50-00-0 Usage
General Description
Different sources of media describe the General Description of 50-00-0 differently. You can refer to the following data:
1. Formaldehyde, also called formic aldehyde or methyl aldehyde, has extensive application. For instance, it is used as a tissue preservative or organic chemical reagent. Thus, formaldehyde is very common to the chemical industry. In fact, formaldehyde is an important chemical used widely by industry to manufacture building materials and numerous household products. It is also a by-product of combustion and certain other natural processes. It is present in substantial concentrations both indoors and outdoors. Formaldehyde is well known as a preservative in medical laboratories, as an embalming fluid, and as a steriliser. Its primary use is in the production of resins and as a chemical intermediate. Urea–formaldehyde (uf) and phenol–formaldehyde (pf) resins are used in foam insulations, as adhesives in the production of particle board and plywood, and in the treating of textiles. Sources of formaldehyde in the home include building materials, smoking, household products, and the use of unvented, fuel-burning appliances, like gas stoves or kerosene space heaters. Formaldehyde, by itself or in combination with other chemicals, serves a number of purposes in manufactured products.
Formaldehyde itself is a colourless gas, but it is more commonly purchased and used in aqueous solution (called formalin solution), with a maximum concentration of 40%. Formalin solutions often contain some amount of methanol as well. Both formaldehyde gas and solutions have a characteristic pungent, unpleasant odour.
2. Formaldehyde solution commercially formaldehyde solution is an aqueous solution containing 37% formaldehyde and 8-10% methanol. Formaldehyde solution can be activated by adding the catalytic amount of lanthanide triflate. This activated formaldehyde solution was employed for the smooth hydroxymethylation reaction of silyl enol ethers. Formaldehyde solution reacts with silyl enol ethers to afford the corresponding hydroxymethylated adducts in high yields.
Chemical Properties
Different sources of media describe the Chemical Properties of 50-00-0 differently. You can refer to the following data:
1. Formaldehyde is colorless gas with a very distinct, pungent odor. It is highly soluble in water and in a variety of organic solvents. It has the potential to react explosively with peroxides and nitrogen oxide.
Formalin, the aqueous form of formaldehyde, is a colorless liquid with a very distinct, pungent odor. It is incompatible and may react with strong oxidizers, alkalis,and acids. The liquid has a variable molecular weight, which is dependent on the specific aqueous formulation.
2. Formalin is made slightly alkaline (pH 8) by the addition of sodium
hydroxide and then urea is added to give a urea to formaldehyde ratio of
about 1: 2 molar. The resulting solution is boiled under reflux for about 15
minutes, acidified (to pH 4) with formic acid and then boiled for a further
5-20 minutes until the required degree of reaction is attained.
3. Formaldehyde is an important chemical widely used by industry to manufacture building materials and numerous household products. It is also a by-product of combustion and certain other natural processes. It is present in substantial concentrations both indoors and outdoors. Formaldehyde is well known as a preservative in medical laboratories, as an embalming fl uid, and as a sterilizer. Its primary use is in the production of resins and as a chemical intermediate. Urea formaldehyde (uf) and phenol formaldehyde (pf) resins are used in foam insulations, as adhesives in the production of particle board and plywood, and in the treating of textiles. Sources of formaldehyde in the home include building materials, smoking, household products, and the use of unvented, fuel-burning appliances, like gas stoves or kerosene space heaters. Formaldehyde, by itself or in combination with other chemicals, serves a number of purposes in manufactured products. It has been reported that the use and production of formaldehyde in 1998 was about 11.3 billion pounds and the international production crossed over 46 billion pounds in 2004.
Uses
Different sources of media describe the Uses of 50-00-0 differently. You can refer to the following data:
1. Formaldehyde (methyl aldehyde, methylene oxide) is a ubiquitous compound found endogenously in the body and environment. It is a colorless, flammable gas with a distinct, pungent odor and is most commonly available in aqueous solutions under the name formalin (37% formaldehyde in water). Formaldehyde has been used as a disinfectant, an embalming agent, and in industry as a precursor in the fabrication of complex compounds. Since scientific research has identified links between formaldehyde and adverse health effects, precautions and protections must be considered during use.
2. Formaldehyde is used in the manufactureof phenolic resins, cellulose esters, artificialsilk, dyes, explosives, and organic chemicals.Other uses are as a germicide, fungicide, anddisinfectant; in tanning, adhesives, waterproofingfabrics, and for tonic and chromeprinting in photography; and for treating skindiseases in animals. In vitro neutralizationof scorpion venom toxicity by formaldehydehas been reported (Venkateswarlu et al.1988).Formaldehyde constitutes about 50% ofall aldehydes present in the air. It is oneof the toxic effluent gases emitted fromburning wood and synthetic polymeric substancessuch as polyethylene, nylon 6, andpolyurethane foams. Firefighters have a greaterrisk to its exposure. Incapacitation fromthe toxic effluent gases is reported to occurmore rapidly from the combustion of syntheticpolymers than from that of naturalcellulose materials.Formaldehyde is directly emitted into theair from vehicles. It is released in traceamounts from pressed wood products suchas particleboard and plywood paneling, fromold “sick” buildings, and from cotton andcotton–polyester fabrics with selected crosslinkfinishes. Formation of formaldehyde hasbeen observed in some frozen gadoid fishdue to enzymic decomposition of the additivetrimethylamine oxide (Rehbein 1985).Its concentration can build up during frozenstorage of fish (Leblanc and Leblanc 1988;Reece 1985). It occurs in the upper atmosphere,cloud, and fog; it also forms inphotochemical smog processes.
3. More than half of the commercial formaldehyde produced is used to manufacture phenolic,urea, and melamine formaldehyde resins. Polyacetyl resins use another 5–10% of formaldehyde,and approximately 80% of formaldehyde goes into the resins and plastics industry.Phenolic-formaldehyde resins were the first synthetic plastics to be produced. The first plasticwas called Bakelite.Formaldehyde has traditionally been used as a preservative in biology and medical laboratoriesand in embalming fluid. Embalming fluids typically contain 5–15% formaldehyde, a significant percentage of alcohol, and other additives to perform certain functions, for example,bleaches and coloring to preserve skin color. Formaldehyde has been used to preserve deadbodies since 1900 and has several qualities that make it the preferred preservative. Foremostamong these is its low cost, but it also has several biochemical advantages: it kills germs andmicroorganisms, destroys decomposition enzymes, retards decomposition of proteins, andhardens body tissues.
4. Formaldehyde is used as the preservative; disinfectant; antiseptic; in embalming solutions; in the manufacture of phenolic resins, artificial silk, cellulose
esters, dyes, urea, thiourea, melamine res ins, organic chemicals, glass mirrors and explosives; used in improving fastness of dyes on
fabrics; in tanning and preserving hides; in mordanting and waterproofing fabrics; as a germicide and fungicide for vegetables and
other plants; in destroying flies and other insects; in preserving and coagulating rubber latex; prevent mildewand spelt in wheat and
rot in oats; used to ren der casein, albumin, and gelatin insoluble; in chemical analysis; as a tissue fixative; as a component of particle
board and plywood; in the manufacture of pentaerythritol, hexamethylenetetramine and lkbutanediol; used in ceiling and wall
insulation; in res ins used to wrinkle-proof fabrics; in photography for hardening gelatin plates and papers, for toning gelatin-chloride
papers and for chrome printing and developing; intermediate in drug manufacture; pesticide intermediate; in the production of urea,
phenolic melamine and acetale resins; in textile products; as an astringent, disinfectant, and preservative in cosmetics, metal-working
fluids, shampoos, etc.; antiperspirant in cosmetics; anticracking agent in dental plastics; in anhidrotics; chipboard production; in
cleaning products, disinfectants and deodorizers, dry-cleaning materials, and glues; in mineral-wool production, paints and coatings,
paper industry, phenolic resins and urea plastics; in adhesives and footwear, photographic paper and solutions, polishes, printing
materials, tanning agents, wart remedies, embalming solutions, fertilizers, wood composites, and insulation.
Description
Formaldehyde is a colorless, flammable gas with a distinctive pungent odor. It is the simplest
aldehyde, which is a class of organic compounds with the carbonyl group bonded to at
least one hydrogen atom. Formaldehyde was described by August Wilhelm von Hoff mann
(1818–1892) in 1867 after the Russian Aleksandr Butlerov (1828–1886) had inadvertently
synthesized it in 1857. Formaldehyde readily dissolves in water to produce a solution called
formalin, which is commonly marketed as a 37% solution.
Physical properties
Formaldehyde is a clear, colorless liquid with a pungent, suffocating odor. Burning taste. Experimentally determined odor threshold concentrations of 1.0 ppmv and 0.50 ppmv were reported by Leonardos et al. (1969) and Nagata and Takeuchi (1990), respectively. Also,formalin is an aqueous solution that is 37% formaldehyde by weight; inhibited solutions (added to prevent polymeri zation) usually contain 6 12% methyl alcohol. Formaldehyde is used in the manufacture of plastics and resins by reaction with phenols,urea, and melamine. It is used as a preservative,a disinfectant, and as a chemical intermediate.
History
Formaldehyde is a by-product of combustion of organic compounds, metabolism, and
other natural processes. Formaldehyde results from wood combustion and elevated atmospheric
concentrations can result from forest fires, as well as from urban pollution sources
such as transportation. Formaldehyde has been identified as a significant indoor air pollutant.
Building materials such as particleboard, plywood, and paneling are major sources of formaldehyde
because they incorporate formaldehyde resins as bonding adhesives. Other sources of
formaldehyde in the home are carpets, upholstery, drapes, tobacco smoke, and indoor combustion
products. Formaldehyde may be emitted from building materials for several years after
installation. In the two decades of the 1960s and 1970s, a half million homes in the United
States used urea formaldehyde foam insulation, but health complaints led to its elimination
as an insulator in the early 1980s. People react differently to formaldehyde exposure, but it is
estimated that between 10% and 20% of the population will experience some reaction at concentrations
as low as 0.2 parts per million. Formaldehyde irritates the eyes, nose, and throats,
producing coughing, sneezing, runny nose, and burning eyes. More severe reactions result in insomnia, headaches, rashes, and breathing difficulties. Some states have established indoor air
quality standards ranging from 0.05 to 0.5 ppm.
Production Methods
The industrial preparation of formaldehyde has occurred since the late 1800s and involvesthe catalytic oxidation of methanol: 2CH3OH(g) + O2(g) → 2CH2O(g).the oxidationtakes place at temperatures between 400°C and 700°C in the presence of metal catalysts. Metalsinclude silver, copper, molybdenum, platinum, and alloys of these metals. Formaldehyde iscommonly used as an aqueous solution called formalin. Commercial formalin solutions varybetween 37% and 50% formaldehyde. When formalin is prepared, it must be heated anda methanol must be added to prevent polymerization; the final formalin solution containsbetween 5% and 15% alcohol.
Preparation
Formalin is adjusted to pH 8 and urea is added to give a urea to
formaldehyde ratio of about 1 :2.5 molar. The resulting solution is boiled
under reflux for 1 hour. Butanol (1.5-2.0 mole per mole of urea) is then added
together with a little xylene. The latter forms, with butanol and water, a
ternary azeotrope which on distillation yields a condensate separating into an
upper organic layer and a lower aqueous layer. By discarding the lower layer
and returning the upper layer to the reactor, water is progressively removed
from the system. After a substantial proportion of the water has been
removed, an acid catalyst (e.g. phosphoric acid or phthalic anhydride) is
added and heating is continued. When the required degree of reaction is
attained, the solution is neutralized and concentrated to the desired solids
content.
Definition
Formalin: a colourless solution of methanal (formaldehyde) in waterwith methanol as a stabilizer; r.d.1.075–1.085. When kept at temperaturesbelow 25°C a white polymer ofmethanal separates out. It is used asa disinfectant and preservative forbiological specimens.
Air & Water Reactions
The solution gives up formaldehyde vapors readily. These vapors are flammable over a wide vapor-air concentration range. Water soluble.
Reactivity Profile
FORMALDEHYDE, SOLUTION, reacts violently with strong oxidizing agents (hydrogen peroxide, performic acid, perchloric acid in the presence of aniline, potassium permanganate, nitromethane). Reacts with bases (sodium hydroxide, potassium hydroxide, ammonia), and with nitrogen dioxide (explosive reaction around 180°C). Reacts with hydrochloric acid to form highly toxic bis(chloromethyl) ether. Polymerization reaction with phenol may develop sudden destructive pressure [Bretherick, 5th ed., 1995, p.168].
Hazard
Moderate fire risk. Explosive limits in air 7–
73%. Toxic by inhalation, strong irritant, a carcinogen. (Solution) Avoid breathing vapor and avoid
skin contact. Confirmed carcinogen.
Health Hazard
Formaldehyde is moderately toxic by skin contact and inhalation. Exposure to
formaldehyde gas can cause irritation of the eyes and respiratory tract, coughing, dry
throat, tightening of the chest, headache, a sensation of pressure in the head, and
palpitations of the heart. Exposure to 0.1 to 5 ppm causes irritation of the eyes, nose, and
throat; above 10 ppm severe lacrimation occurs, burning in the nose and throat is
experienced, and breathing becomes difficult. Acute exposure to concentrations above 25
ppm can cause serious injury, including fatal pulmonary edema. Formaldehyde has low
acute toxicity via the oral route. Ingestion can cause irritation of the mouth, throat, and
stomach, nausea, vomiting, convulsions, and coma. An oral dose of 30 to 100 mL of 37%
formalin can be fatal in humans. Formalin solutions can cause severe eye burns and loss
of vision. Eye contact may lead to delayed effects that are not appreciably eased by eye
washing.Formaldehyde is regulated by OSHA as a carcinogen (Standard 1910.1048) and is
listed in IARC Group 2A ("probable human carcinogen"). This substance is
classified as a "select carcinogen" under the criteria of the OSHA Laboratory
Standard. Prolonged or repeated exposure to formaldehyde can cause dermatitis and
sensitization of the skin and respiratory tract. Following skin contact, a symptom free period may occur in sensitized individuals. Subsequent exposures can then lead
to itching, redness, and the formation of blisters
Fire Hazard
Toxic vapors such as carbon dioxide and carbon monoxide are generated during combustion. Explosion hazard: when aqueous formaldehyde solutions are heated above their flash points, a potential for explosion hazard exists. High formaldehyde concentration or methanol content lowers flash point. Reacts with nitrogen oxides at about 180; the reaction becomes explosive. Also reacts violently with perchloric acid-aniline, performic acid, nitromethane, magnesium carbonate, and hydrogen peroxide. When heated, irritant formaldehyde gas evolved from solution. The main products of decomposition are carbon monoxide and hydrogen. Metals such as platinum, copper, chromia, and alumina also catalyze the formation of methanol, methylformate, formic acid, carbon dioxide, and methane. Reacts with peroxide, nitrogen oxide, and performic acid causing explosions. Can react with hydrogen chloride or other inorganic chlorides to form bis-chloromethylether (BCME), a known carcinogen. Very reactive, combines readily with many substances, 40% solution is powerful reducing agent. Incompatible with amines, azo compounds, dithiocarbamates, alkali and alkaline earth metals, nitrides, nitro compounds, unsaturated aliphatics and sulfides, organic peroxides, oxidizing agents, and reducing agents. Aqueous solutions are unstable. Commercial formaldehyde-alcohol solutions are stable. Gas is stable in absence of water. Avoid oxidizing and alkaline materials. Hazardous polymerization may occur. Compound will polymerize with active organic materials such as phenol. Will polymerize violently in the presence of caustics and nitrides; (amines) exothermic reaction, (Azo compound) exothermic reaction giving off nitrogen gas, (caustics) heat generation and violent polymerization, (dithiocarbamates) formation of flammable gases and toxic fumes, formation of carbon disulfide may result, (alkali and alkaline earth metals) heat generation and formation of a flammable hydrogen gas.
Flammability and Explosibility
Formaldehyde gas is extremely flammable; formalin solution is a combustible liquid (NFPA rating = 2 for 37% formaldehyde (15% methanol), NFPA rating = 4 for 37% formaldehyde (methanol free)). Toxic vapors may be given off in a fire. Carbon dioxide or dry chemical extinguishers should be used to fight formaldehyde fires.
Chemical Reactivity
Reactivity with Water No reaction; Reactivity with Common Materials: No reactions; Stability During Transport: Stable; Neutralizing Agents for Acids and Caustics: Not pertinent; Polymerization: Not pertinent; Inhibitor of Polymerization: Not pertinent.
Agricultural Uses
Microbiocide, Fungicide, Bactericide; Soil
sterilent: Registered for use in the U.S. Not approved for
use in EU countries. Formaldehyde has found wide
industrial usage as a fungicide, germicide and in disinfectants. It is used most often in an aqueous solution
stabilized with methanol (formalin). It is also a pesticide
intermediate.
Trade name
DYNOFORM?; FANNOFORM?;
FORMALITH?; FORMOL?; FYDE?; HERCULES
37 M6-8?; HOCH?; IVALON?; KARSAN?;
LYSOFORM?; MAGNIFLOC 156C FLOCCULANT?;
MORBICID?; STERIFORM?; SUPERLYSOFORM?
Contact allergens
Sources and uses of formaldehyde are numerous. Exposed
people are mainly health workers, cleaners, painters, met alworkers, but also photographers (color developers) and
carbonless copy paper users. Formaldehyde can induce
contact urticaria. Formaldehyde may be the cause of sen sitization to formaldehyde releasers: benzylhemiformal,
bromonitrodioxane, bromonitropropanediol (?), chloroal lylhexaminium chloride or Quaternium-15, diazolidinylu rea, dimethylol urea, dimethyloldimethylhydantoin or
DMDM hydantoin, hexamethylenetetramine or methe namine, imidazolidinylurea, monomethyloldimethylhy dantoin or MDM hydantoin, N-methylolchloracetamide,
paraformaldehyde and trihydroxyethylhexahydrotriazine
or Grotan BK.
Formaldehyde is used for the synthesis of many resins.
Some of them, such as formaldehyde-urea and melamine formaldehyde resins, can be used in textiles and second arily release free formaldehyde (see Chap. 40).
Other resins, such as p-tert-butylphenol formalde hyde resin or tosylamine formaldehyde resin, do not
release formaldehyde.
Biochem/physiol Actions
Formaldehyde is the simplest aldehyde that denatures the bihelical regions of RNA and converts the polynucleotides into random coils. It is a genotoxic substance that significantly induces DNA-protein crosslinks (DPC), sister-chromatid exchanges, micronuclei formation and leads to cytotoxicity. It also induces tumors in the nasal epithelium of rats and supposed to be a human carcinogen.
Safety Profile
Confirmed carcinogen
with experimental carcinogenic,
tumorigenic, and teratogenic data. Human
poison by ingestion. Experimental poison by
ingestion, skin contact, inhalation,
intravenous, intraperitoneal, and
subcutaneous routes. Human systemic
effects by inhalation: lachqmation, olfactory
changes, aggression, and pulmonary changes. Experimental reproductive effects.
Human mutation data reported. A human
skin and eye irritant. If swallowed it causes
violent vomiting and darrhea that can lead
to collapse. Frequent or prolonged exposure
can cause hypersensitivity leading to contact
dermatitis, possibly of an eczematoid nature.
An air concentration of 20 ppm is quickly
irritating to eyes. A common air
contaminant.
Flammable liquid when exposed to heat or
flame; can react vigorously with oxidizers. A
moderate explosion hazard when exposed to
heat or flame. The gas is a more dangerous
fire hazard than the vapor. Should
formaldehyde be involved in a fire, irritating
gaseous formaldehyde may be evolved.
When aqueous formaldehyde solutions are
heated above their flash points, a potential
for an explosion hazard exists. High
formaldehyde concentration or methanol
content lowers the flash point. Reacts with
sodum hydroxide to yield formic acid and
hydrogen. Reacts with NOx at about 180';
the reaction becomes explosive. Also reacts
violently with perchloric acid + anhe,
performic acid, nitromethane, magnesium
carbonate, H2O2. Moderately dangerous
because of irritating vapor that may exist in
toxic concentrations locally if storage tank is
ruptured. To fight fire, stop flow of gas (for
pure form); alcohol foam for 37%
methanol-free form. When heated to
decomposition it emits acrid smoke and
fumes. See also ALDEHYDES.
Potential Exposure
Formaldehyde has found wide indus trial usage as a fungicide, germicide; and in disinfectants
and embalming fluids. It is also used in the manufacture of
artificial silk and textiles, latex, phenol, urea, thiourea and
melamine resins; dyes, and inks; cellulose esters and other
organic molecules; mirrors, and explosives. It is also used
in the paper, photographic, and furniture industries. It is an
intermediate in drug manufacture and is a pesticide
intermediate.
Carcinogenicity
Formaldehyde is known to be a human carcinogen based on sufficient evidence of carcinogenicity from studies in humans and supporting data on mechanisms of carcinogenesis. Formaldehyde was first listed in the Second Annual Report on Carcinogens in 1981 as reasonably anticipated to be a human carcinogen based on sufficient evidence from studies in experimental animals. Since that time, additional cancer studies in humans have been published, and the listing status was changed to known to be a human carcinogen in the Twelfth Report on Carcinogens (2011).
Source
Formaldehyde naturally occurs in jimsonweed, pears, black currant, horsemint, sago
cycas seeds (1,640 to 2,200 ppm), oats, beets, and wild bergamot (Duke, 1992).
Formaldehyde was formed when acetaldehyde in the presence of oxygen was subjected to
continuous irradiation (λ >2200 ?) at room temperature (Johnston and Heicklen, 1964).
Schauer et al. (2001) measured organic compound emission rates for volatile organic
compounds, gas-phase semi-volatile organic compounds, and particle phase organic compounds
from the residential (fireplace) combustion of pine, oak, and eucalyptus. The gas-phase emission
rates of formaldehyde were 1,165 mg/kg of pine burned, 759 mg/kg of oak burned, and 599 mg/kg
of eucalyptus burned.
Gas-phase tailpipe emission rates from California Phase II reformulated gasoline-powered
automobiles with and without catalytic converters were 8.69 and 884 mg/km, respectively
(Schauer et al., 2002).
Environmental Fate
Biological. Biodegradation products reported include formic acid and ethanol, each of which can further degrade to carbon dioxide (Verschueren, 1983).Photolytic. Major products reported from the photooxidation of formaldehyde with nitrogen oxides are carbon monoxide, carbon dioxide and hydrogen peroxide (Altshuller, 1983). In synthetic air, photolysis of formaldehyde gave hydrochloric acid andIrradiation of gaseous formaldehyde containing an excess of nitrogen dioxide over chlorine yielded ozone, carbon monoxide, nitrogen pentoxide, nitryl chloride, nitric acid and hydrochloric acid. Peroxynitric acid was the major photolysis product when chloChemical/Physical. Oxidizes in air to formic acid (Hartley and Kidd, 1987). Trioxymethylene may precipitate under cold temperatures (Sax, 1984). Polymerizes easily (Windholz et al., 1983). Anticipated products from the reaction of formaldehyde with ozone orhydroxyl radicals in air are carbon monoxide and carbon dioxide (Cupitt, 1980). Major products reported from the photooxidation of formaldehyde with nitrogen oxides are carbon monoxide, carbon dioxide and hydrogen peroxide (Altshuller, 1983).Reacts with hydrochloric acid in moist air forming bis(chloromethyl)ether. This compound may also form from an acidic solution containing chloride ion and formaldehyde (Frankel et al., 1974). In an aqueous solution at 25°C, nearly all the formaldehyde add
storage
work with formaldehyde should be conducted in a fume hood to prevent exposure by inhalation, and splash goggles and impermeable gloves should be worn at all times to prevent eye and skin contact. Formaldehyde should be used only in areas free of ignition sources. Containers of formaldehyde should be stored in secondary containers in areas separate from oxidizers and bases.
Shipping
UN1198 Formaldehyde solutions, flammable,
Hazard Class: 3; Labels: 3-Flammable liquid, 8-Corrosive
material. Cylinders must be transported in a secure upright
position, in a well-ventilated truck. Protect cylinder and
labels from physical damage. The owner of the compressed
gas cylinder is the only entity allowed by federal law
(49CFR) to transport and refill them. It is a violation of
transportation regulations to refill compressed gas cylinders
without the express written permission of the owner.
UN2209 Formaldehyde solutions, with not<25% formal dehyde, Hazard class: 8; Labels: 8-Corrosive material.
UN3077 For solids containing varying amounts of formal dehyde : UN3077
Environmentally hazardous substances, solid, n.o.s., Hazard
class: 9; Labels: 9-Miscellaneous hazardous material,
Technical Name Required.
Purification Methods
It commonly contains added MeOH. Add KOH solution (1 mole KOH: 100 moles HCHO) to ~37% by weight aqueous formaldehyde solution (formalin), or evaporate to dryness, to give paraformaldehyde polymer which, after washing with water, is dried in a vacuum desiccator over P2O5 or H2SO4. Formaldehyde is regenerated by heating the paraformaldehyde to 120o under vacuum, or by decomposing it with barium peroxide. The monomer, a colourless flammable gas, is passed through a glass-wool filter cooled to -48o in a CaCl2/ice mixture to remove particles of polymer, then dried by passage over P2O5 and either condensed in a bulb immersed in liquid nitrogen or absorbed in ice-cold conductivity water. The gas or aqueous solutions have pungent suffocating odours, are LACHRYMATORY and suspected carcinogens, handle carefully. Formalin is a disinfectant and a preservative of dead animal and plant tissues. [Beilstein 1 IV 3017.]
Toxicity evaluation
The carbonyl atom is the electrophilic site of formaldehyde,
making it react easily with nucleophilic sites on cell membranes
and in body fluids and tissues such as the amino groups in
protein and DNA. Higher concentrations of formaldehyde
precipitate protein. It is probable that formaldehyde toxicity
occurs when intracellular levels saturate formaldehyde dehydrogenase
activity, allowing the unmetabolized intact molecule
to exert its effects locally. Formaldehyde is a very strong crosslinking
agent even in the low concentration range. The reaction
mechanism of this agent is the initial addition of formaldehyde
to a primary amine on either an amino acid residue or DNA
base to yield a hydroxymethyl intermediate. Then the hydroxymethyl
group condenses with a second primary amine to yield
a methylene bridge.
Incompatibilities
Pure formaldehyde may polymerize
unless properly inhibited (usually with methanol). May
form explosive mixture with air. Incompatible with strong
acids; amines, strong oxidizers; alkaline materials; nitrogen
dioxide; performic acid; phenols, urea. Reaction with
hydrochloric acid forms bis-chloromethyl ether, a carcino gen. Formalin is incompatible with strong oxidizers, alkalis,
acids, phenols, urea, oxides, isocyanates, caustics,
anhydrides.
Waste Disposal
Return refillable compressed
gas cylinders to supplier. Incineration in solution of combus tible solvent. Consult with environmental regulatory agen cies for guidance on acceptable disposal practices. Generators
of waste containing this contaminant (≥100 kg/mo)
must conform with EPA regulations governing storage, trans portation, treatment, and waste disposal.
Check Digit Verification of cas no
The CAS Registry Mumber 50-00-0 includes 5 digits separated into 3 groups by hyphens. The first part of the number,starting from the left, has 2 digits, 5 and 0 respectively; the second part has 2 digits, 0 and 0 respectively.
Calculate Digit Verification of CAS Registry Number 50-00:
(4*5)+(3*0)+(2*0)+(1*0)=20
20 % 10 = 0
So 50-00-0 is a valid CAS Registry Number.
InChI:InChI=1/CH2O/c1-2/h1H2
50-00-0Relevant articles and documents
Dhar, N. R.,Ram, A.
, p. 205 - 205 (1932)
Partial Oxidation of Methane by Nitrous Oxide over Molybdenum Oxide supported on Silica
Liu, R.-S.,Iwamoto, M.,Lunsford, Jack H.
, p. 78 - 79 (1982)
Methanol and formaldehyde were formed as major products at a moderate conversion level (16percent) in the partial oxidation of methane by nitrous oxide in the presence of water over molybdenum oxide supported on silica.
-
Honda et al.
, p. 3534,3536,3538,3541 (1972)
-
-
Shahin,Kutschke
, p. 73 (1961)
-
Atmospheric sink of β-ocimene and camphene initiated by Cl atoms: Kinetics and products at NOx free-Air
Gaona-Colmán, Elizabeth,Blanco, María B.,Barnes, Ian,Wiesen, Peter,Teruel, Mariano A.
, p. 27054 - 27063 (2018)
Rate coefficients for the gas-phase reactions of Cl atoms with β-ocimene and camphene were determined to be (in units of 10-10 cm3 per molecule per s) 5.5 ± 0.7 and 3.3 ± 0.4, respectively. The experiments were performed by the relative technique in an environmental chamber with FTIR detection of the reactants at 298 K and 760 torr. Product identification experiments were carried out by gas chromatography with mass spectrometry detection (GC-MS) using the solid-phase microextraction (SPME) method employing on-fiber carbonyl compound derivatization with o-(2,3,4,5,6-pentafluorobenzyl) hydroxylamine hydrochloride. An analysis of the available rates of addition of Cl atoms and OH radicals to the double bond of alkenes and cyclic and acyclic terpenes with a conjugated double bond at 298 K is presented. The atmospheric persistence of these compounds was calculated taking into account the measured rate coefficients. In addition, tropospheric chemical mechanisms for the title reactions are postulated.
Facile Degradation by Superoxide Ion of Carbon Tetrachloride, Chloroform, Methylene Chloride, and p,p'-DDT in Aprotic Media
Roberts, Julian L.,Sawyer, Donald T.
, p. 712 - 714 (1981)
-
O(1D) reaction with cyclopropane: Evidence of O atom insertion into the C-C bond
Shu, Jinian,Lin, Jim J.,Wang, Chia C.,Lee, Yuan T.,Yang, Xueming,Nguyen, Thanh Lam,Mebel, Alexander M.
, p. 7 - 10 (2001)
The reaction kinetics of O(1D) with cyclopropane was investigated using the universal crossed molecular beam method. The detailed dynamics of this reaction was explained from the analysis of time of flight spectra and angular distribution of th
The Retardation of Methanol Oxidation at a Platinum Electrode in an Acid Solution
Matsui, Hiroshi
, p. 3295 - 3300 (1988)
The rate retardation of the oxidation of methanol at the potential range of about 0.65-0.8 V vs. a reversible hydrogen electrode on a platinum electrode in 0.5 mol dm-3 H2SO4 was studied.The rate retardation of the overall oxidation was caused by that of the oxidation, Reaction D, not via COad.From the relationship among the rate of Reaction D, the COad coverage, and the potentials, three types of rate retardation were found out: Type 1-Reaction D is not accelerated by the potential, and the rate of the reaction is determined by the COad coverage and the methanol concentration.Type 2- the rate of Reaction D decreases at stationary COad coverages as the oxidation is prolonged.Type 3- the rate decreases at COad coverages close to the limiting value.It is proposed that Types 1 and 2 of the rate retardations take place when the adsorption of methanol molecules is rate-determining, and when the formaldehyde and formic acid formed from methanol are accumulated in the vicinity of the electrode, respectively.Type 3 of the rate retardation has been explained in a preceding paper in terms of the aggregate damaging effect of COad.
Photoinduced bimolecular reactions in homogeneous [CH3ONO]n clusters
Bergmann,Huber
, p. 259 - 267 (1997)
The photodissociation of homogeneous methyl nitrite clusters, [CH3ONO]n with n≈400-1000, was investigated in a supersonic jet using excitation mainly at 365 nm, which corresponds to S0→S1 (nπ*) excitation in the monomer. Besides the two types of NO(X2II) photofragment distributions, a rotationally relaxed one (Trot to approximately 250 K) and a nonthermally `hot' one (〈J″〉 = 35.5) which result from the primary dissociation step CH3ONO→CH3O+NO of cluster-bound CH3ONO, we observed the products HNO-(X1A′) and H2CO(X1A1) by state-selected LIF spectroscopy. Their product-yield excitation spectra and their formation dependence on the backing pressure revealed that HNO and H2CO originate exclusively from cluster photodissociation and not from primary photodissociation of the monomer. The mechanism of their formation was found to be the disproportionation reaction of the primary photofragments, CH3O+NO→HNO+H2CO, mediated by caging of the cluster environment. The fragments collide with, and recoil at, the solvent shell followed by subsequent recombination, disproportionation, or escape from the evaporating solvent cage. The present results are consistent with previous findings on the photolysis of isolated CH3ONO molecules in solid noble gas matrices where exclusively the products HNO and H2CO were found.
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Rosenblatt et al.
, p. 1649 (1968)
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TITRIMETRIC DETERMINATION OF GLYCEROL AND OF GLYCEROL 1-PHOSPHATE USING PERIODATE OXIDATION
Zakharans, V. Ya.,Lipsbergs, I. U.,Valdnietse, A. T.
, p. 216 - 217 (1983)
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Taylor,Blacet
, p. 1505 (1956)
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Mann,Hahn
, p. 329 (1969)
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Infrared Matrix Isolation Studies of the Reactions of Dichloro- and Dibromomethane with Atomic Oxygen
Lugez, C.,Schriver, A.,Schriver-Mazzuoli, L.,Lasson, E.,Nielsen, C. J.
, p. 11617 - 11624 (1993)
The reactions of atomic oxygen with CH2Cl2 and CH2Br2 trapped in argon matrices have been studied by FTIR spectroscopy.O(1D) and O(3P) were generated in situ by UV photolysis of co-deposited ozone.Products were identified by employing 18O and scrambled 18O/16O ozone as well as deuterated methylene halides.Kinetic studies performed on both CH2Cl2 and CH2Br2 with O(1D) under the same experimental conditions allowed the reaction pathway to be determined.With CH2Br2 as parent molecule, three routes were evident leading to (i) CHOBr,(ii) CO...(HBr)2, and (iii) CH2O.With CH2Cl2 as parent molecule, only the first two channels were observed.Carbonyl compounds rapidly decomposed under irradiation, and CO...(HX)2 was also produced as a secondary species.
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Sibirskaya,Pikaev
, (1968)
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Absorption Cross Section and Kinetics of IO in the Photolysis of CH3I in the Presence of Ozone
Cox, R. A.,Coker, G. B.
, p. 4478 - 4484 (1983)
The photolysis of CH3I in the presence of O3 was used as a source of IO radicals in N2 + O2 diluent at 1-atm pressure and 303 K.IO was detected in absorption by using the molecular modulation technique.The absorption spectrum in the region 415-470 nm, arising from the A2Π 2Π transition of IO, was recorded and the absolute absorption cross section at the band head of the (4-0) band at 426.9 nm determined to be 3.1+2.0-1.5x10-17 cm2 molecule-1.IO decayed by a rapid reaction which yielded an aerosol of probable formula I4O9 as a final product.The observed rate coefficient for IO decay was near the gas kinetic collision rate which probably reflects an efficient attachment of IO radicals to the growing aerosol.The significance of the photochemical and kinetic parameters for atmospheric iodine chemistry is briefly discussed.
Nonenforced Concerted General-Acid Catalysis of the Dehydration Step in Formaldehyde Thiosemicarbazone Formation
Palmer, John L.,Jencks, William P.
, p. 6466 - 6472 (1980)
At pH>6 the formation of formaldehyde thiosemicarbazone proceeds with rate-limiting dehydration of the carbinolamine intermediate, which is at equilibrium with formaldehyde hydrate and thiosemicarbazide (K = 550 M-1).At higher concentrations of formaldehyde a bis(formaldehyde) addition compound is formed, which undergoes dehydration more slowly.The dehydration step is subject to general-acid catalysis by phosphate and phosphonate buffers with α = 0.83.A solvent deuterium isotope effect of kHA/kDA = 2.6 for catalysis by ethylphosphonate monoanion and published evidence support a concerted mechanism of catalysis.The calculated rate constant for formation of the O-protonated carbinolamine is > 104 faster than the observed rate constant for dehydration and the rate constant for expulsion of water from this species is 7 s-1.Thus, it appears that a concerted mechanism can exist when it is not enforced by the nonexistence of the O-protonated species.The secondary α-deuterium isotope effect of KH/kD = 1.06 (1.03 /D) for catalysis by phosphate monoanion suggests an early transition state but other criteria suggest a central or late transition state for C-O cleavage.
BIOSYNTHESIS OF DOLICHOLACTONE IN TEUCRIUM MARUM
Grandi, Romano,Pagnoni, Ugo M.,Pinetti, Adriano,Trave, Roberto
, p. 2723 - 2726 (1983)
Iridodial is a very efficient precursor of dolicholactone in Teucrium marum.In the biogenetic formation of the lactone ring a hydride shift from C-1 to C-10 is observed.Citronellol and its 10-hydroxy derivative are preferred as precursors with respect to the C-2/C-3 unsaturated analogues. - Key Word Index: Teucrium marum; Labiate; dolicholactone; monoterpene biosynthesis; iridane skeleton; hydride shift.
Mechanistic and kinetic study of formaldehyde production in the atmospheric oxidation of dimethyl sulfide
Urbanski, Shawn P.,Stickel, Robert E.,Zhao, Zhizhong,Wine, Paul H.
, p. 2813 - 2819 (1997)
Tunable diode laser spectroscopic detection of formaldehyde (H2CO) and HCl coupled with laser flash photolysis of Cl2CO-CH3SCH3-O2-N2 mixtures, in both the presence and absence of NO, has been utilized to conduct a mechanistic and kinetic investigation of the atmospheric oxidation of the CH3SCH2 radical, a product of dimethyl sulfide (DMS, CH3SCH3) reactions with OH and NO3 in the atmosphere. The temperature dependence of the CH3SCH2O2 + NO rate coefficient (k2) and the 298 K rate coefficient for the CH3SCH2O2 self reaction (k4) have been measured. The Arrhenius expression k2 = 4.9 × 10-12 exp(263/T) cm3 molecule-1 s-1 adequately summarizes our CH3SCH2O2 + NO kinetic data over the temperature range 261-400 K. Contributions from side reactions, which are not completely quantifiable, limit the accuracy of the k4 (298 K) determination; our results indicate that the true value for this rate coefficient is within the range (1.2 ± 0.5) × 10-11 cm3 molecule-1 s-1. In both reactions CH3SCH2O2 is converted to H2CO with unit yield (at T = 298 K). Our results demonstrate that the lifetime of CH3SCH2O, a proposed precursor to H2CO, is less than 30 μs at 261 K and 10 Torr total pressure.
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Warshowsky,Elving
, p. 253 (1946)
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Ramaradhya,Freeman
, p. 1836 (1961)
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New alkyl-cobalt(III) complexes with tridentate amino-oxime ligands: Synthesis, structure, and reactivity
Dreos, Renata,Felluga, Alessandro,Nardin, Giorgio,Randaccio, Lucio,Siega, Patrizia,Tauzher, Giovanni
, p. 267 - 276 (2001)
The oxidative addition of alkyl halides to the CoI species generated by the reduction of [CoIII(LNHpy)(HLNHpy)]-(ClO4)2 (1), where HLNHpy is the tridentate 2-(2-pyridyl-ethyl)amino-3-butanone oxime ligand and LNHpy is its conjugate base, led to the formation of a new class of organocobalt complexes of general formula [RCoIII(LNHpy)(HLNHpy)]-(ClO4) [R = Me (2a), Et (2b), CH2CF3 (2c), nBu (2d), and CH2Cl (2e)]. All the complexes were characterised by 1H and 13C NMR spectroscopy. The X-ray structures of 2a, 2b and 2c provide evidence for a pseudo-octahedral configuration, where HLNHpy and LNHpy act as bi- and tridentate ligands, respectively. The axial geometry in 2a is closer to that found in methylcobalamin than that reported for other models, suggesting steric and electronic cis influences of the equatorial ligands close to those of the corrin nucleus. The solution properties and the reactivity show strong analogies with those of the previously known Vitamin B12 models.
Catalytic Oxidation of Methane to Methanol initiated in a Gas Mixture of Hydrogen and Oxygen
Wang, Ye,Otsuka, Kiyoshi
, p. 2209 - 2210 (1994)
Selective oxidation of methane to methanol at atmospheric pressure has been achieved using a gas mixture of hydrogen and oxygen over iron phosphate catalyst at > 623 K.
Kinetics of the Reaction between Methoxyl Radicals and Hydrogen Atoms
Dobe, Sandor,Berces, Tibor,Szilagyi, Istvan
, p. 2331 - 2336 (1991)
The kinetics of the reaction of CH3O with H have been studied under pseudo-first-order conditions with an excess of H using an isothermal discharge-flow reactor.Three different CH3O sources were used and the decay of was monitored by laser-induced fluorescence (LIF) as a function of .A second-order rate coefficient of (2.0 +/- 0.6) x 1013 cm3 mol-1 s-1 was determined for reaction CH3O + H -> products at room temperature and a slight positive temperature dependence was observed between 298 and 490 K.Formaldehyde formation was found to be the dominant reaction path (81 +/- 12percent).Further identified products were OH (7 +/- 3percent) and methanol (a few percent) which were produced by the decomposition and stabilization, respectively, of the initially formed bound adduct.
44-Methylgambierone, a new gambierone analogue isolated from Gambierdiscus australes
Murray, J. Sam,Selwood, Andrew I.,Harwood, D. Tim,van Ginkel, Roel,Puddick, Jonathan,Rhodes, Lesley L.,Rise, Frode,Wilkins, Alistair L.
, p. 621 - 625 (2019)
A new analogue of gambierone, 44-methylgambierone, was isolated from the benthic dinoflagellate Gambierdiscus australes collected from Raoul Island (Rangitahua/Kermadec Islands). This molecule has been previously reported as maitotoxin-3. The structure of 44-methylgambierone was elucidated using 1D- and 2D-nuclear magnetic resonance spectroscopy and mass spectrometry techniques. The nine-ring polyether backbone (A–I) and functional groups (carbonyl, terminal diol, 1,3-diene and monosulphate) are the same for both compounds with the addition of an olefinic methyl group being the only modification in 44-methylgambierone.
Oxidation of triethanolamine by ceric ammonium sulfate in aqueous sulfuric acid: spectrophotometric kinetic and mechanistic study
Padhy, Ranjan Kumar,Sahu, Sarita
, p. 69 - 78 (2021/11/30)
Oxidation kinetics of triethanolamine by ceric ammonium sulfate in aqueous sulfuric acid has been studied spectrophotometrically in contexts of many physicochemical processes. Stoichiometry of the reaction is found to be 1:6. Contrary to the literature findings the reaction proceeds without the presence of any transition metals acting as catalysts. Oxidation kinetics shows unit order dependence on oxidant, Ce(IV) and substrate, triethanolamine as well. Complex, fractional inverse order dependence on [H+], unaltered rate in the presence of added products at the initial stage and inverse dependence on added salt, sodium bisulfate are the findings. With increase in the solvent polarity, rate of the reaction also increased. Activation and thermodynamic parameters are computed from the temperature dependence observations. Suitable kinetic model and explanations are provided considering all the findings with a proposal of formation of an activated complex of the type [Ce(IV)-triethanolamine]. Graphical abstract: [Figure not available: see fulltext.]
Method for preparing formaldehyde by photocatalytic oxidation of ethylene glycol
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Paragraph 0007; 0033-0080, (2021/05/26)
The invention provides a method for preparing formaldehyde from ethylene glycol by photocatalytic oxidation. According to the method, ethylene glycol is taken as a substrate, air or oxygen is taken asan oxygen source, and a C-C bond cracked product, namely, formaldehyde can be generated under illumination in presence of a catalyst. The conditions are mild, the oxidation efficiency and the productyield are high, and the air or the oxygen is taken as the oxygen source under the illumination condition, so that the method is economical, environmentally friendly and green, meets the strategy of sustainable developed energy and has broad application prospect.
Study on the selective oxidation of methane over highly dispersed molybdenum-incorporated KIT-6 catalysts
Chen, Pei,Fan, Xiaoqiang,Kong, Lian,Li, Jianmei,Liu, Baijun,Liu, Bonan,Xiao, Xia,Xie, Zean,Zhao, Zhen
, p. 4083 - 4097 (2021/06/30)
A series of molybdenum-incorporated mesoporous silica (Mo-KIT-6) catalysts were successfully synthesized by a one-pot hydrothermal synthesis method, and were applied in the selective oxidation of methane to formaldehyde using oxygen as an oxidizing agent under atmospheric pressure. Comparatively, the corresponding supported catalysts (Mo/KIT-6) were prepared by incipient-wetness-impregnation method. The results of the small angle XRD, nitrogen adsorption/desorption isotherms, UV-vis, H2-TPR and UV-Raman spectroscopy characterization combined with the catalytic activity tests demonstrated that molybdenum atoms were inserted into the framework of the mesoporous materials for the Mo-KIT-6 catalysts and the highly dispersed MoO bonds dominantly existed, which were responsible for the efficient selective formation of formaldehyde. However, for Mo/KIT-6 catalysts, the molybdenum oxide species were mainly loaded on the surface or inside the outer pore channels of the support and abundant emergence of the Mo-O-Mo bond played a major role in the activation of methane to COx. Furthermore, with equivalent molybdenum content, the methane selective oxidation performance of 8Mo-KIT-6 was obviously better than that of 4.6Mo/KIT-6, and the formaldehyde yield (2.1%) of 8Mo-KIT-6 was 2.3 times as much as that (0.9%) of 4.6Mo/KIT-6.In situandoperandoUV-Raman results demonstrated that the structures of the MoOxactive sites have a strong effect on the formation and elimination of carbon deposition during the separated redox reaction with methane and O2, respectively. The polymerized MoOxactive sites are favorable for the formation of graphitic carbon (G), which is called ordered carbon, while the isolated MoOxactive sites are favorable for the formation of disordered carbon (D). The reduced highly dispersed MoOxactive sites incorporated in the framework of silica are more easily reoxidized than those on the supported catalysts.