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| | tert-Butyl hydroperoxide Basic information |
| | tert-Butyl hydroperoxide Chemical Properties |
| Melting point | -2.8 °C | | Boiling point | 37 °C (15 mmHg) | | density | 0.937 g/mL at 20 °C | | vapor pressure | 62 mmHg at 45 °C | | refractive index | n20/D 1.403 | | Fp | 85 °F | | storage temp. | 2-8°C | | pka | pK1: 12.80 (25°C) | | form | Liquid | | color | Clear colorless | | PH | 4.3 | | Water Solubility | Miscible | | Merck | 14,1570 | | BRN | 1098280 | | Henry's Law Constant | 4.2×100 mol/(m3Pa) at 25℃, Wang et al. (2017) | | Exposure limits | No exposure limit is set. On the basis
of its irritant properties a ceiling limit of
1.2 mg/m3 (0.3 ppm) is recommended. | | Stability: | Stable, but may explode if heated under confinement. Decomposition may be accelerated by traces of metals, molecular sieve or other contaminants. Incompatible with reducing agents, combustible material, acids. | | InChI | 1S/C4H10O2/c1-4(2,3)6-5/h5H,1-3H3 | | InChIKey | CIHOLLKRGTVIJN-UHFFFAOYSA-N | | SMILES | CC(C)(C)OO | | LogP | 1.230 (est) | | CAS DataBase Reference | 75-91-2(CAS DataBase Reference) | | NIST Chemistry Reference | Tert-butyl hydroperoxide(75-91-2) | | EPA Substance Registry System | tert-Butyl hydroperoxide (75-91-2) |
| Hazard Codes | O,C,N,T | | Risk Statements | 7-10-20/21/22-34-65-52/53-43-67-53-68-51/53-23-21/22 | | Safety Statements | 14-3/7-61-45-36/37/39-24-17-16-14A-26-62-47-43 | | RIDADR | UN 3109 5.2 | | WGK Germany | 3 | | RTECS | EQ4900000 | | F | 3-21 | | Autoignition Temperature | Self-accelerating decomposition at 88 to 93 °C | | TSCA | TSCA listed | | HazardClass | 5.2 | | PackingGroup | II | | HS Code | 29094990 | | Storage Class | 5.2 - Organic peroxides and self-reacting hazardous materials | | Hazard Classifications | Acute Tox. 2 Inhalation
Acute Tox. 3 Dermal
Acute Tox. 4 Oral
Aquatic Acute 1
Aquatic Chronic 1
Asp. Tox. 1
Eye Dam. 1
Flam. Liq. 3
Muta. 2
Org. Perox. F
Skin Corr. 1C
Skin Sens. 1
STOT SE 3 | | Hazardous Substances Data | 75-91-2(Hazardous Substances Data) | | Toxicity | LD50 oral (rat) 406 mg/kg
LD50 skin (rabbit) 460 mg/kg
LC50 inhal (rat) 500 ppm (4 h) |
| | tert-Butyl hydroperoxide Usage And Synthesis |
| Chemical Properties | tert-Butyl hydroperoxide (TBHP) is a water-white liquid
commonly commercially available as a 70% solution in
water; 80% solutions are also available. It is used to initiate
polymerization reactions and in organic syntheses to introduce peroxy groups into the molecule. | | Uses | TBHP is an intermediate in the production of propylene
oxide and t-butyl alcohol from isobutane and propylene. It is
primarily used as an initiator and finishing catalyst in the
solution and emulsion polymerization methods for polystyrene
and polyacrylates. Other uses are for the polymerization
of vinyl chloride and vinyl acetate and as an oxidation
and sulfonation catalyst in bleaching and deodorizing operations.
It is a strong oxidant and reacts violently with
combustible and reducing materials, and metallic and sulfur
compounds. | | Uses | tert-Butyl hydroperoxide is used as an initiator for radical polymerization and in various oxidation process such as sharpless epoxidation. It is involved in osmium catalyzed vicinal hydroxylation of olefins under alkaline conditions. Furthermore, it is used in catalytic asymmetric oxidation of sulfides to sulfoxides using binaphthol as a chiral auxiliary and in the oxidation of dibenzothiophenes. It plays an important role for the introduction of peroxy groups in organic synthesis. | | Description | Tert-butyl hydroperoxide is an alkyl hydroperoxide in which the alkyl group is tert-butyl. It is widely used in a variety of oxidation processes. It has a role as an antibacterial agent and an oxidising agent. | | Application | tert-Butyl hydroperoxide (t-BOOH) decomposes under the catalysis of metal ions to form other alkoxy and peroxy radicals, thereby generating reactive oxygen species including hydrogen peroxide. This accelerates the chain reaction of lipid peroxidation, leading to DNA damage, cytotoxicity, and alterations in intracellular calcium homeostasis, ultimately causing cellular injury and apoptosis. In scientific research, t-BOOH is frequently employed to induce pharmacological oxidative stress responses and establish an oxidative stress model in cell cultures[3]. | | Production Methods | TBHP is produced by the liquid-phase reaction of isobutane
and molecular oxygen or by mixing equimolar amounts of
t-butyl alcohol and 30–50% hydrogen peroxide. TBHP can
also be prepared from t-butyl alcohol and 30% hydrogen
peroxide in the presence of sulfuric acid or by oxidation of
tert-butylmagnesium chloride. The manufacturing process of
TBHP is in a closed system. | | General Description | Watery odorless colorless liquid. Floats and mixes slowly with water. | | Reactivity Profile | Most alkyl monohydroperoxides are liquid. The explosivity of the lower members (e.g., methyl hydroperoxide, or possibly, traces of the dialkyl peroxides) decreasing with increasing chain length and branching [Bretherick 2nd ed. 1979 p. 10]. Though relatively stable, explosions have been caused by distillation to dryness [Milas, JACS 1946, 68, 205] or attempted distillation at atmospheric pressure [Castrantas 1965 p. 15]. | | Health Hazard | tert-Butyl hydroperoxide is a strong irritant.Floyd and Stockinger (1958) observed thatdirect cutaneous application in rats did notcause immediate discomfort, but the delayedaction was severe. The symptoms were erythemaand edema within 2–3 days. Exposureto 500 mg in 24 hours produced asevere effect on rabbit skin, while a rinse of150 mg/min was severe to eyes.
It is moderately toxic; the effects aresomewhat similar to those of MEK peroxide.Symptoms from oral administration in ratswere weakness, shivering, and prostration.
LD50 value, intraperitoneal (rats): 87 mg/kg
LD50 value, oral (rats): 406 mg/kg. | | Flammability and Explosibility | tert-Butyl hydroperoxide is a flammable liquid and a highly reactive oxidizing agent.
Pure TBHP is shock sensitive and may explode on heating. Carbon dioxide or dry
chemical extinguishers should be used for fires involving tert-butyl hydroperoxide. | | reaction suitability | reagent type: oxidant | | Mechanism of action | The general mechanism of transition metal-catalyzed oxidative Mannich reactions of N, N-dialkyl anilines with tert-butyl hydroperoxide (TBHP) as the oxidant consists of a rate-determining single electron transfer (SET) that is uniform from 4-methoxy- to 4-cyano-N, N-dimethylanilines. The tert-butylperoxy radical is the major oxidant in the rate-determining SET step that is followed by competing backward SET and irreversible heterolytic cleavage of the carbon–hydrogen bond at the α-position to nitrogen. A second SET completes the conversion of N, N-dimethylaniline to an iminium ion that is subsequently trapped by the nucleophilic solvent or the oxidant prior to the formation of the Mannich adduct[1].
Tert-butyl hydroperoxide could induce oxidative stress in liver mitochondria at low concentrations. The damaging effect of low concentrations of tBHP in the course of pyruvate oxidation in isolated liver mitochondria is caused by the opening of the nonspecific Ca2+-dependent cyclosporin A-sensitive pore in the inner mitochondrial membrane[2]. | | Safety Profile | Moderately toxic by
ingestion and inhalation. A severe skin and
eye irritant. Mutation data reported. At
highest dosage levels, symptoms noted were
severe depression, incoordmation, and
cyanosis. Death was due to respiratory
arrest. Very dangerous fire hazard when
exposed to heat or flame, or by spontaneous
chemical reaction such as with reducing
materials. Moderately explosive; may
explode during distillation. Violent reaction
with traces of acid. Concentrated solutions
may ignite spontaneously on contact with
molecular sieve. Mixtures with transition
metal salts may react vigorously and release
oxygen. Forms an unstable solution with
1,2-dichloroethane. To fight fire, use alcohol
foam, CO2, dry chemical. When heated to
decomposition it emits acrid smoke and
fumes. | | Carcinogenicity | A study performed to evaluate
the carcinogenicity of TBHP found it was not carcinogenic
when applied to the skin of mice at 16.6% of the peroxide 6
times a week for 45 weeks. However, if its application was
preceded by 0.05 mg of 4-nitroquinoline-1-oxide as a 0.25%
solution in benzene applied 20 times over 7 weeks followed
by TBHP (16.6% in benzene), then malignant skin tumors
appeared between days 390 and 405 of the experiment .
This supports the theory that peroxides are not complete
carcinogens, but may act as promoters . The effects of
TBHP on promotable and nonpromotable mouse epidermal
cell culture lines were reported by Muehlematter et al. . | | storage | tert-butyl hydroperoxide should be stored in the dark at room temperature
(do not refrigerate) separately from oxidizable compounds, flammable substances,
and acids. Reactions involving this substance should be carried out behind a safety
shield. | | Toxicity evaluation | TBHP accelerates oxidation of glutathione and decreases the
metabolism of sodium hexobarbital in rat livers and is a strong
oxidation agent. | | Incompatibilities | tert-Butyl hydroperoxide and concentrated aqueous solutions of TBHP react
violently with traces of acid and the salts of certain metals, including, in particular,
manganese, iron, and cobalt. Mixing anhydrous tert-butyl hydroperoxide with
organic and readily oxidized substances can cause ignition and explosion. TBHP can
initiate polymerization of certain olefins. | | Waste Disposal | Excess tert-butyl hydroperoxide and waste material containing this substance should be placed in an
appropriate container, clearly labeled, and handled according to your institution's waste disposal guidelines. | | References | [1] Maxim O, et al. Mechanistic Investigation of Oxidative Mannich Reaction with tert-Butyl Hydroperoxide. The Role of Transition Metal Salt. Journal of the American Chemical Society, 2013; 135: 1549–1557.
[2] Fedotcheva N, et al. Mechanism of induction of oxidative stress in liver mitochondria by low concentrations of tert-butyl hydroperoxide. Biochemistry (Moscow), 2013; 78: 75–79.
[3] MARIO ALÍA. Response of the antioxidant defense system to tert-butyl hydroperoxide and hydrogen peroxide in a human hepatoma cell line (HepG2)†[J]. Journal of Biochemical and Molecular Toxicology, 2005, 19 2: 119-128. DOI:10.1002/jbt.20061.
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| | tert-Butyl hydroperoxide Preparation Products And Raw materials |
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