4098-71-9

A clear to light-yellow liquid. Slightly denser than water and insoluble in water. Toxic by inhalation and skin absorption. Very irritating to skin. Used to make polyurethane coatings.

ISOPHORONE DIISOCYANATE(4098-71-9) reacts with all substances containing active hydrogen atoms such as water, alcohols, phenols, amines, mercaptans, amides, urethanes and ureas.

Insoluble in water. This chemical may be sensitive to moisture.

A severe irritant, toxic by skin absorption.

This material is highly toxic by inhalation and moderately toxic through the skin. (Non-Specific--Isocyanates) People with skin or respiratory problems should avoid exposure.

When heated to decomposition, ISOPHORONE DIISOCYANATE emits toxic fumes of nitrogen oxides.

Isophorone diisocyanate (IPDI) (CAS No. 4098-71-9) is a clear to pale-yellow liquid with a camphorlike odor which is insoluble in water and miscible with most common organic solvents. IPDI exists in two conformers, cis and trans. Their reactivities are similar and each conformer is an asymmetrical molecule with the secondary isocyanate group being more reactive than the primary isocyanate group. Since the substance does not contain any groups that might oxidize or spontaneously ignite, it is not expected that IPDI would self-ignite, oxidize, or explode at ambient conditions. The water solubility is approximately 15 mg l-1 at 23 ℃, and hydrolysis with a half-life of about an hour leads to polymers or to the corresponding diamine.

colourless or slightly yellow liquid

ChEBI: A diisocyanate in which the two isocyanate groups are linked by an isophorone substituent.

Isophorone diisocyanate (IPDI) is prepared by the phosgenation of isophorone diamine (l-amino-3-aminomethyl-3,5,5-trimethylcydohexane):

IPDI is a synthetic organic chemical, which does not occur naturally in the environment. At room temperature, it is a liquid. It is miscible with alcohol, diglycol, monoethyl ether, ether, acetone, carbon tetrachloride, benzene, chlorobenzene, kerosene, and olive oil. IPDI decomposes in water producing CO2, which can produce significant pressure in a closed container. Upon contact with water or moist air, IPDI will react to form stable, insoluble polyurea solids. This reactivity dramatically limits the mobility of these products in the event of a spill (spills are localized and have only transient impact), and the products will tend to remain in, and react within, the environment to which they are released. IPDI is not readily biodegradable. It reacts with water forming solid insoluble polyurea, isophorone diamine (IPDA), and CO2, thus the predominant removal mechanism is expected to be hydrolysis. The rate constant of the OH radical sensitized indirect photodegradation of isophorone diisocyanate corresponds to a half-life of 1.8 days at a 24 h mean OH radical concentration of 500 000 molecules per cm³. A preliminary hydrolysis test resulted in a dissipation half-life of 0.84 h (approximately 50 min) at 23 ℃. Polyurea is more or less inert and – due to its molecular size – not bioavailable. No biodegradation (0% degradation within 28 days) was observed in a manometric respiratory test performed with domestic, nonadapted activated sludge. As no degradation occurred in the test on ready biodegradability, it is not expected that a significant degradation would occur in a simulation test (water and soil). The test substance is considered as nonbiodegradable in surface water, sediment, and soil. However, biodegradation is considered as irrelevant as primary degradation step anyway because immediate hydrolysis takes place. Due to hydrolysis in water, bioaccumulation of IPDI is not expected. The bioaccumulation potential of the hydrolysis product IPDA is considered to be low (log Kow = 0.99). There are no data on terrestrial bioaccumulation available.

The toxicological properties of isocyanates are attributed to the –N=C=O group. The consequence is that in the hydrolysis of IPDI predominantly polyurea molecules are formed with liberation of CO2. The polyurea molecules are insoluble in water. Beside these insoluble main hydrolysis products, there are minor amounts of other hydrolysis products having a low to moderate molecular weight and these are more or less water soluble (e.g., isophorone diamine). The local toxic effect of the substance IPDI is not related to metabolic mechanisms, because it is a simple destruction of membranes due to corrosivity of the substance.

Disposal is by chemical incineration of IPDIsolution in a combustible solvent.