1-Butyl-2,3-Dimethylimidazolium Dicyanamide is an ionic liquid attracting attention for its unique structure and versatile properties. This chemical contains a core imidazolium ring, with butyl and methyl groups offering tailored solubility characteristics. Its molecular formula, C11H18N6, underlines the complexities of the organic backbone fused with reactive nitrogen atoms from the dicyanamide anion. In the laboratory and in commercial applications, this compound stands out for both physical and chemical features, making it an intriguing choice among modern ionic liquids. As the push for alternative solvents and efficient raw materials continues, interest in this compound grows, especially in green chemistry sectors and advanced material development, where both purity and stability play essential roles.
On the shelf, 1-Butyl-2,3-Dimethylimidazolium Dicyanamide shows up as either a solid in powder or crystalline form, or as a colorless to pale yellow liquid, depending on ambient temperature and grade. Suppliers provide this compound as flakes, pearls, or bulk solid, and sometimes as a prepared solution with precise concentration per liter. Its solid-state density averages around 1.07 g/cm³, a figure important for engineers and chemists looking to fine-tune dosing and reactions, especially in large-scale setups. The crystal structure offers reliable repeatability, which means users benefit from predictable behavior during synthesis or separation processes. Consistency in form provides benefits in storage, weighing, and preparation, reducing error risks in sensitive research or industrial processes. These physical properties impact not just handling but also how the compound blends, dissolves, or interacts with other raw materials during various reactions.
With a structure made up of a symmetric imidazolium cation, flanked by butyl and methyl substituents, and the flexible, electron-rich dicyanamide anion, this compound demonstrates remarkable thermal and chemical stability. The molecular interactions within solutions often influence viscosity, conductivity, and miscibility—key factors in battery electrolytes and advanced polymer synthesis. In electrochemistry work, the inherent ionic mobility supports efficient ion transport, which becomes crucial in energy storage and conversion applications. The dense arrangement of polar and non-polar groups allows this material to tackle specialized separations where ordinary solvents fail. Its low volatility means less loss during temperature cycling, which can translate into safer, more efficient lab and manufacturing environments.
Each shipment of 1-Butyl-2,3-Dimethylimidazolium Dicyanamide aligns with standardized chemical specifications, focusing on purity, water content, and particle size when delivered as powder or flakes. Typical purity runs above 99%, assuring minimal contamination that could impact analytical or synthetic processes. Water content impacts reactivity, so most vendors limit this to below 0.5%. Related documentation includes an HS Code, often categorized under 2933 for heterocyclic compounds, which customs officials use to monitor and tax this material during international shipping. Accurate information on grade, batch, and transport safety ensures that end-users receive the product in optimal condition, streamlining not just regulatory oversight but also quality control steps in large-scale production or experimental settings.
Handling 1-Butyl-2,3-Dimethylimidazolium Dicyanamide requires common-sense precautions familiar to any experienced chemist or plant operator. This chemical, like many advanced raw materials, can cause irritation if it comes into prolonged contact with skin or eyes. Inhalation of powder or mist should be avoided, and any spillage calls for containment and cleanup with gloves and protective eyewear. Safety Data Sheets note that while not as acutely toxic as some traditional solvents, this compound poses environmental risks if disposed of improperly. Waste streams should be collected and processed according to local hazardous material guidelines, especially since dicyanamide breakdown can create secondary pollutants. Good ventilation, monitored storage temperatures, and labeled containers minimize risk and create a safer work environment. Real-world incidents have shown that small procedural lapses—like running reactions with unlabeled beakers—can snowball, which only underscores the value of strict chemical hygiene.
Applications for this ionic liquid touch on multiple high-tech fields, from catalysis and electrochemistry to advanced separation science. As a raw material, the compound often acts as a specialized solvent in organic synthesis, enabling reactions that demand high ionic strength or unique solvation features. Its low melting point, wide liquidus range, and inherent stability support use in batteries, where cycle life and reliability matter as much as conductivity. In material science, its ability to fine-tune polymer morphologies offers researchers another lever for custom properties, such as flexibility or conductivity. Experienced chemists know that the difference between an efficient, scalable process and a failed batch can come down to the right raw materials—properties like purity, phase, and compatibility can make or break a pilot line. Suppliers continue to develop new crystal forms and tailored solutions that feed into specialized separation processes, pushing the frontier in advanced synthesis and electrochemical technology.
The chemical sector needs to balance productivity with safety and environmental stewardship, especially as regulatory frameworks tighten. Sourcing 1-Butyl-2,3-Dimethylimidazolium Dicyanamide from reputable vendors lowers the risk of contamination or hazardous byproducts. High-purity batches, rigorous transport protocols, and user training deliver value across the chain, from R&D labs to large-scale industrial plants. Investment in real-time monitoring, better waste collection, and emergency response planning reduces both cost and ecological risk. My experience in chemical manufacturing has shown that upfront attention to specification and safe handling always saves trouble down the line. Stakeholders in material science, energy storage, and green chemistry recognize this balance, pushing for transparent supply chains and closed-loop recycling. Practical, effective solutions draw on both shared knowledge and innovation, so the next round of technology improvements builds in safety and sustainability from the ground up.
