Lithium-ion batteries (LIB) are manufactured through a multistep process combining various active and inactive materials. Material selection and processing conditions can greatly affect the final battery performance.
From lightweight laptops to cross-country EV driving, countless applications require increasing lithium-ion batteries’ energy density and performance. Since battery electrodes directly contribute to these aspects of battery function, electrodes and their components are of particular interest to battery researchers seeking to advance technology to the next level. Battery slurry processing is also a key step of manufacturing, offering significant opportunities to increase efficiency while reducing cost.
The world is driven by battery power, and the various battery testing laboratory applications help to ensure that we get the most out of them.
Over the past decade, battery research, development, and quality control have adopted in-situ and in-operando isothermal microcalorimetry (IMC) as the leading method to evaluate heat flow during lithium-ion battery cycling. While cycling a cell to failure can take many months, emerging diagnostic tests are able to predict long-term behavior in a matter of weeks.
Whether you’ve used a cell phone or driven an electric vehicle (please, not at the same time), you’ve probably come to realize that lithium-ion batteries are taking over the energy world. They power our portable electronics, vital medical equipment, electric vehicles, and renewable energy storage. As the market expands, researchers are finding ways to make Li-ion batteries increasingly powerful, dependable, and safe, all while minimizing production time and cost.