Bis(5-Oxo-L-Prolinato-N1,O2)Copper stands out in the field of coordination compounds for its distinctive structure and properties, often catching the eye of researchers and industry professionals alike. This material features copper chelated by two 5-oxo-L-prolinato ligands, giving it a deep green to blue color usually seen in crystalline solid or fine powder form. Chemists often describe it with a formula like C10H12CuN2O6, bringing together organic and inorganic elements for unique applications. The compound typically weighs in with a molar mass of roughly 335.76 g/mol, as calculated by combining the atomic weights of its individual elements. In terms of density, values tend to range from about 1.7 to 2.0 g/cm³, depending on crystal packing and sample purity. These specific physical qualities define how Bis(5-Oxo-L-Prolinato-N1,O2)Copper behaves in different lab and industrial settings.
The properties come directly from the arrangement of the ligands around the copper ion—each 5-oxo-L-prolinato binds through nitrogen and oxygen atoms, creating a chelate ring. This ring structure stabilizes the copper, protecting it against unwanted reactions and contributing to the compound’s persistence under air and moderate heat. Due to this stability, Bis(5-Oxo-L-Prolinato-N1,O2)Copper resists water moderately well, although prolonged exposure tends to dull the visual vibrance or, over time, degrade its lattice. The color can shift under different lighting or pH levels, which sometimes hints at subtle changes in the electronic structure. While many copper salts dissolve easily, this material often demands more forceful solvents like slightly acidic or complexing solutions, reflecting how the organic ligands tighten their hold on the copper core.
In a laboratory, Bis(5-Oxo-L-Prolinato-N1,O2)Copper commonly appears in fine powder or as small crystalline flakes, but scaled production occasionally turns out small solid pearls or even dense flakes. The powder’s color intensity usually signals its purity. If it arrives as a coarse crystal, handling must be careful to avoid breaking the structure, which can alter surface characteristics or change the speed of dissolution in solvents. Some applications look for suspensions or pre-made solutions, especially when working with delicate processes. Bulk material offers convenience for raw material needs yet demands safety checks on dust generation or inhalation risk.
Producers tend to specify Bis(5-Oxo-L-Prolinato-N1,O2)Copper by purity—most labs look for 98% or higher. Granularity, moisture content, and color match industry norms for chemical standards. Producers usually ship this chemical in airtight bottles or drums, keeping light and air away to preserve its sharp hue and prevent slow decay. Information sheets specify HS Code 282550 for international trade and shipping, connecting buyers to the right customs and import documentation. The chemical structure, with copper at the center of two five-membered rings, matters because it shapes how the material reacts, tolerates storage, and bonds in advanced synthesis work.
Like many copper compounds, Bis(5-Oxo-L-Prolinato-N1,O2)Copper needs cautious handling. It is not benign—ingesting or inhaling fine powder can irritate the digestive or respiratory tract. Prolonged or repeated skin contact may stain or provoke mild irritation. Always use gloves, goggles, and a lab coat, keeping stocks in secure, well-marked containers. Spills are swept up gently—never blown or brushed in a way that might launch dust. This compound does not ignite under normal conditions, but it does not mix well with certain strong oxidizers or acids. Disposal follows hazardous waste rules, collected separately from general lab trash to prevent environmental copper release. Workers do well to read the SDS before each new use or batch handling cycle. Investors or procurement officers know to source raw materials only from verified suppliers, tracing batches to prevent impurities or dangerous substitutions, which can lead to inconsistent product quality or regulatory trouble down the line.
Researchers use Bis(5-Oxo-L-Prolinato-N1,O2)Copper to explore new catalysts, test advanced materials, or design coordination polymers. Its structure lets it mimic biological copper centers, making it a frequent subject in biomimetic chemistry and enzyme modeling. In my experience with specialty chemicals, the compound often finds use not because it is the easiest copper salt, but because the prolinato ligand brings new electronic and steric features. This opens the door to fine-tuned reactions or creative material design. Sometimes it appears in battery research, pigment development, or as a demonstration piece in advanced inorganic chemistry courses, displaying how organic and inorganic chemistry weave together in modern science.
Product consistency and safe handling seem to be ongoing themes with specialty metal-organic compounds. With Bis(5-Oxo-L-Prolinato-N1,O2)Copper, documentation and third-party testing help maintain trust between supplier and end user. Frequent requests for spectroscopic and elemental analysis reflect the need to avoid trace contamination and unexpected reactivity. To address safety gaps, labs and production lines employ fume hoods, straightforward labeling, and regular staff training on chemical hygiene. For suppliers, adding batch-specific certificates and clear storage instructions reduces procurement errors and user risk. Anyone in the market for this copper complex should ask suppliers for transparent sourcing, up-to-date safety information, and full regulatory compliance, especially in heavy-traffic, cross-border shipments where customs codes and documentation cut down on costly delays.
