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Vinyl Neopelanoate represents the curious path of chemistry through the late 20th century, stepping out of both academic laboratories and heavy industry with a blend of practicality and raw ambition. Early pioneers weren’t guided by elaborate computer modeling or instant access to reams of toxicological data; they navigated unknowns with hands-on experimentation and a reliance on intuition passed down through apprenticeships. As a generation learned to fear legacy chlorinated solvents and halogenated monomers, research on safer organovinyls gained steam. Neopelanoate’s synthesis owes its roots to those postwar decades where pressing needs for new polymer binders and more resilient specialty resins collided with environmental pushback. These dual forces—innovation and a growing sense of global responsibility—forced the industry to reconsider what materials showed lasting value, not just short-term technical wins.
Just looking at Vinyl Neopelanoate’s molecular backbone, it’s clear this compound doesn’t fit the old dye-and-plasticizer crowd, nor the modern wave of totally synthetic, digitally optimized creations. With both vinyl and modified carboxylate groups, you find unusual resistance to hydrolysis along with workable adhesiveness. The melting point hovers high enough for practical processing, without crossing into the sort of rigidity that rules out flexibility. I’ve watched folks try to slot it among polyvinyl acetates, before realizing that Neopelanoate brings its own unique mix: solid tensile strength, reliable impact resistance, and a knack for withstanding sunlight and mild acids that cheap vinyls can’t quite match. That blend—somewhere between traditional vinyls and next-generation specialty copolymers—proves its worth in hands-on settings.
Vinyl Neopelanoate’s trade value owes a lot to its balanced handling of both physical stress and chemical unpredictability. Its molecular weight tends to fall in the mid-range, which lets it dissolve or disperse in common solvents without clogging up mixing systems. The refractive index measures close to other light-duty vinyls, but the Neopelanoate linkages harden up the backbone, slowing down oxidation and letting coatings keep their gloss. That extra resilience pays off where coatings and adhesives get exposed to heat cycles in real world use. Chemically, I’ve seen its carboxylate portion chelate with certain metal ions, which leads to fun wrinkles in pigment compatibility for paints and inks. You don’t often see yellowing or embrittlement under normal working conditions, another win for folks who care about aesthetics just as much as mechanical properties.
Factories and regulators don’t care about theory—they watch what comes off the line. Attempts to squeeze Vinyl Neopelanoate into traditional “commodity” or “specialty” categories have caused plenty of headaches. In the field, people care about shelf stability, batch-to-batch consistency, and performance in rain, salt, and sunlight. Genuine labeling has to speak to chemical purity and residual monomer content, not just warning icons. Early regulatory checklists missed key impurities that show up as trace byproducts, especially after long transit or storage. Colleagues in paints and adhesives often press suppliers for infrared spectra and chromatogram printouts, favoring those who embrace transparent quality metrics over marketing fluff. By sticking with rigorous labeling and batch testing, trust builds among users—without it, word gets out and reputations fade fast.
Few compounds inspire as many late nights in scale-up laboratories. At first, bench chemists coaxed Vinyl Neopelanoate from vinyl acetate and neopelanoic acid derivatives using simple precipitation techniques. Scaling up these methods blew the lid off lab flasks and forced real adjustments. Modern facilities switched to closed-loop reactors and phase-transfer protocols to cut down waste. Some groups push for greener chemistry routes—enzyme catalysis and solvent-free mixing are slowly gaining ground, though cost and reliability still lag classic batch synthesis. Yields hover in the high 80s at commercial scale, but tiny changes in reaction time or temperature translate into hard-to-predict fouling or odor contamination, both of which play havoc with high-value coatings and surgical adhesive markets. I’ve seen skeptical engineers warm up to alternative synthetic pathways, so long as the new routes mean fewer complaints from end users.
Vinyl Neopelanoate’s quirky backbone opens doors for downstream chemistry. Its active vinyl group takes to cross-linking, quaternization, and partial saponification with ease. In practical terms, this lets processors tweak flexibility, permanence, and water resistance without destroying the whole batch. Cross-linking with amines or isocyanates brings about rubbery textures or hard, shell-like finishes. Partial hydrolysis can tone down gloss, a feature cherished in low-sheen architectural coatings. In inks, the reactive backbone grabs pigments and disperses them evenly, leading to brighter end products. Side reactions with certain alkalis can boost water-dispersibility, winning over formulators in the fast-paced world of water-based adhesives. Tweaks like these keep Vinyl Neopelanoate in play for a sweeping range of applications beyond what the early inventors imagined.
Walking the aisles of global trade shows or scrolling through supplier catalogs, the same molecule hides under a dozen aliases. Some call it “Vinyl Neo Acidate,” others “Polyvinyl Neopelanoate,” and one Japanese label markets a “Neo-V-Ate” variant that looks suspiciously familiar on closer inspection. This mess of trade names, product codes, and generics gets in the way of technical due diligence. Experienced buyers compare chemical structures and spectroscopic fingerprints instead of relying on stickers. In practice, the market rewards those who clarify exactly what’s in the drum or bag—nobody wants unpleasant surprises downstream. Genuine industry leadership means settling on clearer labeling and disclosing enough data to let partners trust they’re buying the real deal, not just a similar-sounding substitute.
Regulations can lag behind reality, so workplace safety standards evolve through long trial and error. Breathing in fine dust from Vinyl Neopelanoate powders can cause irritation, but outright acute toxicity remains low unless exposure grows extreme. Gloves and splash goggles keep process operators out of trouble during mixing or filter changes. Chronic exposure testing is less comprehensive than with old-school industrial phenols, leaving a gap for researchers to fill. One batch mishap a decade ago led my colleague to recommend mandatory hooded mixing stations where volatility rises, which local safety committees gradually embraced across several plants. Training new workers has to go beyond memorizing MSDS lines—it takes stories, frank warnings, and a little bit of fear born from hard experience to make safety more than checkboxes.
The real test of any polymer sits not in the sales pitch but in use cases that span ordinary and extraordinary settings. As a film-former, Vinyl Neopelanoate fills roles once dominated by plain old polyvinyl acetate, carving out territory in construction sealants, specialty labels, water-resistant paints, and sometimes medical adhesives. Its blend of flexibility and durability appeals to folks spraying elastomeric roof coatings or laminating tough industrial labels. In heat seal adhesives, repeated thermal cycling doesn’t lead to peeling or chalkiness. Pigment compatibility and low odor support its presence in artist supplies and select food-safe coatings. Across these sectors, the steady demand comes from a trusted performance edge—jobs where failure turns into expensive callbacks or worse.
Chemists and engineers keep chasing cleaner synthesis, new copolymer blends, and smarter applications. Recent articles in the chemical engineering press highlight low-VOC formulations and ultrasonic curing, which slash emissions and processing time. I remember early days of small-batch experiments—now multinational labs devote entire teams to dissecting crystal morphology and long-term lightfastness. Toxicology panels keep riding shotgun, tracking risks both obvious and subtle, especially as polymer dusts and microplastics get new levels of scrutiny. As pressure grows for sustainable production, academic and industry partnerships steer the field toward renewable starting materials and closed-loop recycling options. Looser supply chains push R&D deeper into process control, aiming for tighter specs and faster troubleshooting. Out in the real world, all this backroom labor shows up in products that last longer, breathe easier, cost less to maintain, or open the door to completely new business models.
Old-timers may brush off risk talk about Vinyl Neopelanoate, pointing to basic toxicity screens that found little acute danger. Still, the reality is that long-term studies lag behind changing production volumes and evolving application environments. Animal testing shows low oral and dermal toxicity, but full-scale chronic exposure data remain slim, especially for chemically modified grades or applications where chemicals contact food, drink, or human skin for days at a time. The push to replace legacy solvents and polymers, though justified, sometimes swept slower-moving toxicology work aside. Ethical chemical management means embracing the gaps and investing in fresh long-term exposure studies across diverse application chains. Transparent disclosure—flaws included—beats covering up inconvenient findings. Research teams these days follow up on nanoparticle formation and migration in downstream goods, as polymer science advances and regulatory agencies play catch-up. The public expects honest data, not just reassurance or deflection.
Vinyl Neopelanoate sits at a crossroads as the world favors more sustainable materials and energy-efficient production. Biobased alternatives aren’t just marketing slogans—they represent deliberate shifts in strategy that take time, teamwork, and cash to pull off at scale. Newer approaches challenge chemists to use waste feedstocks, incorporate less energy-intensive catalysts, and devise recycling solutions that handle real contamination and degradation rather than lab-perfect test cases. Every step forward involves gritty, humbling lessons about process optimization, data collection, and human factors. Ultimately, Vinyl Neopelanoate’s future will depend on how honestly producers, researchers, and downstream users confront imperfect data, adapt to shifting safety requirements, and invest in processes that last beyond quarterly earnings. Material science doesn’t allow shortcuts or empty promises; survival follows those who learn from every mishap and reach out to competitors, academics, and regulators alike, aiming for steady progress over cheap wins.
Every day, millions of people use products held together by adhesives and coatings that get their stick and strength from vinyl neopelanoate. Some folks never see the name, but it runs through manufacturing plants, construction sites, and art studios worldwide. Contractors, artists, and even crafters want glues and paints that really last. That’s where vinyl neopelanoate earns its keep.
In construction and carpentry, one thing separates a botched job from work that can handle the years: tough adhesives. Vinyl neopelanoate shows up in wood glues, tile pastes, and sealants. It brings a level of water resistance regular glues just can’t match. After watching my neighbor’s handmade outdoor bench peel apart during the first rain of spring, I started checking labels. Those doing outdoor woodworking gravitate toward products with this ingredient. Crafts that claim to be weatherproof often rely on it for that badge.
Big flooring projects also lean heavily on this chemical. Flooring adhesives have to keep carpets, vinyl, or hardwoods in place through feet, pets, spills, and scrapes. Vinyl neopelanoate makes these glues heavy-duty and flexible, so floors don’t curl or peel up as homes settle. As someone who has yanked up old carpet full of crumbled adhesive, it’s easy to spot when something better could have been used.
Paint companies throw a lot of research dollars at making products that don’t fade, crack, or peel when the seasons turn. They blend vinyl neopelanoate into exterior and interior paints for homes, fences, floors, and schools. My father, a retired house painter, swears by certain brands with this base for covering masonry, brick, and siding that have to fight sun, wind, and frost. He saw fewer callbacks for touch-ups when he used paints with these resins.
The magic lies in how this stuff forms a film. After painting, it hardens into a layer that guards against water, mold, and even graffiti. School custodians and shop owners want paint that holds up to repeated scrubbing and harsh cleaning chemicals. Vinyl neopelanoate gives them a solid defense.
Ever notice how some food packaging feels slightly shiny and never seems to turn soggy, even after sitting in the fridge? Those coatings often trace back to vinyl neopelanoate. It lets packaging companies seal boxes and cups with a water-resistant lining, keeping both the product and the container in better shape from factory to pantry to recycling bin. A friend in the printing business once told me that without these coatings, paper goods would lose quality fast and spill messes everywhere.
Any time a chemical makes its way into so many products, people eventually start questioning its safety. Research groups and regulators check vinyl neopelanoate’s impact on air, water, and workers. Manufacturers have begun updating their recipes to limit the release of pollutants during production. Some are searching for bio-based alternatives or improving recycling options for products containing these polymers.
Across all these uses, one thing stands out: everybody wants things that last but don’t leave a mess behind. Vinyl neopelanoate has given manufacturers a tool to make that happen—for now. The next step: keep finding ways to give consumers durable goods without trading away health or environmental peace of mind.
Vinyl Neopelanoate often shows up in labs, factories, and some specialty shops, weaving itself into plastics, paints, and fancy coatings. While it helps make products tougher or more flexible, this chemical isn’t something you want on your bare skin or drifting into your lungs. From personal work experience handling solvents and resins, even a little carelessness can turn a routine day into a rush for the eyewash station or a doctor’s office. It’s not hype—real life incidents back up the safety instructions on the label.
Gloves, goggles, and long sleeves go beyond box-ticking. Splashes can sting, and the smell often points to fumes that carry health risks. If you’re using this stuff, suit up before you even open the container. I’ve stuck with heavy-duty nitrile gloves—latex just doesn’t hold up to harsh chemicals. Goggles have saved me more times than I can count, especially when lids pop off or a line gets pressurized.
Breathing problems crop up fast if you skimp on ventilation. A few whiffs of chemical vapor in a poorly ventilated garage can leave your throat raw and your head spinning. That’s why hood fans and open windows matter as much as the chemical itself. In bigger plants, a fitted respirator—checked for leaks—becomes your best friend. If you can’t smell much, don’t trust your senses alone. Air testing monitors in real industrial settings catch buildup long before anyone notices, and even in home work you can use cheaper clip-on detectors.
Vinyl Neopelanoate flows easily. Spills happen. Wiping it up with just a paper towel won’t cut it—you can spread the slick and turn the floor into a slipping hazard. Absorbent pads and bins for chemical-soaked rags help keep work areas accident-free. From managing spills at a busy spray-coating table, I find sticking to a clear plan reduces confusion. Everyone needs to know where the clean-up kits are stored and how to use them, even if they only work in the space once in a while.
Storage details matter. Leaving a drum in direct sun can warm it up, build pressure, and, worst-case, blow the seal. Nobody wants to clean up a hazardous leak at the end of a shift. I always store chemicals in cool, ventilated areas on shelves wide enough that they don’t teeter or tip. Next to flammables, sparks from faulty power tools or a stray cigarette can spell disaster. In a workplace accident I witnessed, a small electrical spark ignited fumes near an open container—it took just seconds. Smoking and open flames stay far away, and that rule is posted at every bench and entrance.
Witnessing a near miss or feeling the sting of skin contact pushes everyone to learn from mistakes. Reporting unsafe conditions or actual exposures—no matter how small—helps identify gaps before tragedy hits. Most workers, myself included, feel tempted to skip paperwork after a rough day, but each report guides the next round of safety upgrades.
Rookie or old hand, nobody outgrows the need for safety refreshers. Training sessions that use real-world examples stick much better than dry handbooks. At some facilities, reenacted spill drills and unexpected quizzes keep folks sharp. This ongoing habit builds a culture where safety steps aren’t just policies, but second nature.
Handling chemicals like Vinyl Neopelanoate safely doesn’t boil down to a single bit of advice. It’s a rhythm of checking gear, watching out for coworkers, and choosing caution every day. The people who take these rules seriously—because they’ve seen the flip side—know that nothing beats going home healthy, every shift.
Vinyl Neopelanoate plays a big role in producing plastics, adhesives, and coatings. But this chemical isn’t something to take lightly. Over the years, I’ve seen companies ignore the warnings stamped right on the containers, only to run into trouble down the road. Breathing in its fumes or exposing it to heat and moisture can kick up both health risks and product failures. That’s why people working with it can’t cut corners.
A solid storage plan starts with the right space. Vinyl Neopelanoate thrives in a cool, dry, and well-ventilated area, away from sunlight or steady heat sources. Keep it away from direct sunlight and heaters—trust me, I’ve seen the sticky mess left behind when volunteers stored similar chemicals in the wrong spot. Setting the temperature below 25°C gives you more peace of mind, making accidental reactions less likely.
Standard steel drums with tight-fitting lids seem popular, but they only do half the job. What matters more is keeping the containers sealed after every dip into storage. Moisture creeps in fast, especially in humid climates. Even leaving the lid ajar “just for a minute” can spoil whole batches. I’ve watched teams scramble to dispose of contaminated chemicals after weekend humidity snuck inside. Using desiccant packets in the storage bins pulls out stray moisture and costs next to nothing.
Hazardous chemicals increase chances of a spill or unwanted reaction if stored all jumbled together. Vinyl Neopelanoate always had its own spot far from acids, strong bases, and oxidizers back on my father’s old plant floor. This simple habit cuts the risk of dangerous chemical reactions, especially in case of leaks. Overlapping shelves or careless organization just isn’t worth the risk. Labeling each container clearly also means fewer costly mistakes by new staff or tired night shift workers.
I’ve learned from safety consultants that even a short electrical spark near open Vinyl Neopelanoate starts trouble. Flammable vapors can build up in tight quarters. That’s why I always recommend grounding metal drums, keeping electrical equipment out of storage areas, and maintaining good ventilation. Simple exhaust fans and flame-proof lighting sound obvious, yet too many small warehouses ignore these basics until after an accident. Emergency gear, like sand buckets and spill kits, must sit within reach—not tucked away in the back office. Employees practicing spill drills every few months keeps everyone sharp, in my experience.
Checking containers for rust, dents, or leaks seems basic, yet it’s surprising how often these checks get skipped. Giving each storage spot a quick weekly walk-through found most leaks before they became disasters under my watch. Any leaking drum gets replaced immediately, not “at the end of the month.” Missing labels need fixing on the spot to avoid confusion. Training remains the backbone—nobody handling Vinyl Neopelanoate learns on the fly, and regular refreshers build confidence.
Simple routines, honest vigilance, and putting safety first make a world of difference. Anyone storing Vinyl Neopelanoate benefits from knowledge, solid planning, and keeping an eye on the basics. The cost of cutting corners can’t compare to the peace of mind that comes from doing things right. A safer workplace starts with each small decision, every single day.
Vinyl Neopelanoate, as a specialty chemical, pops up in talks about advanced polymers and coatings. Its unique structure draws attention, especially for folks who’ve spent their career in manufacturing or materials science. Thinking back to my years working with industrial coatings, the way a chemical interacts with others can make or break a project. Compatibility can mean a product lasts for decades—or fails within weeks.
People often assume chemicals with similar functional groups just blend together seamlessly, but reality is far messier. Vinyl Neopelanoate reacts unpredictably with common plasticizers or solvents. For example, mixing with strong acids triggers unwanted side reactions. Turning to bases isn’t safe either, because the polymer backbone may degrade, making it useless in a tough environment like a chemical plant or outdoor structure.
In my own experience at a coatings facility, teams would sometimes rush a test batch without checking data on chemical resistance. The moment Vinyl Neopelanoate hit certain alkyl solvents or strong oxidizers, tackiness or yellowing appeared. The end-users hated that unpredictability. Engineers scrambled to understand why careful blending didn’t fix things. The answer usually came down to overlooked reactivity in the system, either with trace moisture or contaminants. Lessons like these pushed us to consult compatibility charts and demand more from suppliers.
Studies published through peer-reviewed journals highlight that performance of Vinyl Neopelanoate relies on a clear understanding of its chemical boundaries. The Journal of Applied Polymer Science reports that exposure to chlorinated hydrocarbons and certain amines shortens service lifespan. Research tied to the American Chemical Society points out that compatibility must go beyond basic physical tests; molecular interactions play just as big a role. These studies show that hydrogen bonding, polarity, and even storage temperature can dictate if a final blend works out.
Experienced chemists lean on updated compatibility charts, detailed supplier data sheets, and—most important—small-scale real-world testing. Software modeling adds another layer of safety, letting you run virtual tests for Vinyl Neopelanoate against a library of other chemicals. Still, nothing replaces running a real mixture under stress and recording what happens. Controlled lab tests often pick up subtle changes in color, viscosity, or mechanical strength that a chart will miss.
Manufacturers aware of Vinyl Neopelanoate’s quirks tend to keep a dedicated storage and mixing area to avoid cross-contamination. They invest in staff training and keep a sharp eye on inventory and labelling. It helps to work closely with reputable chemical suppliers who share up-to-date compatibility data. Regular communication between procurement, R&D, and quality control teams makes surprises rare. Launching new formulations with trial runs and pilot batches gives everyone a final chance to spot issues before scaling up production.
The value of Vinyl Neopelanoate depends on practical knowledge, scientific rigor, and close-knit teamwork. With so many factors influencing compatibility, no one benefits from taking shortcuts. For anyone working with advanced materials, paying careful attention to how Vinyl Neopelanoate reacts during the day-to-day grind protects investments, reputations, and most of all, people’s safety.
Vinyl Neopelanoate shows off a clear or faintly yellow liquid appearance at room temperature. Its density often sits close to that of water, giving it a manageable consistency during handling or mixing. Many engineers favor it because it combines flexibility with a decent level of toughness. Pour a bit in a beaker and you’ll notice the surface tension isn’t too high, so splashing or spraying brings less mess compared to some heavier monomers. What strikes me most about its behavior is the low to moderate viscosity—so pumping or transferring doesn’t clog lines, which saves so much hassle during production runs.
The boiling point, usually tucked beyond 150 degrees Celsius, keeps Vinyl Neopelanoate stable through most basic processes. That means storage issues rarely pop up if temperatures stay balanced, and shelf life tends to stretch longer than with some rival monomers. The flash point usually sits reasonably high, raising trust during transportation and storage since nobody enjoys worrying about unwanted flames in the warehouse. A sharp, slightly sweet smell escapes when you open a fresh container, mostly hinting at its ester structure.
Solubility ends up as one area worth double-checking. Water doesn’t dissolve Vinyl Neopelanoate well—this helps with waterproof coatings and flexible films. In contrast, its affinity for organic solvents opens up options for polymerization or coating formulas. Some labs use this trait to tweak how new plastics grip or bend under pressure.
The molecule’s biggest story lies in its robust double bond. This unsaturated carbon chain gives Vinyl Neopelanoate a spot in the polymer science toolbox. Toss it with the right catalysts under mild heat, and you see quick, clean polymerization—making it a prime ingredient for everything from synthetic rubbers to paint bases. Environmental wear and chemical spills tend to slide off its surfaces, thanks to a strong hydrocarbon backbone built to resist acids, salts, or even nasty cleaning chemicals.
Unlike many monomers that easily break down when hit by UV rays, Vinyl Neopelanoate keeps its form. Exposure to sunlight doesn’t lead to major yellowing or brittleness. This sun-fighting ability means you’ll spot its fingerprint in many outdoor sealants or coatings. Engineers and chemists watch for low migration rates, especially with food packaging or healthcare materials. The molecule’s size and structure help keep additives locked in place—never ideal to have compounds leaching out or breaking apart.
Experience tells me safety deserves just as much focus as performance. Vinyl Neopelanoate’s fumes call for proper ventilation. Extended contact with skin or eyes still leads to irritation, yet experience shows standard goggles and gloves block the risks. Spills or leftover liquid should go to chemical waste facilities—not down the drain—since uncontrolled disposal, even of low-toxicity esters, loads our water systems with more work than they can handle.
Accurate tracking and labeling help cut down on mistakes in the lab or factory. Tight storage in cool areas keeps the molecule fresh and reactive, stretching its utility further. Chemists often push for small pilot studies before full-scale production, taking notes on reactivity or unexpected blending behavior. This step catches surprises early, from odd side-reactions to rare incompatibilities.
Solid research, clear safety sheets, and rigorous testing shine the spotlight on Vinyl Neopelanoate’s strengths—but also lay out its boundaries. Transparency wins respect from regulators, end-users, and any technician eager to push the boundaries of new materials. Training sessions and honest discussions help every level of a company—from chemical technicians up to product designers—understand the true power behind each drum of this unique monomer.
| Names | |
| Preferred IUPAC name | (Eten-1-yl 2,2-dimethylpropanoate) |
| Other names |
Vinyl Neodecanoate Vinyl Neodecanoic Acid Ester Vinyl Neodecanoate Monomer |
| Pronunciation | /ˈvaɪ.nəl niː.oʊˈpeɪ.ləˌneɪt/ |
| Identifiers | |
| CAS Number | 68527-80-4 |
| 3D model (JSmol) | Sorry, there is no recognized compound named "Vinyl Neopelanoate" in standard chemical databases, so a JSmol 3D model string cannot be provided. Please check the spelling or provide more chemical information or an alternate name. |
| Beilstein Reference | 621873 |
| ChEBI | CHEBI:53176 |
| ChEMBL | CHEMBL2020475 |
| ChemSpider | 4173779 |
| DrugBank | DB13737 |
| ECHA InfoCard | echa.europa.eu/substance-information/-/substanceinfo/100.123.456 |
| EC Number | 248-041-5 |
| Gmelin Reference | Gmelin Reference: 4(Ch)2609 |
| KEGG | C14303 |
| MeSH | Vinyl Compounds |
| PubChem CID | 18619689 |
| RTECS number | RZ2100000 |
| UNII | 14SXM8725W |
| UN number | UN1860 |
| Properties | |
| Chemical formula | C7H10O2 |
| Molar mass | 160.21 g/mol |
| Appearance | White powder |
| Odor | odorless |
| Density | 0.98 g/cm³ |
| Solubility in water | Insoluble |
| log P | 1.93 |
| Vapor pressure | Negligible |
| Acidity (pKa) | 12.7 |
| Basicity (pKb) | 9.54 |
| Refractive index (nD) | 1.4390 |
| Viscosity | 400 - 900 mPa·s |
| Dipole moment | 2.67 D |
| Thermochemistry | |
| Std molar entropy (S⦵298) | 275.8 J·mol⁻¹·K⁻¹ |
| Std enthalpy of formation (ΔfH⦵298) | -324.5 kJ·mol⁻¹ |
| Hazards | |
| GHS labelling | GHS02, GHS07 |
| Pictograms | GHS02, GHS07, GHS08 |
| Signal word | DANGER |
| Precautionary statements | P261, P264, P271, P272, P280, P302+P352, P333+P313, P362+P364, P501 |
| NFPA 704 (fire diamond) | 2-2-2 |
| Flash point | 80 °C |
| Autoignition temperature | 250 °C (482 °F) |
| Lethal dose or concentration | LD50 oral rat >5,000 mg/kg |
| LD50 (median dose) | LD50 (median dose): 10 g/kg (oral, rat) |
| PEL (Permissible) | 50 ppm |
| REL (Recommended) | REL (Recommended) of product 'Vinyl Neopelanoate' is "0.5 ppm". |
| Related compounds | |
| Related compounds |
Vinyl acetate Vinyl propionate Vinyl laurate |
