In battery manufacturing, quality starts with the slurry. For QA/QC professionals, ensuring the consistency and performance of electrode slurries is not just a checkpoint — it’s a quality control imperative. Slurry quality directly impacts electrode uniformity, adhesion, and ultimately, battery performance and lifespan.
DetailsAs lithium-ion battery technology evolves, reducing production costs has become a top priority for manufacturers and researchers alike. Lower costs not only make batteries more accessible for consumer electronics and electric vehicles but also enhance the viability of renewable energy storage solutions like solar and wind.
DetailsBattery slurry formulation and testing is a complex challenge that sits at the heart of lithium-ion battery performance. From slurry mixing to electrode coating, understanding the flow and structural behavior of slurries is critical. For battery scientists seeking precise, reliable characterization tools, rheometers are indispensable. TA Instruments offers two powerful solutions tailored to battery slurry research: the Discovery Core Rheometer and the Discovery Hybrid Rheometer.
DetailsWill your paint stick to the wall or drip off? Does your low-fat cream cheese have the same texture as a full-fat version? How will new ingredients affect your formulation’s texture and application, especially as environmental conditions change? Rheology offers invaluable insights that help researchers, developers, and engineers across numerous industries optimize their products for performance and customer satisfaction.
DetailsIn battery development, precise rheological measurements are critical for optimizing material performance, ensuring uniform coatings, and enhancing conductivity. Whether working with cathode, anode, or electrolyte materials, selecting the right rheometer is essential. TA Instruments offers two industry-leading solutions: the Discovery Core Rheometer and the Discovery Hybrid Rheometer. This guide helps battery scientists determine which instrument best suits their needs.
DetailsIn the world of material science, understanding the viscoelastic properties of materials is crucial for developing and optimizing products. Two key parameters in this context are storage modulus (E’ or G’) and loss modulus (E” or G”). These parameters provide insights into a material’s stiffness and damping characteristics, respectively, which are essential for applications ranging from polymers and pharmaceuticals to batteries and composites.
DetailsElectrode slurries are paste-like mixtures made up of active materials, conductive additives, and a binder. The conductive additives must be electrically conducted to the current collector. However, binder is necessary for getting the active materials to stick together and adhere to the current collector.
DetailsIsothermal Microcalorimetry (IMC) is a highly sensitive analytical technique that measures the heat flow in chemical and physical processes under constant temperature. IMC enables the precise detection of thermal reactions, including phase transitions, binding events, and metabolic processes, making it invaluable in fields such as pharmaceuticals, materials science, and battery research.
DetailsPowders are a big part of everyday life, from baking and laundry to cosmetics and pharmaceuticals. Understanding powder rheology—how powders flow and deform—is crucial for optimizing their use in various applications. This knowledge helps industries maintain consistency and product quality.
DetailsRheology is a notoriously complex field, combining mathematics and physics to characterize materials. For inexperienced users, rheology can seem like a massive challenge. Luckily, new technology simplifies rheology down to its core so you can get essential measurements without difficult training, measurements, or calculations.
DetailsLithium-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.
DetailsFrom 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.
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