Vanadium Isooctanoate is a vanadium-based organometallic compound recognized for its unique chemical properties and uses in a range of industrial applications. This material contains vanadium in its core, bonded to isooctanoate ligands, resulting in a product suited for catalyst manufacturing, chemical synthesis, and other specialty uses. With a strong reputation for reliability, it often comes into play where precision and performance matter. The integration of isooctanoate groups introduces stability and solubility traits that enable more controlled reactions in both organic and mixed-phase systems.
Vanadium Isooctanoate shows up in different forms—powder, flake, solid, beads, and crystal. In liquid states, it dissolves well in various organic solvents with good consistency. Expect to see shiny crystals or pale-colored powders, depending on purity and manufacturing methods. The density typically hovers near 1.08-1.15 g/cm3, though this aspect shifts based on crystal structure and formulation specifics. In flake or powder form, it proves easier to handle in commercial and laboratory settings, offering lower dusting potential and improved flow characteristics when measured by liter or gram.
The molecular formula of Vanadium Isooctanoate generally follows the arrangement C16H30O4V, meaning the atom ratio ties vanadium with long-chain organic moieties. This configuration leads to a structure where vanadium’s variable oxidation states play a key role in reactivity. The crystal lattice remains relatively stable under dry, ambient conditions but can shift if exposed to moisture, which is a common trait among vanadium-organic complexes. Each molecule’s property profile ties back to vanadium’s coordination environment and ligand bulk, inviting chemists to study and leverage its tendencies during process design.
Vanadium Isooctanoate usually comes indexed under HS Code 282530, recognized across trading platforms and customs services. In terms of purity, commercial products often offer 95% or better, ensuring suitability in sensitive or regulated environments. It’s common to see sellers highlight trace metal analysis, residual moisture, and other contaminants, since these directly affect overall performance as a chemical raw material. Chemists may also quote exact vanadium content per gram or per liter of solution, as this figure directly impacts dosing and reaction calculations.
Anyone dealing with Vanadium Isooctanoate quickly learns to respect its chemical nature. While it stands stable when stored in sealed, dry containers away from heat, contact with strong oxidizers or acids leads to breakdown and potential risk. The compound’s thermal limits stretch beyond most standard laboratory conditions, but exceeding 200°C can trigger decomposition. It is considered hazardous and harmful, warranting thorough use of gloves, goggles, ventilation, and fume hoods. Handling spills or residues by means of dry sand or inert absorbent minimizes secondary risks. MSDS documentation advises storage below 30°C, away from direct sunlight, emphasizing safety at every point in the handling process.
This compound feeds a variety of niches: as a catalyst precursor in polymerization, an additive in lubricants, and a starting point for vanadium carbide or other specialty chemicals. Its high purity and reactivity make it a prime candidate for raw materials sourcing in industries ranging from petrochemicals to specialty glass manufacturing. The cost of vanadium-containing chemicals tends to fluctuate alongside global supply of vanadium ore, which anchors the price and availability of this and similar organometallics.
Working with Vanadium Isooctanoate highlights an ongoing challenge in chemical industries—balancing performance with responsible stewardship. Inhalation, ingestion, or skin contact brings risk of acute toxicity, which pushes for airtight safety cabinets, strong procedural controls, and regular air quality monitoring. Waste and residue call for regulated disposal, since vanadium toxicity extends to aquatic environments and soil. Training and education remain critical, as small errors introduce outsized harm. Industry standards increasingly focus on traceability for all vanadium-based products, which encourages companies to work with certified suppliers and uphold auditing systems that prevent environmental releases during production, use, and disposal.
