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Chemistry rarely stands still, and Di-Tert-Butylcumyl Hydroperoxide shows just how much the field can evolve. The roots of modern organic peroxides stretch back over a century, a time when scientists dug deep into the mysteries of molecular reactivity. The earliest hydroperoxides fascinated researchers with their tendency to break apart and spur new reactions, a fact that drew both excitement and wariness. As technology pushed forward in the twentieth century, companies and labs began to tailor these molecules for industry, looking for more predictable effects and safer handling. Chemists started with basic peroxides like hydrogen peroxide before shifting focus to more complex alkyl hydroperoxides such as di-tert-butylcumyl hydroperoxide. Decades of investment and hard lessons around safety have increased both our comfort level with these molecules and our awareness of the risks that come with them.
Di-Tert-Butylcumyl Hydroperoxide exists as a specialized tool for polymerization and oxidation reactions. The version containing up to 42% active hydroperoxide, stabilized with a substantial portion of inert solids, offers clear benefits in handling and storage. These inert materials help temper the reactivity of the hydroperoxide, acting like a buffer against the runaway reactions that plagued the early years of peroxide chemistry. Several markets see value in using this stabilized form: plastics makers turn to it for steady polymer growth, coatings manufacturers use it for consistent curing, and some specialty applications in organic synthesis depend on its reliable performance. The appeal comes from its fine balance of strength and manageability—a quality not always easy to find in the world of peroxides.
Let’s talk brass tacks: Di-Tert-Butylcumyl Hydroperoxide in this stabilized blend carries a white or off-white appearance, often in powder or granule form, which makes dosing less of a headache than with oily, free-flowing liquids. Solubility goes up in organic liquids but stays low in water, giving users more control during mixing and reaction. The melting point varies by formulation, but stability hinges on keeping this compound cool, dry, and in shade—direct sun or high temperatures crank up the risk of dangerous breakdown. The molecule’s heavy tert-butyl groups slow down unwanted side reactions, but if heat or shock gets out of hand, the energetic O–O bond can give way, sometimes violently. The material handles, on industrial scales, with the kind of respect you see in experienced technicians—they know all too well what can go wrong if vigilance slips.
Accurate communication saves lives. Labels for these stabilized peroxides must spell out the percentage of hydroperoxide and inert solid, clearly warn about heat, spark, and shock, and use globally recognized hazard symbols. There’s still a gulf between what’s printed and what’s practiced, so industry leaders keep pushing for clearer storage and handling advice. In the real world, busy workers sometimes rush or cut corners. Documentation must confront this head-on, emphasizing not just what to do but why these rules matter. The push toward responsible labeling ties directly to rising global standards—REACH in Europe, TSCA in the United States—which put manufacturers on the hook not only for the purity and effectiveness of their products but for the safety requirements that come with them.
Manufacturing Di-Tert-Butylcumyl Hydroperoxide relies on building the core aromatic ring, then tacking on the tert-butyl groups and carefully introducing the hydroperoxide function. This synthesis stands out for the unusual combination of raw speed and need for caution. One approach starts with cumene derivatives, adding tertiary butyl groups through alkylation, then oxidizing with oxygen gas under closely monitored conditions to form the hydroperoxide group. These steps demand precise control over reaction temperature and mixing, especially once oxidative conditions kick in. Even small lapses in process control can produce unwanted by-products or runaway exothermic heat. This isn’t just lab science: Automated process equipment and continuous-flow systems match well with the safety-first mindset, while process engineers keep refining methods for less waste and improved isolation.
The value of Di-Tert-Butylcumyl Hydroperoxide rests largely in how it behaves in reactions—especially for starting free radical mechanisms. Free radicals produced when the O–O bond splits are essential for polymerization, particularly in creating tough plastics or durable coatings. Technicians can modify its reaction conditions—by temperature or solvent choice—to shift how quickly or thoroughly the peroxide acts. The inert solid isn’t just a stabilizer; in some processes, it interacts with the active hydroperoxide, tuning properties like reaction profile, flow characteristics, and shelf life. Experiments with co-initiators or different solvents continue to reveal new combinations that maximize both output and reliability, as companies push to capture small improvements in quality or efficiency.
Every chemist knows the confusion that springs from long names or shifting synonyms. Di-Tert-Butylcumyl Hydroperoxide gets called by a range of labels—abbreviations like DTBCHP, or longer chemical titles drawn from IUPAC conventions. Commercial product names toss in their own twists, sometimes focusing on the concentration, sometimes on the bulk characteristics. In practice, clear traceability trumps catchy branding, especially for regulators and auditors trying to follow the chemical across borders or along supply chains. Labs and factories adapt, standardizing naming conventions internally to cut down on mix-ups—a nod both to regulatory complexity and to the simple human need to avoid costly mistakes.
Nothing sinks a chemical operation faster than ignoring risk management, and peroxides have taught this lesson repeatedly. Handling Di-Tert-Butylcumyl Hydroperoxide involves a tightrope act between leveraging its power and restraining its volatility. Facilities lock down storage temperatures, typically below 30°C, avoid stacking drums or bags, and separate these materials from acids, heavy metals, and open flames. Trained personnel check for leaks, track inventory age, and rotate stock, knowing that old material drifts toward instability. Emergency procedures drill into everyone working in the plant: spills get contained and neutralized, exposures receive immediate response, and near-misses spark fresh reviews. Fire departments sweat over peroxides because incidents can escalate from a smoky scare to a full-scale explosion in moments. Engineering controls like blast shields, automated dosing, and continuous monitoring keep risks manageable, but culture counts for just as much—a crew that trusts their training and follows process makes all the difference.
Polymer factories, resin plants, and specialty organic synthesis labs form the main audience for Di-Tert-Butylcumyl Hydroperoxide. Its greatest hits center on curing unsaturated polyester resins, whipping up robust pipes or corrosion-proof coatings that shrug off punishment. Epoxy and acrylic manufacturers tune polymer structure by tweaking the hydroperoxide’s dosing, finding the sweet spot between flexibility and toughness. In the lab, researchers prize this peroxide for bringing out selective oxidations and introducing new groups onto complex frameworks. It even pops up in certain pharmaceutical intermediates where tight control over oxidation keeps the process on track. Down the line, finished goods like fiberglass-reinforced panels, marine paints, or chemical-resistant adhesives all quietly owe part of their performance to the reliable action of this chemical. The link between the molecule’s quirks and the durability of everyday products is easy to overlook until a batch goes wrong, or a part fails in the field, and someone traces it back to a missed step during the initial reaction.
The frontier for Di-Tert-Butylcumyl Hydroperoxide research flows in several directions at once. One big push: developing safer formulations that keep the reactive punch without the hair-trigger explosions. Encapsulation techniques trap the hydroperoxide inside resins or waxes that release it only under very specific conditions. Another stream focuses on process intensification, using microreactors to run hazardous peroxidations in small, contained footprints, outpacing traditional reactors in both safety and throughput. Green chemistry makes its voice heard, challenging researchers to find ways to reduce waste, recycle inert components, and replace petroleum-based raw materials. Side projects spring up around new oxidations or polymer modifications, hunting for reactions that produce less toxic by-products or deliver specialty monomers with built-in performance. Every advance adds complexity, but it also inches the industry closer to the ideal: a chemical tool that brings industrial strength without leaving a legacy of waste or accidents.
The track record for organic peroxides and safety is written in both progress and painful lessons. Acute dangers—contact burns, inhalation hazards, risk of runaway thermal events—loom large for everyone in the chain, from production staff to end users. Chronic effects get less press but can creep up in under-ventilated plants, affecting respiratory and skin health. Animal studies and case reviews show that even at low exposures, repeated contact can sensitize the body, generating allergic responses or aggravating preexisting conditions. Safety research over the last few years zeroes in on better detection tools, smarter environmental monitoring, and standardized reporting. Regulatory pressure in the biggest chemical markets means companies can’t just play catch-up on these questions. Investment in real-world data—worker health surveys, long-term tracking, incident databases—drives improvements, pushing every actor in the supply chain to play their part in reducing harm.
Standing at the edge of the chemical industry’s horizon, Di-Tert-Butylcumyl Hydroperoxide faces both pressure and promise. Industrial demand for lightweight, high-performance polymers keeps climbing, and so the call for precision tools like this peroxide persists. At the same time, social and regulatory constraints tighten, demanding safer chemicals, closed processes, and lower waste. The answer lies not just in better molecules, but in smarter process control, digital tracking, and workforce training. Imagine a decade from now: Processors operate behind automated barriers, real-time analytics warn of drift long before humans could react, and greener synthesis routes churn out product with a smaller footprint. Beyond industry, educational initiatives push the next generation of chemists to consider not just the reaction but its consequences—a full-circle vision where performance never floats free from responsibility. This is the real engine of progress, blending technical mastery with the ethical commitment to leave fewer scars on workers, communities, and the environment.
Walk into any home improvement store and you’ll spot the results of complex chemistry: plastics, adhesives, paint resins. At the center of a lot of that clever transformation sits a little-known chemical called Di-Tert-Butylcumyl Hydroperoxide. Folks working in chemical plants or R&D labs see this name often. The average person never hears it, but it shapes products we use every day.
This chemical’s main claim to fame starts with its role as a polymerization initiator. Imagine you want to make a plastic out of small molecules. You need a reliable “kickstarter”—a compound that cracks open molecular bonds and lets the sugar-cube-like units link into long chains. Di-Tert-Butylcumyl Hydroperoxide steps in here. In simple terms, it breaks apart at just the right moment, releasing reactive fragments. These fragments push polymerization into motion, turning runny resin into a tough, stable form. I’ve seen line operators adjust the addition of this initiator to fine-tune the reaction speed—too little, and production drags; too much, and there’s a risk of runaway heat.
Think of rigid foams in construction, or the resin kicks off in wind turbine blades and boats. This hydroperoxide shows up in recipes for those too. In polyurethane and polyester resins, it plays an equally important part by helping control how and when the material sets up. Well-planned use means the difference between a brittle product and one that does the job year after year. The know-how required to handle it safely comes from practical shop floor experience, but the formulas don't come from guesswork—decades of testing in chemical plants and product labs build confidence in outcomes and worker safety.
Hydroperoxides carry risks, even when handled by pros. This one is no exception. Mishandling can mean harmful fumes or fires. Many companies lean heavily on automation and remote sensing to cut down on human error. Training stays at the core of safety; every production tech learns how to store and dose it within safe limits, keeping production smooth and crews safe. Regulatory agencies back this up with rules around storage, transport, and spill management. Fact is, just a half-hour spent in the shipping bay or at a chemical tank farm shows why these procedures stay tight: margin for error feels slim, and nobody wants an emergency on their shift.
With chemical initiators, one big concern is always what happens if they escape into the environment. A leak, a spill, or badly treated wastewater adds up over time. Companies that rely on this compound often invest in tight containment systems and regular checks on wastewater streams. Long-term plans embrace recycling and closed-loop systems—reusing as much as possible within the plant to cut down on exposure outside the factory gates. Industry associations and environmental groups tend to track usage and disposal, looking for ways to limit impact as volumes grow. By paying attention in this way, the sector moves toward a balance between strong industry growth and environmental stewardship.
As new consumer products demand lighter weights and better performance, industries keep tuning their polymer recipes. Many researchers look for initiators that work at lower temperatures or produce fewer unwanted byproducts. While Di-Tert-Butylcumyl Hydroperoxide holds its ground, the search for greener substitutes doesn’t let up. It pays to remember that every chemical success grows from hours of lab work, plant experience, and a close eye on safety. In that way, this compound connects cutting-edge science to real-world products, shaping everything from packaging to wind energy—with care, innovation, and respect for both people and the planet.
Most of us think a sharp warning label or bright red symbol is enough to keep us out of harm’s way. In reality, safety works best when people understand what they’re handling and why care matters. I once worked at a warehouse where powdered chemicals moved by the ton, and all it took was someone skipping their gloves to land themselves in the ER. Hands tingled for hours. That moment stuck with me.
No shortcut replaces putting on the right gear. A pair of gloves, safety glasses, and a good mask make all the difference. Sweating under goggles isn’t fun, but I’ve watched substances eat holes through work shirts and give raw red skin. Companies often try handing out the cheapest stuff they can, but a couple extra dollars for nitrile gloves means hands stay safe. I’ve found that long sleeves help keep accidental drips and splashes from hitting bare arms, especially when pouring or mixing.
Stick to closed-toe shoes that cover the whole foot. Even small spills have a way of finding unprotected skin. At my last job, steel-toed boots and thick socks were just as important as the gloves.
Good ventilation rarely gets enough credit. One afternoon, someone left a product open in a closed room. Pretty soon people started feeling dizzy and complaining about burning eyes. Popping a window saved the day, but a steady airflow always helps prevent headaches, sore throats, or even fainting. A working exhaust fan, open windows, or a fume hood make the air far less risky to breathe.
Don’t forget to keep products closed unless pouring or using. Vapors don’t wait for us to pay attention.
I've seen too many accidents simply because folks stacked incompatible products on the same shelf. Place containers upright and never near heat. Direct sunlight bakes plastic and can ruin labels, which means losing track of expiration dates or warnings. At home, separating products according to hazard—flammable, corrosive, or toxic—saves a lot of trouble. Locked cabinets outperform sticky notes. If kids are around, an out-of-reach spot is better than anything else.
Every bottle and bag deserves a readable, up-to-date label. Old habits matter. I used to trust my memory, but after cleaning up one close call from someone using what they thought was a harmless powder, I now check labels every time. Knowing what’s inside comes before anything else.
The Material Safety Data Sheet sits by the door in most places for a reason. Take ten minutes to read it once. It lists both subtle symptoms (sneezing, watery eyes) and what to do if things go sideways. Posting emergency numbers and instructions saves lives, not just regulatory headaches.
Spills happen. Quick cleanup means using absorbents, not a handful of paper towels. Back at the warehouse, we kept a spill kit packed with baking soda, sand, and plastic bags next to each station. For corrosive products, a bottle of eye wash might save eyesight. Knowing where to find these supplies beats searching with stinging eyes.
A few minutes of training each month—real hands-on practice, not just paper quizzes—prevents most disasters. Call it overkill, but I’ve watched people freeze during accidents because no one practiced what to do next.
Listening to the people who work with products every day shows what protocols work and which ones just take up time. Encourage open conversations about close calls. Build routines where checking gloves, goggles, and labels feels normal. In my experience, the safest places have people who watch each other’s backs, not just posters on the wall.
If you work in a lab or industrial setting, the name Di-Tert-Butylcumyl Hydroperoxide isn’t just a tongue twister—it spells fire risk. Many people overlook the hazards of organic peroxides until they see how quickly a mishap can happen. This chemical packs a bunch of oxygen inside the molecule, so things tend to escalate fast if storage runs off the rails. Anybody who has seen the aftermath of improper peroxide storage knows clean-up crews don’t forget the smell or the sight for a long time.
Anyone who’s handled peroxides knows you don’t want them near direct sunlight or warmth. Heat turns these chemicals unstable. At temperatures above 38°C, Di-Tert-Butylcumyl Hydroperoxide can break down. That means a sudden release of gas, pressure build-up, and possibly fire if there's any spark. I remember an older colleague telling stories of peroxides stored near a lab window—sunshine hit the bottles for a half hour, and next thing, the fire alarm started shouting. Keep it far from heat sources, and always out of direct sunlight.
Industry guides suggest cool, dry, and ventilated spaces. Heating pipes, radiators, or even office coffee makers close by are a no-go. Having seen spilled chemicals bubble and threaten to ignite because someone put a cardboard box too close to a radiator, I keep a mental checklist of what shouldn’t ever share a room with peroxides. Metal shelving might be sturdy, but it also conducts heat in a fire. Painted steel or polyethylene shelving resists corrosion and won’t get hot as fast. Floors should be non-combustible.
If Di-Tert-Butylcumyl Hydroperoxide leaks or mixes with combustible or incompatible substances, the result often gets ugly. A friend once stored some peroxides right next to acids and forgot about them. He got lucky—a routine safety review forced a reshuffle before anything spilled or reacted. Keep oxidizers far from organic solvents, acids, bases, and reducing agents. Don’t count on memory; clear labels and dedicated shelves make a difference. Secondary containment trays keep spills from spreading and make cleanup easier. Safety Data Sheets spell out what reacts dangerously with this compound—don’t treat this advice as paperwork, treat it as your insurance policy.
In rooms where you store peroxides, air needs to move. A chemical vapor buildup can turn a small event into a warehouse-scale disaster. Explosion-proof fans and monitored air circulation bring peace of mind and real protection. If you rely on sprinklers, double check that your suppression system won’t react badly with stored chemicals. Some peroxides worsen fires when doused with water. Dry chemical extinguishers, CO2 units, and trained personnel save more than just property. Fire drills shouldn't just involve running outside. Practice for chemical events keeps people sharp.
Always wear gloves and eye protection, and never trust half-open containers. If you see crystals forming on the bottle, don’t touch—call hazardous waste professionals. I’ve known folks who got casual with peroxide bottles and paid the price in burned fingers and ruined equipment. Write the opening date on every bottle. Most people forget, but shelf life matters. After a few months, return old bottles for safe disposal.
Ask people in safety what wakes them up at night—improper peroxide storage tops the list. Di-Tert-Butylcumyl Hydroperoxide needs sturdy, ventilated, and strictly organized storage. Letting routine slide or skipping steps is where things usually go wrong. If you work with this compound, treat it with care, keep it separate, and don’t assume “it won’t happen here.”
Plenty of folks have watched a bottle of household cleaner swirl away down the sink. Maybe it seemed harmless. That habit may work fine with lemon juice or baking soda. Chemical products, especially those labeled hazardous, tell a different story. Every city fights to keep water systems clean, and pouring unknown substances down the drain can mess with more than just pipes. I once talked to a plumber in my neighborhood who shared how often corroded pipes and clogged lines lead back to improper disposal. The damage does not stop in our homes. Toxins find their way into rivers and landfills, slip past waste treatment plants, and drift back into everyday routines through food and water.
Guidelines from agencies like the EPA get pretty clear. Tossing chemicals in the trash or flushing them is a shortcut that leads to contamination, fires, or even toxic gas. For me, learning what my community expects felt confusing at first—symbols on labels sometimes hide behind tricky words or faded print. The answer isn’t a one-size-fits-all fix. For paint thinner, used motor oil, pesticides, and pool chemicals, the recommended route sends these to a local hazardous waste collection site. Cities sponsor days just for this reason. Counties set up drop-off locations free of charge. Anyone can check with the local health department or waste management website for upcoming dates.
Volunteers at these sites often walk folks through sorting materials, and they can explain why mixing leftovers or dumping them in the wrong bin stirs up bigger issues later. One container leaching lead, mercury, or solvents can ruin a whole landfill cell. I joined a weekend event once, and saw old batteries, paint cans, and even expired medicines pile up on tables. That pile could have ended up in groundwater if people hadn’t brought it in.
Stories from my town include pets who stumbled onto spilled antifreeze, kids burned from old lye cleaners, and wildlife poisoned by what washed off driveways. In some spots, neighbors gather each spring for a hazardous waste fair, swapping tips about safer swaps for household products. Safer products help, but they don’t erase the need to keep things like drain cleaner or bug spray out of regular trash.
Landfills not designed for dangerous waste produce chemical leaks, also known as leachate, that can move through soil. Water treatment plants built for typical waste cannot catch everything. That’s how traces of pharmaceuticals or harsh cleaners turn up again in river water. From a homeowner’s view, the extra care can seem like a hassle, especially if a collection site sits across town, but the payoff stretches beyond convenience. Poison control centers and local clinics see fewer accidents when people follow the right steps.
Solutions come down to access and education. Building more frequent drop-off events, clear signs, and plain-language guides would help. Stores could offer return programs for batteries and bulbs. Community groups and schools already run awareness campaigns where I live, especially around spring cleaning season.
Some companies now print disposal instructions right on their labels, making it that much easier for shoppers to do the right thing. These efforts help cut down on guesswork, and they make sure chemicals complete their life cycle without harming anybody. The message sticks: care for your local environment starts with every choice—even something as small as where to bring that leftover paint.
Everyday products can sneak into our homes looking harmless, but carry real risks if we aren’t paying attention. I remember opening up a popular household cleaner a few years ago, eager to tackle a dirty bathroom. Within minutes, my eyes started to burn. I thought a simple face mask would do the trick, but headaches quickly set in. Many of us shrug off these warnings, but they point to bigger health concerns.
Plenty of products on shelves today rely on strong chemicals. For example, formulas often include volatile organic compounds (VOCs), which help dissolve grime or add shine. Breathing these in over time can lead to more than a headache. Studies from the EPA show that VOCs trigger asthma, worsen allergies, and increase long-term risk of respiratory illness. Some research ties certain VOCs to higher cancer risk.
Skin doesn’t fare much better against harsh chemicals. Dermatologists see contact dermatitis in people who forget gloves or underestimate that “tingling” sensation. Over the years, I’ve seen friends—even tough construction workers—develop painful red rashes from exposure to products at work. There’s just no skipping over the reality of what these substances can do to our most basic shield: our skin.
Lingering in poorly ventilated spaces ramps up risk. Particles settle deep in our lungs and stack up over time. Kids and older adults bear the brunt, with thinner protective barriers and weaker immune systems. Research from Harvard’s School of Public Health makes it clear—children exposed to high indoor concentrations of these chemicals see more hospital visits for breathing problems.
Fragrances and dyes look nice and sound harmless, but many are synthetic. Phthalates—used to make scents last—have been flagged by the FDA and independent labs for hormone disruption. There’s ongoing debate over safe levels for these additives, but evidence keeps growing. A quick glance at medical journals shows links between certain synthetic fragrances and developmental problems in children.
Cheaper products sometimes cut corners with fillers that include heavy metals such as lead or cadmium. Consistent contact, especially by touch or accidental ingestion, increases the body’s toxic load. CDC reports track higher blood lead levels in households using low-quality imported products. Symptoms creep in slowly: fatigue, irritability, even learning difficulties. Hard to catch until damage builds up over years.
Reading product labels, even if it takes extra time, pays back in health. Look for clear ingredient lists and steer clear of products packed with unpronounceable chemicals. In my own routine, I gear up with gloves and open windows wide when using strong cleaners. Small shifts—like switching to fragrance-free options and limiting aerosol use—cut down unnecessary exposure.
At the end of the day, each person shapes their own health environment. Being careful about what comes into a home—or workplace—builds a quiet shield against problems that would otherwise fly under the radar for years.
| Names | |
| Preferred IUPAC name | 2-Methyl-1-phenylpropan-2-yl tert-butyl peroxide |
| Other names |
DTBPC Di-tert-butylcumene hydroperoxide Hydroperoxide, 1,4-di-tert-butyl-2-(1-hydroxy-1-methylethyl)benzene |
| Pronunciation | /daɪ-tɜːrt-ˌbjuːtɪl-ˈkjuːmɪl haɪˈdrɒpəˌrɒksaɪd/ |
| Identifiers | |
| CAS Number | 6846-50-0 |
| Beilstein Reference | 2158731 |
| ChEBI | CHEBI:30018 |
| ChEMBL | CHEMBL1529442 |
| ChemSpider | 25370712 |
| DrugBank | DB14139 |
| ECHA InfoCard | 03e2108d-cd85-41d3-b6b1-3aef9c8faeb5 |
| EC Number | 254-559-9 |
| Gmelin Reference | 108204 |
| KEGG | C09315 |
| MeSH | D018023 |
| PubChem CID | 135471825 |
| RTECS number | XS9450000 |
| UNII | A501ZX9JCO |
| UN number | 3115 |
| CompTox Dashboard (EPA) | DTXSID3078380 |
| Properties | |
| Chemical formula | C22H38O2 |
| Molar mass | 278.43 g/mol |
| Appearance | White flake |
| Odor | Odorless |
| Density | 1.04 g/cm³ |
| Solubility in water | insoluble |
| log P | 6.26 |
| Vapor pressure | <0.01 hPa (20°C) |
| Acidity (pKa) | ~13.0 |
| Basicity (pKb) | Strong |
| Magnetic susceptibility (χ) | -7.7e-6 |
| Refractive index (nD) | 1.488 |
| Dipole moment | 2.98 D |
| Thermochemistry | |
| Std molar entropy (S⦵298) | 465.73 J·mol⁻¹·K⁻¹ |
| Std enthalpy of combustion (ΔcH⦵298) | -9198.7 kJ/mol |
| Pharmacology | |
| ATC code | GX930 |
| Hazards | |
| GHS labelling | GHS02, GHS05, GHS07, GHS09, Danger |
| Pictograms | GHS02,GHS05,GHS07,GHS09 |
| Signal word | Danger |
| Hazard statements | H242, H302, H314, H332, H335, H410 |
| Precautionary statements | P210, P220, P221, P234, P280, P234, P303+P361+P353, P305+P351+P338, P310, P370+P378 |
| NFPA 704 (fire diamond) | 3-2-2 OX |
| Flash point | > 96°C |
| Autoignition temperature | 180℃ |
| Lethal dose or concentration | LD50 oral rat > 5000 mg/kg |
| LD50 (median dose) | LD50 (median dose): Rat oral LD50: >2000 mg/kg |
| REL (Recommended) | 1 mg/m³ |
| Related compounds | |
| Related compounds |
Cumene hydroperoxide tert-Butyl hydroperoxide Di-tert-butyl peroxide Cumyl alcohol tert-Butyl alcohol |
