What is a CAS Number?

In order to correctly identify specific chemicals, the Chemical Abstracts Service (CAS) has designated 163 million organic and inorganic compounds their own unique CAS Registry Number, a five-to-ten string of text in the form of xxxx-yy-z. It’s like a compound’s social security number: regardless of the compound’s name(s), it has only one CAS-Number. The implementation of the CAS-Number system has solved significant scientific complexities, most of which have made technical communication difficult. Because compounds may have a myriad of names and/or unusual and long names, the CAS-Number is a convenient way of specifying and identifying a compound without additional confusion. Take methanol, for example, which has an extensive list of commonly used synonyms¹—methyl alcohol, wood alcohol, carbinol, methylol, hydroxymethyl, MeOH, etc. And those are only in English! If methanol is instead referred to by its CAS-Number 67-56-1, there is then a bridge that traverses all synonyms and languages. Additionally, CAS-Numbers are assigned to the specific forms of a compound to avoid even further confusion. While 1317-38-0 and 1317-39-1 both refer to Cupric Oxide compounds, the former appears as a wire whereas the latter is a black powd er. The question ‘Which form of Cupric Oxide?’ is thus eliminated by just a few digits. CAS-Numbers are particularly beneficial in laboratory environments, business transactions involving chemicals, and for educational purpose s. So, if you’re in any of these potential domains, CAS-Numbers are necessary tools that are 1) easily found on Google and 2) completely cost-free.

The CAS was originally founded in 1907 as a division of the American Chemical Society to help scientists easily access colleagues’ literature. About sixty years later, the registry introduced the CAS-Number to make chemical identification simpler and more seamless; and in 1980, the CAS online database was founded and proved to be invaluable to chemical research and the transmission of chemical information. The United States Environmental Protection Agency (USEPA) now relies on CAS numbers for the definite identification of chemical substances (EPA-United States Environmental Protection Agency 1998), as well as The European Union (EU) through the REACH (Regulation on Registration, Evaluation, Authorization and Restriction of Chemicals) candidate list, which relies on a proper identification of these problematic substances (REACH 2007). It’s essentially ubiquitous in the chemical world and effortless to access/utilize. Though there are various ways of finding a compound’s CAS-Number, the example below demonstrates one way of doing so.

¹ Information found on PubChem, an open chemistry database at the National Institutes of Health(NIH). “Methanol.” National Center for Biotechnology Information. PubChem Compound Database, U.S. National Library of Medicine, pubchem.ncbi.nlm.nih.gov/compound/Methanol.

Two of the easiest and most credible sources to use when finding a compound’s CAS-Number are ChemIDplus from the National Library of Medicine and the NIST Chemistry Webbook from the National Institute of Standards and Technology. For simplicity, I’ll just explain using ChemIDplus. Begin by searching “ChemIDplus” in the Google search bar, and click on the first result to get to the main search page. It should read “ChemIDplus Advanced.” Then, simply enter the desired compound under “Substance Identification.” I’m going to use Ibuprofen for this example, only because my father and I recently had an argument about its validity. Notice that after searching Ibuprofen in the Substance Identification table, Ibuprofen was the main Substance Name. If I searched “Advil” instead of Ibuprofen, I would have to click on “Names and Synonyms” to clarify it is the same substance. If it directs you to the correct substance, the CAS-Number can be found directly under the substance name, where “RN” indicates the corresponding Registry Number. Note, however, that this is only if using the ChemIDplus website. These numbers are sometimes in square brackets and in other abbreviations on other websites. But no matter how you find the CAS-Number, remember that each compound, and form of that compound, will have its own CAS-Number . So, double check that the number and compound are the correct match., or its uses go down the drain.

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What is Potassium Manganate used for?

Potassium manganate is the inorganic compound with the formula K2MnO4. This green-colored salt is an intermediate in the industrial synthesis of potassium permanganate (KMnO4), a common chemical. Occasionally, potassium manganate and potassium permanganate are confused, but they are different compounds with distinctly different properties.

Potassium Manganate is used for producing batteries, bleaching skins, fibers, oils; disinfectants; mordant (wool); photography; printing; source of oxygen (dyeing); water purification. Learn more about City Chemical LLC.

source https://www.citychemical.com/potassium-manganate.html

Preparation For Chemical Spills In The Work Environment Needs To Be Made

Chemicals in the workplace have to be considered for repercussions of spills before they take place. Breakthrough prep work can prevent a small spill from becoming a catastrophe. Before dealing with any chemical, end up being accustomed to a chemical's threats consisting of hazards of a clean-up. Read the Material Safety Data Sheet (MSDS) as well as use suitable safeguards to prevent a spill in the first place. Have the correct emergency situation equipment or spill sets prior to a spill happens for each and every family members of chemicals. If a spill does occur, the chemical must be understood and also any kind of dangers it will certainly impose. Have a policy on that to get in touch with for a spill. Make use of the correct treatments with the clean-up. If an emergency solution is required to be gotten in touch with, the details on the chemical splashed will certainly require to be recognized, such as if the chemical is health and wellness harmful. Information required to be collected for a splashed chemical: Personal direct exposure - If the spill will certainly create accident to any individual vacate the area. Control - If it is practical to stop the spill from spreading or going into a flooring drainpipe. Prevent access - If others may pertain to damage by entering the location, prevent access to the location. Analysis - Establish the sort of material splashed and also the degree of the spill. Injuries - Determine type and also degree of injuries, if appropriate. Reporting-- Know that to contact. A phone emergency contact listing need to be uploaded by each phone. Be prepared to address concerns on the material splashed, quantity, threats, degree of the spill, and also if any type of what injuries have taken place. The responsibility for clean-up of a spill of a material is based upon the level of risk of the spill itself and the level of individual safety devices called for. Spills that are not health harmful or there are trained people with correct clean-up devices, the spill ought to be consisted of and also removed. Spills that call for protective clothes and also an air-purifying respirator should be taken care of by highly educated employees and may consist of outdoors services. In order to identify that is responsible for a clean-up of a spill, each chemical must be categorized for a provided circumstance. Check out the MSDS on a chemical prior to collaborating with it. Know what to do if the splashed amount is little or a large amount. Chemicals might be fairly harmless in small amounts, however incredibly dangerous in big quantities. City Chemical produces chemicals like: Acetone Sodium Bisulfite (540-92-1), Aluminum Citrate (31142-56-0), Aluminum Fluoride (7784-18-1), Ammonium Carbamate (1111-78-0), Ammonium Iodide (12027-06-4), Ammonium Fluoride (12125-01-8), Barium Cyanide (542-62-1), Cerium Molybdate (13454-70-1), Clerici Solution (61971-47-9), Cobalt Carbonyl (10210-68-1), Cupric Oxide (1317-38-0), Dichlorophene (97-23-4), Diethylsilane (542-91-6), 3,3-Dimethylnaphthidine (13138-48-2), Germanium Disulfide (12025-34-2), D-Glucosamine (3416-24-8), Hexamethylditin (661-69-8), Humic Acid (1415-93-6), DL-Iso-Citric Acid triSodium Salt (1637-73-6), Lead Iodide (10101-63-0), Lead Thiocyanate (592-87-0), Magnesium Fluoride (7783-40-6), Molybdenum Dichloride Dioxide (13637-68-8), Nickel Monoxide (1313-99-1), Potassium Manganate (10294-64-1), Primuline (8064-60-6), Quininic Acid (86-68-0), Silicon Tetraiodide (13465-84-4), Silver Nitrate (7761-88-8), Tantalum Ethoxide (6074-84-6), Tetraethylgermanium (597-63-7), Tetraethylsilane (631-36-7), Triethylsilane (617-86-7), Tubocurarine Chloride (57-94-3), Zinc Chromate (13530-65-9), Zinc Silicofluoride (16871-71-9), CVD & ALD Precursors, Electronic Chemicals, Laboratory Reagents, Patina Chemicals Learn more about City Chemical at citychemical.com If the possibility of a spill has actually written plans and skilled employees, the potential for a calamity can be prevented. Recognizing and recording chemicals available will guarantee the safety of employees. This understanding will additionally be essential for emergency situation personnel responding to a call such as a fire on the properties.

source https://www.citychemical.com/

Bismuth (III) Oxychloride - Cas No. 7787-59-9

Bismuth (III) Oxychloride - Cas No. 7787-59-9 is an inorganic compound of bismuth with the chemical formula: BiOCl. BiOCl is formed during the reaction of bismuth chloride with water. It has been used in cosmetic products such as eye shadow, hair sprays, powders, nail polishes, and many more. It is also known as pearl white. Learn more about City Chemical LLC.

source https://www.citychemical.com/bismuth-iii-oxychloride.html

1,4-Naphthoquinone - Cas No. 130-15-4

1,4-Naphthoquinone (Cas: 130-15-4) or para-naphthoquinone is an organic compound derived from naphthalene. It has a molecular formula of: C10H6O2. It forms volatile yellow triclinic crystals and has a sharp odor similar to benzoquinone. It is almost insoluble in cold water, slightly soluble in petroleum ether, and more soluble in polar organic solvents. It is mainly used as a precursor to anthraquinone by reaction with butadiene followed by oxidation. Learn more about City Chemical LLC.

source https://www.citychemical.com/1-4-naphthoquinone.html

Antimony Trioxide - Cas No. 1309-64-74

Antimony Trioxide - CAS No. 1309-64-74 is the inorganic compound with the formula Sb2O3. It is the most important commercial compound of antimony. It is found in nature as the minerals valentinite and senarmontite. It dissolves in aqueous solutions with hydrolysis. It is mainly used as flame retardant synergist in combination with halogenated materials. It is also used in the manufacturing of a plastic material known as polyethylene terephthalate (PET). Learn more about City Chemical LLC.

source https://www.citychemical.com/antimony-trioxide.html

Zinc Oleate - Cas No. 557-07-3

Zinc Oleate (Cas. 557-07-3) is the Zinc salt of oleic acid with the molecular formula: C36H66O4Zn. It is a light tan color powder containing about 8.5-10.5% zinc. Zinc oleate may appear as bloom on the surface of oil or alkyd paints when it is formed by the reaction of oleic acid with zinc white pigment. Zinc oleate is also used as a drier in paints, resins and varnishes. Learn more about City Chemical LLC.

source https://www.citychemical.com/zinc-oleate.html