harvesting desert beetles. Well-defined nanostructured surfaces have huge commercial potential due to product enhancement: reduced reflectivity in photonic devices and solar panels, antiglare plastic parts for the automotive industry, hydrophobic self-cleaning surfaces for smart packaging, antireflective and smudge-free smartphone displays, and biofouling resistant marine and water treatment systems. Unfortunately, the lack of cost-effective, scalable, nanopatterning methods is a major hurdle for the commercial exploitation of nanopatterned surfaces.

Objectives and Impact

SUN-PILOT will address this challenge by developing a novel and cost effective platform for up-scaling sub-wavelength nanostructures fabrication techniques that can be applied to curved surfaces such as optical lenses, and the mass production of metal moulds for injection moulding of plastic parts.
This project brings together scientists and engineers to span innovation, business development and the product cycle from suppliers to end users. Achieving the objectives will ensure a leadership role for Europe in the production of nanostructured surfaces.

Methodology

The SUN-PILOT consortium will develop a pilot production process capable of creating a tailored nanopattern on a surface. The process has two key stages; a masking step using block copolymers that self-assemble into a defined pattern, and an etching step to transfer that pattern into the substrate below. The project will first apply this process on optical glasses, and to metals suitable for injection mould inserts. Also included in the work programme are activities on design and production of tailored block copolymers and polymer additives, and on demonstration of injection moulded parts for the automotive industry.

Work performed

In the first period of the project, the teamâ€™s focus has been on establishing a high quality, scalable source for some of the key polymers used in the nanostructuring process. These have been designed on principles of sustainability and security, considering availability, lifecycle costs and impact relative to equivalent materials on the market today. University of Bordeaux (Laboratoire de Chimie des PolymÃ¨res Organiques) and Fraunhofer Institute for Applied Polymer Research have worked together to design a new process for making high molecular weight block copolymer systems, while Micro Resist Technology GmbH have developed new additives for easy peel injection moulding.

In parallel, Trinity College Dublin, AMO GmbH have begun process development and optimisation for fabrication of glass with antireflective surfaces, and metals with surfaces that reduce glare, repel water and dirt, or reflect certain colours. Our activity has been steered by our set of end users in the optics and automotive industries, and our production and process experts IPO and Tecnalia. The first samples of AR glass have been produced and shared within the consortium for evaluation.

Final results

The expected impact of SUN-PILOT for the optics Industry is a disruptive surface patterning technology that will boost the performance/cost ratio of photonic devices, as pilot production demonstrates mass fabrication of scratch and wear-resistant antireflective optical surfaces. Significant enhancement will be achieved in the efficiency of optical components and systems incorporating these devices, such as laser systems, electronic displays, security cameras and medical devices.

The automotive industry will benefit from a novel method to produce functional surfaces at lower cost and lighter weight than existing lamination methods.
In both industries, the replacement of coatings and lamination with surface modification will have real environmental benefit, eliminating the need for several intensive processes and harmful chemicals in production, and making parts easier and cleaner to reuse and recycle.

The new pilot production capacities â€“ polymer synthesis, surface treatment and etching, and injection moulding, will be made accessible to other projects and teams developing similar technologies.