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Looking back, the journey of titanium trichloride mixture is not the usual tale of slow discovery and gradual application. Early chemists struggled to tease pure titanium from its stubborn ores, but by the late 1800s, the world started to recognize the punch this transition metal could pack. Titanium trichloride earned its keep as people looked for ways to reduce titanium tetrachloride, chase after pure metal, and bring new colors to industry. As more labs and factories popped up through the industrial revolution, the relentless push for lighter, stronger, more corrosion-resistant materials brought titanium and its chlorides into the spotlight. Before long, the mixture became more than a laboratory curiosity—it started powering real discoveries, from synthetic rubbers to the catalysts that fuel modern chemistry’s engines. The chemical never grew into a household name, but anyone paying attention to specialty manufacturing knows at least a little of its story.
You won’t often find titanium trichloride mixture behind a glass counter, but in industrial settings and research labs, demand has always been steady. Its reputation isn’t built on flash; people care about it because the chemistry works. This compound comes as a bluish-violet, moisture-sensitive solid. Not every process can handle it, but for those that can, it opens doors. Titanyl salts don’t stand alone—the trichloride mixture brings allies, often completed by titanium dichloride or tetrachloride in strategic blends that fit tightly controlled processes. These subtle tweaks let technicians hit exact reaction rates and selectivity targets. It’s the backbone for certain polymerizations and plays key roles in producing high-purity silicon, aluminum, and even fuel additives. Year after year, the chemical sits on procurement sheets for companies chasing more efficient, cleaner methods—there’s always another use lurking just ahead.
Get close to titanium trichloride mixture and you’ll see why labs treat it with respect. This stuff lights up with a shiny, violet-blue color, shifting easily to green with the smallest slip—a hint of its readiness to react. The powder or crystalline form gives off potent fumes in moist air and snaps to attention when water touches it. Hydrolysis shatters it fast, breaking it down into titanium dioxide and hydrochloric acid with a fizz and a pungent smell that nobody forgets. It behaves as a strong Lewis acid, snatching up ligands with enthusiasm and sparking redox chemistry when combined with active metals or hydrogen donors. Despite its activity, chemists prize it for its reliable stoichiometry—you know what you’ll get if you handle it right. Not every property is a friend, though. High reactivity means mishandling leads to burns or worse, and improper storage creates real risk. Safety-conscious labs invest heavily in climate controls and air-free glove boxes just to keep things stable.
There’s no sweating the small stuff with titanium trichloride mixture. Producers list clear grades and standards to keep buyers happy: content percentage of trichloride, impurity thresholds, and compatible diluent types. Where purity hits certain thresholds, the mixture commands higher prices, especially in catalytic or electronic applications. You won’t find lazy labeling here. Each batch carries hazard warnings, reactivity notes, and storage conditions—no room for shortcuts. Regulators like OSHA and the European Chemicals Agency draw bright lines around handling and transport, meaning every drum gets tracked, signed, and sealed with more paperwork than almost any basic chemical. Even so, companies sometimes run into gray areas around international transit and disposal, since rules shift fast as new research reveals just how reactive or persistent the mixture can be.
Getting from raw titanium to titanium trichloride mixture is a classic chemical hustle. Most operations rely on direct chlorination: feed titanium dioxide or scraps of the metal to a stream of chlorine gas in the glowing belly of a furnace. You tune temperature, feed ratios, and contact time if you want that deep violet trichloride as opposed to paler tetras or dichlorides that muddy the product. The process chews up energy and spits out hydrogen chloride fumes, so big plants have to invest in sturdy containment and vapor capture hardware. Recovery and recycling matter here, with many firms looping spent chlorine and scavenged byproducts back through the reactor. Folks in the lab sometimes go old school, using organochlorine compounds or reducing agents like aluminum to grab precise blends for research tasks. Waste streams can be gnarly, with halogenated tars and acidic residues demanding full-time attention from waste managers.
Titanium trichloride mixture rarely stays the same for long. In catalytic action, it teams up with alkyl aluminum compounds during polymerizations, flipping from Lewis acidity to redox wizardry in a single step. Even dilute solutions in organic solvents like toluene or dichloromethane spark new compounds, often shifting colors and driving reactions deeper than anyone expected. Chemists modify the mixture by controlling ligands or adding co-catalysts, tuning reactivity for specialty plastics and some of the world’s longest-chain polymers. Some labs even tweak the mix for surface coating applications, laying thin titanium-rich films on glass or metal to boost durability or tweak conductivity. Every successful reaction here tricks out more value from the same base building blocks—it’s about coaxing just a bit more utility from a well-trodden formula. Reductive carboxylations, alkene metathesis, and cross-coupling chemistry all draw from its well, pushing the cutting edge a little further.
Chemists have a habit of gathering aliases, and titanium trichloride mixture is no stranger to the club. People call it TiCl3 mix, violet titanium chloride, or just “blue chloride” among in-house teams. In catalogues, you’ll see product numbers linked to grades and descriptors like “reduced titanium chloride” depending on the blend, with specialty names peppered through academic and patent literature. Despite the fancy labels, all versions track back to the same core chemistry—highly reactive, moisture-wary, and loaded with catalytic potential. Synonyms matter most in purchasing cycles; the wrong choice can trip up an entire project or send a batch out of spec.
Handling titanium trichloride mixture never leaves room for half-measures. Storage calls for dry boxes, nitrogen blankets, and well-trained operators armored with gloves, goggles, and suits. Watch an experienced chemical handler at work, and you’ll see a ballet of careful movements: open only under inert gas, keep containers sealed, and salt away fire suppression gear where spills might happen. Direct skin contact brings real pain, so eyewash stations and emergency scrubbers sit close. Air monitoring helps catch vapor leaks before they trigger alarms or evacuations, and spill drills are just part of the job. Disposal partners with regulatory oversight to revisit standards every few years, because as environmental data rolls in, the industry keeps shifting protocols. Nobody pretends all the risks can be erased, but most large outfits recognize that cutting corners means inviting trouble, lawsuits, or accidents with headlines nobody wants to read.
Most people outside specialty chemistry miss just how much of modern manufacturing leans on titanium trichloride mixture. In the polymer industry, it launched the age of Ziegler-Natta catalysts—unlocking routes to polyolefins that now line shelves, wire insulation, and food packages across the globe. Its fingerprint turns up in oligo- and polysilicon production, fine-tuning crystal growth for semiconductors and solar panels. Some aluminum purifiers depend on these mixtures to strip out trace contaminants, giving metals a longer, stronger service life. In some fuel systems, chemists use the trichloride to generate unique organic intermediates, jumpstarting pharmaceutical syntheses or specialty coatings. For each high-profile use, another dozen fly under the radar: battery research, corrosion-resistant paints, and energy sector breakthroughs. Its magic always rests on a tightrope—the power of being almost too reactive, tightly leashed and coaxed into building the stuff of modern life.
Ask around at tech and industrial expos, and someone’s always pitching “the next big thing” involving titanium trichloride mixture. Labs hunt up new ligands, eco-friendlier co-catalysts, and hybrid catalyst beds almost nonstop. Research tries to push efficiency—lowering the toll exacted by waste heat, energy loss, and hazardous byproducts. Especially in green chemistry circles, people keep swapping out hydrocarbon solvents and chasing milder operating conditions. Additive manufacturing, thin film deposition, and nanoparticle synthesis all look for sharper, less wasteful reactions, and the trichloride mixture keeps earning its place in toolkits. Every new breakthrough hits a wall called “scalability”—bench tricks don’t always survive the leap to production lines. Still, every successful pilot or new market launch carries traces of that old violet solid, passed down from bench to plant, always with new adjustments built on past data.
Nobody ignores the real risks here. Animal studies and historical reports point to acute hazards: severe irritation to eyes, skin, and lungs, with long-term exposure linked to more severe outcomes. Workers in legacy plants sometimes report chronic coughs, skin issues, or sensitivity, with regulators steadily tightening workplace limits. Labs try to pin down the exact mechanisms, testing how quickly it hydrolyzes and what toxic breakdowns can slip through in accident scenarios. Spill containment and cleanup plans got tighter as new data emerged, forcing companies to move fast or face major liability. Environmental persistence doesn’t usually rival heavy organics, but fresh regulatory frameworks keep squeezing the room for error. Personal experience shows that following tight protocols matters: cuts heal, equipment gets replaced, but dangerously cut corners always come back as lessons learned the hard way.
The world keeps shifting, and titanium trichloride mixture faces both challenge and opportunity. Growing demand for clean polymers and next-generation electronics ties fortunes to the pace of R&D. Green chemistry calls out for safer, smarter, more recyclable catalysts, and the companies that figure out how to get the most from titanium trichloride without piling up waste will lead the charge. Some see chances in medical technology: tailored coatings for implants or new reactions to build smart drug carriers. Cost pressures drive some research, but more often it’s regulatory and sustainability goals lighting the way. Renewable energy sectors, especially solar and battery technology, stand ready to absorb better titanium-based catalysts, with a growing need to prove each new process meets tight environmental expectations. The story of titanium trichloride mixture isn’t over yet. With the right push, that old violet powder could carve new paths in industries we haven’t even imagined.
Titanium trichloride mixture isn’t something the average person keeps on their radar, but it plays a key role in some industries that touch daily life. In my career, I’ve come across the stuff mostly in the context of chemistry labs and manufacturing plants. It’s this deep purple solution that packs a punch in how it interacts with other chemicals, particularly for those making plastics and specialty materials. For anyone working in industry or environmental science, understanding where this mixture slots in can help shed light on the products we all depend on.
In the world of plastics, titanium trichloride mixture is a key catalyst for producing polypropylene. This plastic shows up everywhere — food packaging, textiles, car parts, even medical devices. The manufacturers rely on this mixture for its ability to trigger a reaction that links tiny propylene molecules together, building the long chains that form this tough, flexible material. Polypropylene has changed how we store food and build safer, lighter vehicles, all thanks to that behind-the-scenes chemistry.
The process is hardly small-scale, and with the global demand for polypropylene rising every year, companies keep their sources of titanium trichloride locked down tight. Efficient use matters: cutting waste during catalyst reactions keeps costs down and limits chemical pollution.
Chemists often use this mixture as a reducing agent in their toolkits. Sometimes in pharmaceutical research or material science, they want to strip away oxygen atoms or start reactions that need a lot of push. My experience in the lab taught me to be careful with it — it can react dramatically with air and moisture. Safeguarding workers and maintaining quality rests on solid training and up-to-date equipment.
Beyond labs, it pops up in specialty metallurgy. Certain alloys gain unique features when produced with help from titanium trichloride mixtures, such as improved strength or resistance to corrosion. So, from plane engines to complex electronics, a lot rides on getting this chemistry right.
As with many industrial chemicals, titanium trichloride mixture has a dark side — it’s hazardous if handled the wrong way. A spill or leak can mean health risks for workers and air or water contamination in the community. I remember how plant safety drills focus on preventing exposure because a misstep can lead to burns or long-term harm. That’s why strict handling protocols and protective equipment see daily use in environments where this compound is prepared or reacts.
Environmental responsibility takes center stage today. Companies keep investing in better containment, recycling unused chemicals, and switching to cleaner technologies. Regulators push hard for regular audits and emissions tracking, and workers keep getting fresh training to spot and stop problems before they spread.
My time in industry taught me not to take these invisible helpers for granted. The balance between powerful chemistry and real risks shapes daily decision-making. With stronger safety measures and cleaner processes, titanium trichloride mixture can keep powering the stuff we count on — without putting people or the planet in harm’s way.
Titanium trichloride doesn’t belong anywhere near careless hands. I learned early in my lab days that this stuff can be mean. Its vapors attack moist skin, the throat, eyes and even lungs in seconds. The mixture often gives off hydrogen chloride, which means you’re basically one slip away from breathing in acid or landing in the hospital with a nasty skin burn. I keep those facts in mind every time I see a shipment arrive or hear a tech talk about scaling up a process.
Splash-proof goggles matter more than a fancy smock. Stubborn redness in my eyes after a lazy glove-and-glasses routine taught me quick—tight-fitting chemical goggles or even a face shield are the minimum. Gloves should be thick nitrile or neoprene, never old latex. That slick, garlicy odor means vapors are leaking somewhere, so I double-check for any exposed wrists and fasten my sleeves snug under glove cuffs. Long sleeves and actual chemical lab coats give an extra layer of security, because even a pinhole splash burns through cheap cotton.
Bad ventilation kills quick in this field. I push all my work with titanium trichloride under a fume hood—fully functional, airflow checked with a strip of paper before starting. No open bottles outside that hood, ever. I watched a friend struggle for breath after he worked in a stuffy corner where the ductwork hadn’t been cleaned in months. Permanent damage, just for the sake of being in a rush. Good airflow pulls those acid vapors away before they can do harm.
I never leave spills for “later.” Even the smallest drop can react hard with water and fill a room with choking clouds. Spill kits with absorbent material and neutralizers should always stand ready nearby. If a mix hits the bench or floor, I throw on thicker gloves and a respirator, scoop up the spill with absorbent pads, and follow with a special neutralizer that works on both trichlorides and hydrochloric acid. No shortcuts, no improvising with paper towels and wishful thinking. It’s too easy to let fumes slip up your nose or settle on the skin if you try to cut corners.
Sealed bottles go in locked cabinets, nowhere near water or damp air. Titanium trichloride hates moisture, and any contact can set off a reaction. Years back, a mislabeled bottle wound up next to the emergency eyewash in my old workplace. The mixture corroded through, leaked with a hiss, and we had to clear the building for hours while fire crews mopped up. Now, I label everything twice, check seals before I lock things away, and always store acids separately from bases and combustibles.
Working with dangerous chemicals should never turn into guesswork. Refresher training goes beyond generic videos—the best labs run hands-on drills, with staff practicing how to use eyewash stations, showers, and spill kits until it becomes muscle memory. Quick action makes all the difference if something goes sideways. In my experience, printed emergency instructions near the hazard area, not buried in a folder, save minutes in a crisis. Emergency contacts, clear signage, and easy-to-find first aid gear offer layers of real protection.
People get comfortable, start skipping steps, and think nothing will happen. The truth with titanium trichloride is, the margin for error shrinks with every shortcut. I remind my coworkers—and myself—that safety routines come from lessons paid for in scars, ruined equipment, and worse. Protecting yourself isn’t paranoid. It’s respect: for the risks, for your coworkers, for the science, and for your own future.
Titanium trichloride mixture falls under a tough group of chemicals. Just a whiff of the sharp, choking fumes will send most people running for the exit. I’ve seen crews in chemical plants treating it with nothing less than deep respect, and for good reason. If containers leak or catch some stray water, the result isn’t just a ruined batch. You get clouds of hydrochloric acid gas and intense heat. Burns, coughs, and hazardous environments pile up in seconds. Local fire departments train for situations like this, and it can shut down entire blocks. Keeping this compound under control helps protect workers, property, and the neighborhood outside the fence.
A responsible facility rarely leaves storage details to chance. Stainless steel drums or carbon steel tanks lined with material that resists strong acid usually get the nod for titanium trichloride. Someone might try plastic for other chemicals, but this one punches through most plastics after a while. Any hint of water around storage spaces means trouble. I’ve seen small spills on concrete start hissing because dew from a pipe overhead dripped onto the floor. That’s how easily water triggers a reaction. So dry, tightly-sealed containers stay top priority.
Ventilation can’t become an afterthought. Fumes from this mixture corrode electronics and harm lungs. Last year, one site I checked forgot to replace a faulty vent in a tank room. Within a week, the overhead lighting showed rust, and the workers started complaining about sore throats. Negative pressure systems keep vapors away from people and sensitive equipment. Without proper airflow, even a seemingly minor leak escalates into a full shutdown.
You walk into an industrial worksite, and every drum looks the same shade of grey, black, or blue under harsh warehouse lights. Titanium trichloride mixture needs unmistakable labels. Hazmat decals, unique paint, and clear warnings in more than one language all matter. It only takes a moment of confusion for someone new on the job to reach for the wrong barrel, and the fallout can fill an emergency room. Proper training cuts down on mistakes, but labels carry their own weight, especially during shift changes or in emergency drills.
I always encourage plant operators to keep spill kits and neutralizing agents within arm’s reach, not three hallways away in some obscure locker. A bag of dry sand — not sawdust, which titanium trichloride eats — stops a small leak from spreading. Workers stay safer when practical barriers surround the storage site. Catch basins with solid lips and strong warning signs force people to slow down before entering the area.
I’ve met a handful of managers who rely on locked isolation rooms and storage away from doors and windows. That buys critical time if an accident happens. Scheduled inspections are more useful than one-off checks, especially after heavy rains, freezes, or plant shutdowns. Corrosion sneaks up if you lose track of maintenance for even a month. Some places tap into electronic sensors that detect leaks or pressure spikes — worth every cent if they catch a problem early.
Above all, teamwork stands out. Supervisors who invest in routine training and encourage open reporting of little leaks avoid disasters. Creating an environment where every worker feels empowered to pull the plug on unsafe conditions pays off in years, not just one audit cycle. The storage of titanium trichloride mixture doesn’t belong in a forgotten corner. Mistakes can be costly, but regular attention and smart planning keep everyone safer.
Mention titanium trichloride to anyone in the field of chemistry or industrial processing and the first reaction is often curiosity about its real makeup. Most folks expect pure TiCl3, but mixtures sold under this name usually aren't just one compound. Commercial titanium trichloride mixture typically contains more than one chemical species—mainly TiCl3 and TiCl2, with a variety of accompanying impurities—shaped by both manufacturing choices and storage practices.
The bulk of titanium trichloride mixture includes TiCl3, a violet-blue crystalline solid known for its use as a catalyst component and as a reducing agent. It doesn’t stand alone. TiCl2 often joins the party, forming during reduction of titanium tetrachloride, which is the precursor for most commercial trichloride. Depending on batch and source, these mixtures wind up containing about 93-97% TiCl3, with 3–7% as TiCl2. Sometimes there’s a hint of TiCl4 left over as well.
A few years ago, I handled one of these mixtures in a research lab. We had a commercial batch—supposedly high-purity titanium trichloride—but analysis by X-ray diffraction showed a strong signal for TiCl2. The supplier’s own data sheet confirmed about 5% TiCl2, along with traces of TiCl4. Breathing this stuff isn’t smart, as TiCl3 and TiCl4 react sharply with water vapor to throw off hydrochloric acid fumes—something that became obvious after my co-worker left a vial open just a bit too long. This highlight’s why understanding what you’re really buying matters, not just for chemists but for anyone working in production settings.
Elemental analysis and practical experience both reveal why knowing the mixture’s chemical composition matters. The main ingredient, titanium trichloride, runs at about 154.23 g/mol molecular weight. TiCl2 clocks in lower. Both chlorides deliver strong reducing power and play key roles in processes from polypropylene production to specialty organic synthesis. But side products like TiCl4 can lead to handling hazards, toxic exposure, and inconsistent performance in sensitive catalytic reactions—a fact well documented in both safety bulletins and journal literature.
Heavy metals and traces of iron, nickel, or even vanadium occasionally sneak into these mixtures during industrial processing of titanium ore. These impurities may skew results in research settings or poison catalysts in large-scale setups. Some published studies show that even parts-per-million levels of iron can reduce polymerization yields or alter the end-product’s texture or color.
Control starts with informed sourcing and transparency from suppliers. Every lot benefits from a detailed certificate of analysis showing not just percentages of TiCl3 and TiCl2, but also the presence of TiCl4 and heavy metal traces. Labs that need just TiCl3 should validate purity before use. In some cases, fresh synthesis by careful reduction of TiCl4 with hydrogen or aluminum lets users dodge batch-to-batch surprises.
Handling these mixtures safely requires serious respect for their tendency to hydrolyze. Good ventilation, sealed containers, and personal protective equipment aren’t up for debate—especially in humid places. Waste disposal must avoid mixing with water to prevent hydrochloric acid leaks; neutralizing agents or specialized waste streams offer safer options.
The short answer: Commercial titanium trichloride mixture rarely contains just one compound. It’s a blend—useful, reactive, and a little demanding of respect and diligence from everyone who encounters it.
Titanium trichloride comes up often in the chemical and manufacturing world, especially in catalyst production and metal treatments. Anyone who’s spent time around industrial sites will recognize the heavy focus on safety. The mix isn’t something you’ll find in your home, but people get curious about the risks, especially because unfamiliar words make chemicals sound distant and mysterious. The everyday worker has a straightforward concern: “Is this stuff going to hurt me?”
Titanium trichloride itself isn’t something you want in your lungs, eyes, or on your skin. The compound reacts strongly with water to release hydrochloric acid fumes. Breathing those can cause a burning sensation, coughing, and in some cases, lung damage if you don’t get out of the cloud soon. The liquid splashed onto skin may leave burns or irritation — even a quick spill will show how reactive it feels.
Government safety agencies like OSHA and NIOSH treat titanium trichloride with respect. Exposure limits remain tight. Workers have to wear goggles and gloves; companies set up ventilation and keep showers nearby for emergencies. Even people who feel comfortable around chemical tanks won’t get careless with this mixture.
It doesn’t stop with emergency rooms. Some studies suggest longer exposures can trigger chronic problems in the airways. Anyone with asthma could have a rough time in a poorly ventilated room holding this compound. Burning in the throat, coughing, or chronic wheezing can become a daily reality if the job ignores proper protection.
Personal safety starts with workers, but then spills over — literally — into environmental health. A titanium trichloride leak doesn’t stay put. The chemical reacts with water instantly, churning out vapors that affect animals and humans alike. Rivers, streams, and the soil nearby all face risk if spills go unreported or mishandled. Local authorities might order evacuations or temporary closures for big accidents. I’ve seen neighborhoods brought to a standstill while teams neutralized a chemical plume.
The fact is, accidents usually trace back to human shortcuts or a lack of training. The best solution always comes down to planning and ongoing education. Facilities running titanium trichloride operations need protocols — not just the paper binders employees sign on hiring day, but real, routine drills. Every worker should know what to do during a spill. Simple steps like double-checking valves and cleaning up droplets immediately can prevent the big disasters everyone fears.
Any new worker deserves mentorship, not just a slideshow. It’s safer when a seasoned hand points out where leaks start, how gaskets degrade, and the subtle signs that a container isn’t sealed right. Managers should reward vigilance because sometimes the quiet warning catches the worst mistakes just in time.
Safer alternatives might show up in the future, but for now, industrial users rely on titanium trichloride for its effectiveness. Government oversight plays a key role, but personal accountability matters just as much inside the facility gate. Working with chemicals means trusting your training and looking out for coworkers. Every step towards prevention equals healthier lungs and safer communities. Ultimately, a culture of safety takes root when leadership and frontline workers meet in the middle, sharing both responsibility and respect for the risks they face every day.
| Names | |
| Preferred IUPAC name | Titanium(III) chloride |
| Other names |
Titanium trichloride, mixture with aluminum chloride |
| Pronunciation | /taɪˈteɪniəm traɪˈklɔːraɪd ˈmɪks.tʃər/ |
| Identifiers | |
| CAS Number | 7705-07-9 |
| Beilstein Reference | 3586572 |
| ChEBI | CHEBI:53305 |
| ChEMBL | CHEMBL1201538 |
| ChemSpider | 5098660 |
| DrugBank | DB14676 |
| ECHA InfoCard | 14d4bfc8-ef5b-4f29-b4df-50c0ac073cdf |
| EC Number | 232-042-7 |
| Gmelin Reference | 85443 |
| KEGG | C18636 |
| MeSH | D013976 |
| PubChem CID | 86344 |
| RTECS number | WX4370000 |
| UNII | 22FS0O13TY |
| UN number | UN3264 |
| CompTox Dashboard (EPA) | CompTox Dashboard (EPA) of product 'Titanium Trichloride Mixture' is "DTXSID9022819 |
| Properties | |
| Chemical formula | TiCl3 |
| Molar mass | 151.29 g/mol |
| Appearance | Purple solution |
| Odor | Pungent |
| Density | 1.36 g/cm3 |
| Solubility in water | Insoluble |
| log P | 1.6 |
| Vapor pressure | Negligible |
| Acidity (pKa) | 1.5 |
| Basicity (pKb) | Very Weak Base |
| Magnetic susceptibility (χ) | −1.5×10⁻⁴ cm³/mol |
| Refractive index (nD) | 1.5 |
| Dipole moment | 1.55 D |
| Thermochemistry | |
| Std molar entropy (S⦵298) | 322.2 J·mol⁻¹·K⁻¹ |
| Std enthalpy of formation (ΔfH⦵298) | -763 kJ/mol |
| Pharmacology | |
| ATC code | V07AB |
| Hazards | |
| GHS labelling | GHS02, GHS05, GHS06 |
| Pictograms | GHS02,GHS05,GHS06 |
| Signal word | Danger |
| Hazard statements | Hazard statements: H314, H318, H332, H335 |
| Precautionary statements | P260, P264, P271, P301+P330+P331, P303+P361+P353, P304+P340, P305+P351+P338, P310, P321, P363, P405, P501 |
| NFPA 704 (fire diamond) | 3-0-2-W |
| Flash point | > 40 °C |
| Lethal dose or concentration | LD50 Oral Rat: 3160 mg/kg |
| NIOSH | NIOSH: XT5250000 |
| PEL (Permissible) | Not established |
| REL (Recommended) | Rooms, 4,9 |
| IDLH (Immediate danger) | Unknown |
| Related compounds | |
| Related compounds |
Titanium tetrachloride Titanium(III) bromide Titanium(III) iodide |
