The spectrum of our activities and services
Synthesis of advanced materials with plasma technology
The synthesis of advanced materials plays a pivotal role in various industries, including electronics, energy storage, aerospace, and healthcare. Plasma technology has emerged as a powerful tool for the fabrication and modification of materials with unique properties and enhanced performance characteristics. By employing plasma-based techniques, researchers and engineers can tailor the composition, structure, and surface properties of materials, enabling the development of innovative solutions to meet the demands of modern applications.
Plasma Enhanced Chemical Vapor Deposition (PECVD):
PECVD is a widely utilized plasma-based technique for the synthesis and deposition of thin films onto substrates. It involves the controlled introduction of precursor gases into a plasma environment, where they undergo chemical reactions and form a thin film on the substrate surface.
Plasma Sputtering:
Plasma sputtering is another widely employed technique for material synthesis. It involves bombarding a target material with high-energy ions in a plasma environment, causing atoms or clusters to be ejected from the target surface. These ejected species then condense onto a substrate, forming a thin film or coating.
Plasma Polymerization:
Plasma polymerization, also known as plasma-enhanced chemical vapor deposition (PECVD), is a versatile technique for synthesizing polymer films and coatings. It involves the deposition of polymer-like materials from gas-phase monomers in a plasma environment.
Data analysis on lithium metal battery
Accurate and comprehensive data collection is vital for effective analysis in lithium metal battery research and development. Sophisticated monitoring systems are employed to capture crucial battery parameters, including voltage, current, temperature, and impedance, during charge and discharge cycles. In addition, advanced diagnostic tools enable in-situ and operando characterization, providing real-time data on the battery's internal processes.
Modification of lithium batteries with plasma
The continual pursuit of high-performance and safer energy storage systems has led researchers to explore innovative methods for improving the characteristics of lithium batteries. One such approach is the modification of lithium batteries using plasma techniques. Plasma, a highly ionized gas, offers unique opportunities to enhance the performance, stability, and safety of lithium batteries. In recent years, significant advancements have been made in plasma modification techniques, unlocking new possibilities for optimizing lithium battery technology.
Plasma surface treatment is a key aspect of modifying lithium batteries using plasma techniques. By subjecting battery components, such as electrodes, separators, and current collectors, to plasma, it is possible to alter their surface properties and enhance battery performance.
Research and development regarding lithium metal battery
Research and development efforts in the field of lithium metal batteries are accelerating the progress towards high-performance energy storage solutions. By addressing the challenges associated with lithium metal anodes, improving battery performance, enhancing cyclability, and prioritizing safety considerations, researchers are paving the way for the commercialization and widespread adoption of lithium metal batteries. These advancements have the potential to revolutionize various sectors, including electric vehicles, renewable energy storage, and portable electronics, ushering in a new era of efficient and sustainable energy storage.
