As the world moves rapidly towards electrification in transportation, electric vehicle (EV) battery manufacturers are under immense pressure to boost productivity and enhance product quality, performance, and safety. These challenges require advanced quality control (QC) and quality assurance (QA) processes for raw materials, components during production, and finished battery products. To address these needs, Agilent Technologies offers a suite of cutting-edge analytical instruments, including the Agilent Cary 630 FTIR and Cary 3500 UV-Vis spectrometers.
Variability in material quality and production consistency poses challenges for battery manufacturers. Ensuring proper electrolyte composition and separator integrity requires rigorous testing to detect issues early. FTIR and UV-Vis spectrometers provide immediate impurity detection, reducing defects and keeping production on track.
The Cary 630 FTIR and Cary 3500 UV-Vis spectrometers offer a comprehensive solution for battery manufacturers and researchers. These instruments enable quick, detailed analyses, uncovering material differences that affect battery performance and safety. They help manufacturers maintain quality standards in high-throughput settings and give researchers the critical data needed to develop next-generation battery materials.
Access the application notes below for improved battery analysis:
Improving Battery Production Yield, Performance, and Stability Using FTIR
The ability to rapidly assess the quality and identity of complex salts used for battery electrolytes makes the Cary 630 FTIR a valuable tool in battery manufacturing QC settings and research and development laboratories.
Material Identification of Lithium-Ion Battery Separators Using FTIR Spectroscopy
Rapid analysis of new and used battery separators using the Agilent Cary 630 FTIR spectrometer presents an effective solution for QC testing in lithium-ion battery manufacturing and is suitable for R&D in battery material development and improvement.
Quick and Easy Material Identification of Salts Used in Lithium-Ion Batteries by FTIR
This application note discusses how the Agilent Cary 630 FTIR spectrometer enables safe, efficient identification of lithium-ion battery salts in a glove box. Its easy-to-use software allows for quick and accurate analysis with minimal training.
Quick and Easy Material Identification of Solvents Used in Lithium-Ion Batteries by FTIR
Read how the Agilent Cary 630 FTIR spectrometer, with MicroLab software, simplifies identifying lithium-ion battery electrolyte solvents. In this study, the Cary 630 FTIR was used to FTIR identify four samples, flagging one for further investigation.
Advancing Research of Lithium-Ion Batteries Using the Agilent Cary 630 FTIR Spectrometer
Demand for lithium-ion batteries is rising due to carbon emission policies. Researchers aim to enhance battery capacity, reduce charging times, and find safer materials. Read how the Agilent Cary 630 FTIR aids battery researchers around the world in achieving their goals.
Applications of FTIR Throughout the Lithium-Ion Battery Life Cycle
This application note discusses how the Agilent 4300 handheld FTIR spectrometer offers fast, non-destructive testing of inorganic materials, enhancing lithium-ion battery design and production. It’s portable and user-friendly, saving time and money in battery material analysis.
Plus access the video...
Lithium-ion Battery Electrolyte Component Analysis
Fast and accurate lithium-ion battery electrolyte component identification is crucial for performance, safety, and stability. Watch this video to see how the Cary 630 FTIR reliably identifies materials and performs hazardous analyses in a controlled environment.
Sponsor:
