N-Ethylpyridinium Dicyanamide belongs to the family of organic salts, structured with an N-ethylpyridinium cation and a dicyanamide anion. This chemical stands out for its variety of physical forms and adaptability across industrial, research, and chemical synthesis environments. The raw material sources shape its molecular purity, which influences every property from physical appearance to handling requirements. It integrates into processes where ionic liquids, catalysts, and intermediate substances are in high demand, so its specification accuracy matters for anyone concerned with consistency, quality, and project repeatability.
Chemically, N-Ethylpyridinium Dicyanamide holds a straightforward formula, C7H10N3 + C2N3–, summing up to a molecular weight near 202.24 g/mol. Its architecture centers on the N-ethylpyridinium ring paired with a dicyanamide group, resulting in a stable, ionically bonded compound. I have worked with similar ionic compounds in laboratory settings; their robust bonding means reliable stability under controlled conditions, and that helps reduce unforeseen degradation during storage and application.
The product appears in multiple formats—beads, powder, crystalline solid, fine flakes, or even as a highly concentrated liquid solution. Each type comes from adjustments in production or post-synthesis processing, helping match requirements in manufacturing, research, or formulating new materials. Color ranges from off-white to colorless, driven by the purity of precursor chemicals and batch-specific processes. Density typically lands between 1.1 and 1.3 g/cm³, giving it good dispersibility in both aqueous and selected organic media. When handling the crystal or flaked format, the static charge can pick up fine dust, so containment and local ventilation lower operator exposure.
Specifications hinge on both purity and water content, with reputable suppliers listing assays usually above 98%, and water content often under 0.5%. The melting point varies but hovers in the 130-160°C range, so temperature consistency during storage keeps the material from clumping or transforming state. Solubility showcases a unique advantage: N-Ethylpyridinium Dicyanamide dissolves efficiently in polar solvents, granting flexibility to chemists aiming for homogenous mixtures or smooth reactions. The product can take the form of large pearls—useful for slow-dispensing or tightly controlled feedstock applications—or a fine, dry powder that disperses quickly in mixing tanks. When I handled similar powders, matching the format to the process method reduced waste and minimized transfer loss.
Packing, shipping, and daily use require attention to hazard classification. The HS Code for N-Ethylpyridinium Dicyanamide generally falls under 292690, marking it within the category for nitrogen-function organic compounds. It carries health and safety risks tied to the dicyanamide moiety—prolonged skin contact or inhalation can cause irritation or sensitization, and improper handling of dust or solution may pose risks if protective gloves, goggles, and controlled ventilation are not used. Material Safety Data Sheets ask for keeping the chemical away from strong acids, oxidizing agents, and open flames, given the potential for decomposition and release of harmful gases. Workplace practices, including local exhaust and emergency showers, especially matter in labs or pilot plants using the material routinely.
Industries adopt N-Ethylpyridinium Dicyanamide as both a specialty ionic fluid and as a raw material for chemical synthesis. Its conductivity, low volatility, and stable nature make it valuable in applications constructing advanced batteries, catalysts, and electrochemical devices. Researchers count on its well-characterized ionic bonding for studying solvent effects, molecular mobility, and reactivity in both organic and aqueous conditions. Since the compound can act as a building block, engineers use it for creating tailor-made compounds with custom reactivity or solubility profiles, enabling smoother formulation steps or new product launches. In my time collaborating on electrochemical projects, a reliable supply of ionic intermediates like this one determined whether a pilot project scaled efficiently or suffered from ingredient inconsistencies.
Proper storage means sealed drums or bottles, preferably in cool, low-humidity rooms to maintain structure and prevent water uptake. Spill containment, labeled containers, and periodic inventory checks address both regulatory needs and internal safety culture. Waste disposal involves coordinating with licensed collectors since the chemical classifies as hazardous, even in small residual amounts after production or laboratory work. Companies taking these precautions avoid regulatory headaches and reduce the risk of cross-contamination in their facilities, keeping staff and downstream processes safer.
Potential solutions can promote safer and more efficient use of N-Ethylpyridinium Dicyanamide. Suppliers develop training modules and feature QR-linked safety guides printed directly on drums or packaging: that bridges the knowledge gap for both new and experienced users. Implementing closed transfer systems with dust collection mitigates airborne contamination and reduces time spent cleaning up after batch handling. At the regulatory and industry level, transparent documentation—COAs with full impurity profiles, clear lot tracking, and prompt safety updates—empower customers to spot out-of-specification batches before they disrupt workflow or endanger health. These steps matter not just for compliance, but for real-world reliability, worker confidence, and product performance.
To recap the concrete details for purchasing and operational decisions: N-Ethylpyridinium Dicyanamide carries the molecular formula C7H10N3 + C2N3–, molecular weight around 202.24 g/mol, forms including powder, flakes, crystals, solid pearls, and concentrated liquid. Density measures about 1.1–1.3 g/cm³. Water content stays low, below 0.5%, and purity often exceeds 98%. HS Code comes in at 292690. Chemical reactivity, stability, and electrical properties make it a valuable material for both research and industrial applications. Proper handling, using appropriate PPE and safety systems, limits the risk of harmful exposure to the chemical’s more hazardous components and preserves long-term safety for workers and the environment. For any operation considering this raw material, keeping processed batches secured and making safety part of daily practice anchors both quality and responsibility in chemical management.
