In the field of new energy batteries, the performance of anode materials directly impacts battery endurance, safety, and cycle life. Shaanxi Wuke Jinsi New Materials Co., Ltd., a high-tech enterprise specializing in the research, development, and manufacturing of silicon-carbon composite anode materials for lithium-ion batteries, places great emphasis on product quality control and performance characterization. Recently, the company introduced the Syens high-frequency infrared carbon-sulfur analyzer from Sichuan Syens Instruments to achieve high-precision detection of carbon and sulfur content in silicon-carbon composite materials.
Carbon content is one of the core indicators of silicon-carbon composite anode materials, as it affects not only the material’s conductivity and structural stability but also the overall electrochemical performance of the battery. Accurate measurement of carbon content helps analyze the relationship between material structure and functionality, while also providing critical support for evaluating process consistency, optimizing manufacturing techniques, and establishing a quantitative relationship between product performance metrics and electrochemical performance.
The Syens high-frequency infrared carbon-sulfur analyzer employs the principle of high-frequency induction furnace combustion and infrared absorption detection, offering significant advantages such as fast detection speed, high accuracy, and excellent repeatability. It is widely used in fields such as carbon materials, metallic materials, ceramics, and new energy materials. The instrument can be optimized based on the characteristics of user samples, meeting diverse testing requirements for different materials.
This collaboration not only reflects Shaanxi Wuke Jinsi’s strong commitment to quality management but also highlights Syens Instruments’ professional expertise in carbon-sulfur detection solutions for new energy materials. Moving forward, Syens Instruments will continue to advance carbon-sulfur analysis technology, providing robust technical support for the research, development, and industrialization of more new energy materials.
