1,4-Di-tert-butyl-2,5-dimethoxybenzene: A Versatile Aromatic Hydrocarbon for Organic Synthesis and Battery Applications
Explore the properties and applications of this key aromatic compound, crucial for advanced synthesis and energy storage solutions.
Get a Quote & SampleProduct Core Value
Di-tert-butyl-dimethoxybenzene
This aromatic hydrocarbon compound, identified by CAS 7323-63-9, is a versatile chemical with significant utility in both organic synthesis and cutting-edge battery technology. Its unique structure and properties make it an invaluable component for researchers and developers.
- As an organic reagent for synthesis, it provides a stable and reactive platform for various chemical transformations, contributing to the development of new compounds.
- The compound serves as a benchmark redox shuttle for lithium ion battery systems, offering a proven solution for enhancing battery performance and safety.
- Its rigid molecular structure ensures exceptional electrochemical reversibility and stability, which are critical for high-performance energy storage devices.
- It is recognized for its role in high-rate overcharge protection, a vital feature for the safe and efficient operation of LiFePO4 cathode materials in lithium-ion batteries.
Advantages Offered by the Product
Enhanced Electrochemical Performance
Its outstanding electrochemical reversibility and stability contribute significantly to the performance and longevity of lithium-ion batteries, making it a key component for battery overcharge protection.
Versatility in Organic Synthesis
As a valuable organic reagent for synthesis, this compound facilitates complex chemical reactions, enabling the creation of novel materials and fine chemicals.
Reliable Overcharge Protection
The compound's proven effectiveness in providing high-rate overcharge protection for LiFePO4 cathode materials enhances the safety and operational parameters of advanced battery technologies.
Key Applications
Organic Synthesis
This compound is extensively used as an organic reagent for synthesis, enabling a wide array of chemical reactions and the creation of complex molecules.
Lithium-Ion Batteries
It functions as a critical redox shuttle additive for lithium ion battery systems, improving safety and performance, particularly in high-rate overcharge protection scenarios.
Material Science Research
Its unique properties make it a subject of interest in advanced chemical building blocks research, exploring its potential in novel material development.
Electrochemical Studies
Researchers utilize it for its notable electrochemical reversibility and stability, crucial for understanding and improving energy storage mechanisms in battery components.
Related Technical Articles & Resources
Why Choose Us?
Leverage our expertise and state-of-the-art infrastructure to accelerate your journey from discovery to commercial success.
Global Experience
With 20 years of R&D, manufacturing, and sales experience, we proudly serve clients across 60 countries and regions worldwide.
Advanced Facilities
Our in-house R&D laboratory, pilot platform, and large-scale production workshop are equipped to meet the audit requirements of global customers.
Seamless Scalability
We facilitate a perfect transition from small-scale lab requirements (grams) to full commercialization (hundreds of tons).