1-Allyl-3-vinylimidazolium dicyanamide stands out in the family of ionic liquids, bridging chemistry and industry through the pairing of 1-allyl-3-vinylimidazolium cation and dicyanamide anion. In labs and factories, this substance builds a reputation for unique solubility and flexibility, making researchers and industrial engineers pay closer attention. Transparent details matter, so here's the substance down to the essentials: one molecule carries a formula of C10H11N5, a molecular weight of roughly 201.23 g/mol, and the structure closely aligns with other imidazolium-based salts recognized for their practical value.
This chemical doesn’t rely on a single form. You may spot it as white to off-white flakes, fine powder, or even solid crystals, each with slight differences in handling and application. Density hovers near 1.16 g/cm³ at room temperature, with solid-state stability that supports safe shipping, blending, and storage. Some suppliers offer the product as larger pearls or fine-grained bulk material. Users may see requests for custom forms—powder for use in catalysis, crystals for fuel cell prototypes, or even solutions tailored for research. If anyone has worked with ionic liquids in the field, the consistency and handling of this compound deliver predictable, reproducible results, which really matters in scaled-up processes.
Its imidazolium backbone brings impressive stability even under changing thermal or pressure conditions. The dicyanamide anion offers a distinct set of reactivity, especially when mixing with other solvents or in ion-exchange columns. 1-allyl-3-vinylimidazolium dicyanamide has a melting point often above 100°C, which helps in processes where higher temperatures are common. The combination of allyl and vinyl groups gives rise to polymerization or crosslinking capabilities not often found in simpler ionic liquids. These features let chemists develop new catalysts, electrochemical devices, or separation membranes.
This material finds use in electrochemistry, catalysis, advanced materials, and even batteries. In the lab, chemists rely on its stability to fine-tune reaction conditions for organic synthesis. Advanced material scientists count on the vinyl group as a handle for chemical modification or crosslinking, directly contributing to the development of membranes and ion-conductive polymers. In recent years, battery developers have explored using this ionic liquid as a component of safer, high-durability electrolytes. Dicyanamide-based ionic liquids stand out in energy storage for their low volatility, which matches the ongoing demand by companies looking for safer raw materials and longer-lasting devices.
Like many specialty chemicals, 1-allyl-3-vinylimidazolium dicyanamide does introduce some safety considerations. Exposure to skin or eyes may cause irritation; inhalation of fine powder creates a risk for sensitive individuals. Industry safety data sheets highlight standard practice: use gloves, eye protection, local ventilation, and avoid prolonged skin contact. Current research suggests that the compound is neither highly toxic nor acutely hazardous under typical handling and storage, but mishandled material can contribute to health issues or environmental release. Chemists and plant managers need to understand and share safe handling guidelines—household drains and landfill disposal do not fit the bill for specialty ionic liquids, and anyone who's been on a lab clean-up crew knows why.
Raw materials for 1-allyl-3-vinylimidazolium dicyanamide typically include imidazole, allyl chloride, vinyl bromide, and sodium dicyanamide. Synthesizing these compounds often involves careful control of reaction conditions, especially to avoid unwanted byproducts or excess waste. Over the past decade, suppliers in China, Europe, and North America have expanded their production lines to keep up with demand from the chemical, energy, and research sectors. Keeping material specs tight ensures efficiency—from melting point and purity to heavy metal content and form factor. Inconsistent supply chains or quality problems impact everything downstream; R&D engineers have learned to confirm each batch before scaling up any process.
Global trade depends on clarity, so most companies ship 1-allyl-3-vinylimidazolium dicyanamide under HS Code 2925299090. At the import/export level, customs and compliance teams track this designation to keep shipments clear and legal. Certificates of analysis usually detail more than just appearance and melting point; specifications extend to water content (often below 0.2% by weight), minimum purity (at least 98%, ideally >99% for electronics), and storage recommendations (sealed, away from light and heat, in dry conditions).
Working in research labs and small production groups, chemists grow to appreciate how the right material can transform a process or launch a product line. Properties like density, melting point, and chemical stability translate into productivity—whether you're developing a new water treatment membrane or simulating battery electrolytes in a university lab. Sourcing safe, high-purity 1-allyl-3-vinylimidazolium dicyanamide means responsible environmental practice and higher yields, avoiding setbacks that cost time and money. Over time, the feedback from scientists and operators improves both the product itself and the training that comes with it, and that’s where progress really takes root.
