Project Title | INSPIRED |
Year Start | 2014 |
Year End | 2018 |
Consortium members | JOANNEUM RESEARCH FORSCHUNGSGESELLSCHAFT MBH NANOTECCENTER WEIZ FORSCHUNGSGESELLSCHAFT MBH NANOGAP SUB-NM-POWDER SA INTRINSIQ MATERIALS LIMITED M-SOLV LTD THOMAS SWAN & CO LIMITED BIONANONET FORSCHUNGSGESELLSCHAFT MBH TOUCHNETIX LIMITED NEXCIS EUROLCDS SIA NANOTECHNOLOGY INDUSTRIES ASSOCIATION ALMA MATER STUDIORUM – UNIVERSITA DI BOLOGNA FUNDACION TECNALIA RESEARCH & INNOVATION UNIVERSIDAD DE SANTIAGO DE COMPOSTELA MIDSUMMER AB |
Description | Printed electronics (PE) is set to revolutionise the electronics industry over the next decade and can offer Europe the opportunity to regain lost market share. Printed electronics allows for the direct printing of a range of functional (conductive, resistive, capacitive and semi-conducting) nanomaterials formulations to enable a simpler, more cost-effective, high performance and high volume processing in comparison to traditional printed circuit board and semiconductor manufacturing techniques. It has been reported by Frost and Sullivan that the market for printed electronics will increase in revenues from $0.53Bn in 2010 to $5.04 Bn in 2016 at a compound annual growth rate of 32.5%. However, the migration towards low-cost, liquid-based, high resolution deposition and patterning using high throughput techniques, such as inkjet printing, requires that suitable functional nanomaterials formulations (e.g. inks) are available for end users in industrially relevant quantities. Presently, there are issues with industrial supply of nanomaterials which are low cost, high performance, environmentally friendly and tailored for high throughput systems. Therefore better collaboration is warranted between supply chain partners to ensure nanomaterial production and nanomaterial formulations are tailored for end use applications to meet this need. The INSPIRED project will address these fundamental issues within the printed electronics industry: Ensuring that suitable functional nanomaterials formulations (inks) are available for end users in industrial scale quantities. Production of these nanomaterial formulations on an industrial scale and then depositing them using cost-effective, high throughput printing technologies enables rapid production of printed electronic components, on a wide variety of substrates. Therefore, enabling new electronics applications, whilst overcoming the problems associated with traditional manufacturing. |
Core Technology | Conductive Nanomaterials |
Industry of application | Conductive materials |
Call | H2020 |
Funding info | This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No 646155 |