Paper detail

A Route to High-Toughness Battery Electrodes

There is increasing interest in materials that combine energy-storing functions with augmented mechanical properties, ranging from flexibility in bending to stretchability to structural properties. In the case of lithium-ion batteries, these mechanical functions could enable their integration in emerging technologies such as wearable, free-form electronics and ultimately as structural elements, for example, in transport applications. This work presents a method to produce flexible LiFePO4 LFP electrodes with an extraordinary combination of electrochemical and mechanical performance. Such electrodes exhibit an exceptionally high specific toughness, combined with superior rate capability and energy density, with respect to reference electrodes with typical metallic current collectors. These properties are a result of the strong adhesion of the active material particles to the high surface area carbon nanotube fiber fabric, used as a lightweight, tough, and highly conducting current collector. This strong adherence minimizes electrical resistance, mitigates interfacial failure, and increases ductility through heterogeneous strain after cohesive failure of the inorganic phase. As a result, these electrodes can withstand large deformations before fracture, and, even after fracture, they retain excellent electrochemical performance, approximately double that of unstretched, Al-supported LFP electrodes with equivalent loading.