The mission put forward by SOLiDIFY project was to develop next generation safe and high performing, cost-effective and environmentally sustainable battery prototypes by novel materials and up-scalable manufacturing process. Several research projects and industries have developed high performing soli-state batteries targeting energy densities of 800-1000 Wh/L, with key advancements focussing on utilizing solid electrolytes such as sulfide, oxide and polymer-based materials to prevent the dendrite formation against Li anode, improve cycling stability against high-voltage cathodes, and enhanced safety by replacing flammable liquid electrolytes. The state-of-the-art lithium-ion batteries could deliver energy density of maximum 800 Wh/L, whereas the unique materials and upscalable-processing technologies aimed to push the boundaries of solid-state lithium metal batteries demonstrating higher energy density up to 1070 Wh/L, a gravimetric energy density of 352 Wh/kg, long-term cyclability, higher intrinsic safety, and a cell cost of 130 €/kWh. These numbers were achieved with 0,1Ah pouch cells.
The consortium adopted low-cobalt content active materials, which significantly enhanced the sustainability of the prototypes by reducing dependency on critical raw materials, facilitating easier recycling, and lowering environmental impacts associated with cobalt mining. The reduced cobalt content minimised the toxic waste generation and led to a more environmentally friendly life cycle for solid-state batteries. In parallel, SOLiDIFY developments were conducted with full Life Cycle Analysis to ensure that a positive environmental impact was achieved with the developed technologies and processed materials. In addition to the assessment, a recycling scenario for the SOLiDIFY cell was proposed to recover the electrode and electrolyte materials used within the project.
The new methodologies and characteristic techniques developed for solid-state-lithium metal batteries as part of the project contributed to strengthening the expertise of the partners, enhancing longer-term capabilities and thus fuelling the EU modelling ecosystem. Advanced materials and pouch cell assembly processes were developed and (some) protected as patent applications to strengthen the patent portfolio of the partners and their position in the market. Such advancements were identified as key exploitable results (KER), which were reviewed and consolidated into 20 KERs. The SOLiDIFY projects’ vision was to contribute to the European society by strengthening the European battery value chain through the development of a competitive and sustainable battery cell in Europe. In addition, the project aimed to enable the development, in Europe, of a gender-diverse, highly qualified work force skilled in the latest battery materials and technologies.