Perovskite solar cells (PSC) have shown an impressive learning curve in the last decades in comparison with 1st, 2nd and initial 3rd generation solar cells (such as DSSC and OPV). Since the very beginning, the main market demands for 3rd generation PV were more flexibility and more colour choices. Both of these ideal properties lead to new business opportunities in BIPV, electronic consumer goods, textiles, etc. These technologies also have low cost using fully printing process, low temperature processes and out of clean rooms which reduce the production cost.
The most important problem in PSC technology is the short lifetime which is currently the main barrier for the marketability of PSC. Up to now all the developed PSC used cheap materials and/or solution which did not exhibit high efficiencies. In contrast high efficiency PSCs usually require relatively expensive materials and vacuum deposition process.
PSC toxicity is considered to be negligible since the amount of lead in perovskite layer is not so relevant if it is compared against Si technology, nevertheless, the solvent toxicity should be taken in account in order to benefit industrialization of PSC products.
APOLO consortium will surpass the aforementioned barriers for market deployment by providing flexible and stable PSCs using scalable and low cost processes, reducing amount of toxic materials tackle the challenges to provide market niches solutions. APOLO developments will ensure to enhance the TRL of PSC technology. APOLO consortium will work on advanced materials, from cell to encapsulant to develop flexible PSC, fully printable, with efficiency of 22% with at least 80% of initial performance after relevant accelerated test from standards.
APOLO solutions will allow the development of a totally new product by integrating the modules into the architecture design of buildings. New applications of this technology open doors to other markets apart from BIPV, such as automotive, textile, etc.
Project Budget: 4’997’191,25€
LEITAT Budget: 720’088,75 €
Financial Framework: Horizon 2020
Contract number: 763989
Start Date: 01/04/2018
End Date: 31/03/2022
This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No 763989. This publication reflects only the author’s views and the European Union is not liable for any use that may be made of the information contained therein.