GLASS4FLEX – pioneering new process technologies for flexible glass in optical systems
Ultra-thin glass – one human hair thick – is ideally suited as a material for mass production of optical components and parts as well as for encapsulating optical and optoelectronic systems. Its production requires a completely coordinated process chain – from manufacture to functionalisation. This is the goal to be accomplished by 2022 in the GLASS4FLEX joint research project.
Ultra-thin glass is often called the new miracle material for a wide variety of applications in optics, biotechnology, and the semiconductor industries. At less than 0.2mm “thick”, it appears to be as thin as polymer film yet has outstanding surface properties compared to plastic and metal films, such as particularly high smoothness, scratch-resistance and transparency. This makes the material particularly desirable for smart-touch surfaces and displays in consumer electronics and the automotive sector. Mass production of optical components requires materials that can serve as the basis substrate for the individual components. In addition, these kinds of sensitive optical systems must be able to be encapsulated to protect them from environmental influences. That makes ultra-thin glass well suitable for these purposes. But the trend towards ever thinner, more flexible and powerful yet lighter electronic devices and automobiles of the future is increasingly leading now to a shift in the glass thicknesses sold in mass volumes to even considerably below 0.2mm.
Although it is currently feasible to manufacture glass in a thickness range of below 0.1mm – which will be important in the future – it is not always possible to achieve the required specifications, however. The challenge in using such thin glass also lies in the entire process chain for its subsequent processing. In addition to the actual glass production, the cleaning and handling as well as the detection of defects in the glass are of great importance for its employability. There is currently no processing plant technology available at all that can be converted for implementing these process steps.
This is where the BMBF-funded GLASS4FLEX joint research project comes in, launched 1 April 2019. The joint project intends to develop new process technologies that do not exist yet as the pioneers for flexible glass applications in next-generation optical systems, and to establish them for developers of such optical systems.
SCHOTT AG, developer and manufacturer of ultra-thin glass, stands at the core of the consortium. The project's participants span the entire process chain – starting with the SCHMID Group, which will be involved with the development of cleaning processes and the associated process technology for thin glass using in-line cleaning systems. The imaging and signal-processing firm Gesellschaft für Bild- und Signalverarbeitung GBS mbH will then take over the R&D for the analysis of the surface properties including the measurement system engineering.
The project addresses the handling of flexible individual large-area thin glass with a maximum size of 1.2m × 0.6m, where solving handling problems will be one of the greatest challenges in the project. The partners ProTec Carrier Systems GmbH and Adenso Industrial Services GmbH meet the challenge. The former – a specialist in developing secure mounting systems – will develop these for the thin glass fixation during the vacuum coating process. Adenso Industrial Services GmbH is engaged in transfer technologies for thin glass before and after vacuum coating. As part of the GLASS4FLEX project, the Fraunhofer Institute for Organic Electronics, Electron Beam and Plasma Technology FEP, in Dresden, Germany, will conduct research on functional optical and electrical coatings for this thin glass in sheet-to-sheet processes based on its state-of-the-art expertise.
Project coordinator Dr Manuela Junghähnel from Fraunhofer FEP explains the goals and approach: “We want to work hand-in-hand with all six project partners to develop new process technologies for the production of high-strength thin glass that can withstand full mechanical stress despite its low thickness. The development of safe cleaning and defect inspection for these types of glass is integral to this, as are the mounting system and functional coating.”
The results are expected to be presented in Dresden by 2022: the first coated large-area thin glass with colour-neutral scratch protection and a transparent electrode, made with a fully developed process chain. In addition, the other main objective is to establish a pre-commercial infrastructure in Dresden that will enable system manufacturers from all the areas mentioned to develop prototype optical components on the basis of coated ultra-thin glass.
The project’s R&D intends to reduce the thickness of current glass-based systems for better mechanical properties without reducing protective effects. The optical elements and the processes required for their manufacture should be suitable for as many applications as possible, especially in the fields of mechanical and plant engineering, electronics, lighting, medical engineering, environmental analysis, and vehicle construction.
The Fraunhofer FEP has been conducting research in coating technologies for ultra-thin glass for several years. Outstanding results have already been achieved in the development of roll-to-roll technologies for depositing inorganic materials on flexible glass. The Institute's unique expertise in research and development for flexible glass will be supplemented by the project.
GLASS4FLEX project partners: SCHOTT AG (Grünenplan, Germany), Schmid Group (Freudenstadt, Germany), Gesellschaft für Bild- und Signalverarbeitung GBS mbH (Ilmenau, Germany), Adenso Industrial Services GmbH (Dresden, Germany), ProTec Carrier Systems GmbH (Siegen, Germany), Fraunhofer FEP (Dresden, Germany).
Caption: Thin glass is a versatile material with many applications (photo: Fraunhofer FEP)