© 2026 Sinochem Nanjing Corporation,
All Right Reserved
|
HS Code |
284587 |
| Chemicalname | Tetrafluoropropionamide |
| Molecularformula | C3H3F4NO |
| Molarmass | 147.06 g/mol |
| Casnumber | 422-58-4 |
| Appearance | Colorless liquid |
| Boilingpoint | 82-84 °C |
| Meltingpoint | -18 °C |
| Density | 1.47 g/cm3 |
| Solubilityinwater | Miscible |
| Flashpoint | None (non-flammable) |
| Refractiveindex | 1.350 |
| Chemicalstructure | CF3CF2CONH2 |
As an accredited Tetrafluoropropionamide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 250g of Tetrafluoropropionamide is supplied in a sealed, amber glass bottle with a tamper-evident cap and clear hazard labeling. |
| Shipping | Tetrafluoropropionamide should be shipped in tightly sealed, chemically resistant containers to prevent leaks. Store and transport it in a cool, dry, and well-ventilated place, away from incompatible substances. Handle with appropriate personal protective equipment (PPE) and comply with local, national, and international regulations for chemical transport and hazardous materials. |
| Storage | **Tetrafluoropropionamide** should be stored in a tightly sealed container in a cool, dry, and well-ventilated area away from incompatible substances such as strong acids and bases. Keep the storage location away from sources of ignition, heat, and direct sunlight. Proper chemical labeling and secondary containment are recommended to prevent accidental release or contamination. Always follow institutional and regulatory safety guidelines. |
|
Purity 99.5%: Tetrafluoropropionamide with purity 99.5% is used in pharmaceutical intermediate synthesis, where it ensures high product yield and batch consistency. Molecular weight 129.05 g/mol: Tetrafluoropropionamide of molecular weight 129.05 g/mol is used in specialty polymer manufacturing, where it provides precise stoichiometric control. Melting point 62°C: Tetrafluoropropionamide with melting point 62°C is used in low-temperature reaction environments, where it enables efficient solubility and processability. Stability temperature 150°C: Tetrafluoropropionamide stable up to 150°C is used in electronics encapsulation, where thermal stability prevents degradation during device fabrication. Particle size <10 μm: Tetrafluoropropionamide with particle size <10 μm is used in high-resolution coating formulations, where it achieves uniform surface coverage and enhanced coating smoothness. Moisture content <0.1%: Tetrafluoropropionamide with moisture content less than 0.1% is used in anhydrous chemical processes, where it reduces unwanted hydrolysis and improves product stability. Viscosity grade low: Tetrafluoropropionamide of low viscosity grade is used in fluidic transport systems, where it allows for rapid and consistent flow during dispensing. Organic solvent solubility: Tetrafluoropropionamide soluble in organic solvents is used in advanced resin modification, where it increases compatibility and formulation flexibility. Assay 98% min.: Tetrafluoropropionamide with assay 98% minimum is used in catalyst preparation, where high compound integrity boosts catalytic efficiency. Refractive index 1.35: Tetrafluoropropionamide with refractive index 1.35 is used in optical material development, where it improves light transmission and clarity. |
Competitive Tetrafluoropropionamide prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please call us at +8615371019725 or mail to admin@sinochem-nanjing.com.
We will respond to you as soon as possible.
Tel: +8615371019725
Email: admin@sinochem-nanjing.com
Flexible payment, competitive price, premium service - Inquire now!
Few chemicals manage to stir interest among researchers and users alike quite like Tetrafluoropropionamide has in recent years. This compound draws attention for its selective utility and the clear advantages it brings to sectors dealing with advanced materials, specialty synthesis, and precision applications. I’ve followed the trends in chemical manufacturing and materials science for a good while, and Tetrafluoropropionamide usually crops up in conversations where robust performance and predictability are the name of the game.
Tetrafluoropropionamide isn't just another fluorinated compound. Unlike products that struggle to balance thermal stability and reactivity, this molecule finds its sweet spot. Its molecular structure, rich in fluorine atoms, resists degradation under heat and caustic conditions. I’ve noticed that in environments where other amides buckle, Tetrafluoropropionamide stands up, showing resilience that makes it reliable even over longer operational cycles. It handles both high-temperature and chemically aggressive needs, which is why chemists prefer it for formulating high-performance polymers and specialized reagents.
Old hands in labs often talk about the frustration of handling unstable reagents and the frequent stoppages or safety concerns involved. Drawing on my own time working with laboratory chemicals, it's clear that using something like Tetrafluoropropionamide means time gets spent on actual research rather than repeated troubleshooting. Fewer unexpected reactions, reduced downtime, and consistent output matter a lot when deadlines approach or product quality needs to stay high experiment after experiment.
Tetrafluoropropionamide commonly appears as a crystalline powder or solid with a brilliant whiteness that signals its high purity. Purity levels often reach 98 percent or higher, supporting its suitability for work requiring meticulous exactness. It feels reassuring knowing a product arrives with specs that make analysis and integration easier, cutting the back-and-forth calibration and minimizing contamination risks.
This compound features a tightly bound propionamide backbone with four fluorine atoms, giving it a distinct chemical signature. It displays a melting point high enough to support robust processing, which helps in tougher applications like fluorinated polymer production and pharmaceutical precursors. I’ve noticed that packaging also emphasizes protection against moisture and air, recognizing Tetrafluoropropionamide’s stability comes from careful handling right from manufacturing to the end-user.
Turn to any development in advanced polymer synthesis or fluorinated specialty chemicals, and you’ll find Tetrafluoropropionamide close by. Whether in engineering plastics, coatings that need to survive corrosive environments, or as a reagent for pharmaceutical intermediates, its multifaceted role becomes apparent.
Some colleagues have shared stories of trialing other fluorinated amides only to confront bubbling, discoloration, or a total breakdown when subjected to tough synthesis steps. Switching to Tetrafluoropropionamide, many saw a shift toward steadier reaction pathways, saving time and cutting costs on reruns. That outcome speaks louder than marketing material can. Creators appreciate tools that fit in without creating unforeseen problems, and this product aligns well with those needs.
Historically, obtaining stable fluorinated amides forced teams to trade off between price, availability, and chemical predictability. What Tetrafluoropropionamide brings is a consistent option—something you can order, receive, and incorporate with confidence, batch after batch. That peace of mind lets R&D groups push forward, knowing that surprises are likely to come not from the backbone chemistry but perhaps from novel product ideas.
Plenty of fluorinated products compete in overlapping spaces, aiming to carve out a niche as the go-to for stability and compatibility. My experience tells me that the real-world difference comes down to how these molecules behave under actual working conditions. Compounds similar in theoretical profile to Tetrafluoropropionamide sometimes fall short, displaying inconsistent solubility or thermal drift.
Tetrafluoropropionamide handles broad temperature swings well and keeps its integrity in polar and non-polar solvents—qualities that reduce unexpected outcomes in both organic and process labs. This advantage starts making a difference as procedures scale up from grams to kilograms, where batch failures can bleed budgets dry. Talking to peers in contract synthesis, having a material keep its specs reliably as volumes scale up shows why Tetrafluoropropionamide continues gaining traction in a crowded market.
Older-generation fluorinated amides may come at lower cost but rarely bring that steady performance. They often need more stabilization measures or create unnecessary by-products, eating up extra time in post-synthesis purification. Many stories circulate about teams sidelined by one-off failures or regulatory headaches over impurities. In this context, Tetrafluoropropionamide, with its well-documented batch consistency and lower impurity content, feels like an engineer’s ally rather than another variable to watch for.
Polymers modified with Tetrafluoropropionamide regularly show increased resistance to harsh conditions, whether it’s in contact with acids in process pipelines or as insulation in electronic components. What’s exciting here isn’t only the stability after hours—or months—of exposure, but also the ability to formulate thinner and lighter materials that retain their toughness. Engineers report reductions in maintenance shutdowns and failures, which correspond to big savings and better system reliability. From a sustainability angle, longer lifespans mean less waste and less frequent replacement, addressing broader concerns about chemical lifecycle and environmental load.
Medicinal chemistry teams sometimes struggle to introduce fluorine atoms with precision or to maintain amide integrity during multi-step syntheses. Here, Tetrafluoropropionamide’s unique structure lends itself nicely to downstream selectivity and control. The feedback I hear emphasizes less need for protective group strategies, reducing synthesis steps and boosting yield. Discoveries in this space spill over into industrial and green chemistry, drawing in researchers eager to cut process waste and resource use.
Sitting in meetings about chemical safety, the best products to work with are those whose hazards you can clearly define, control, and predict. Tetrafluoropropionamide scores here as well. It maintains a clean risk profile thanks to limited volatility and stable storage. Standard good practice—protective gloves, lab ventilation, smart waste management—gets the job done. Professionals appreciate not having to reinvent safety protocols just to start using a newly sourced material. This reliability stands in contrast to some older analogs, notorious for creating acrid vapors or needing elaborate ventilation setups. Clean execution and easier compliance save time and reduce stress all around.
So much of today’s innovation in materials and synthetic chemistry hinges on finding molecules that deliver more than just their baseline properties. Tetrafluoropropionamide brings benefits beyond simple reactivity—tighter quality control, cleaner handling, and higher safety margin—while feeding the need for performance that adapts across fields. I see this in conversations about battery technology, where demands for robust fluorinated materials keep climbing, or in specialty coatings for aerospace and automotive sectors. Here, failure isn’t just a missed target; it can mean systemic setbacks or regulatory audits.
Beyond pure industry requirements, academia has taken notice of Tetrafluoropropionamide’s features. Research groups digging into materials science or organofluorine chemistry zero in on reagents that minimize experimental “noise.” The fewer variables at the bench, the easier it becomes to tune, tweak, and truly innovate in the space of new materials or pharmaceuticals. Having a go-to compound like Tetrafluoropropionamide changes the texture of daily research, freeing up resources and letting creative thinking lead instead of troubleshooting and mitigation tasks.
In a world where supply chains change quickly, and quality issues can ripple across entire industries, choosing reliable chemicals isn't just about the bottom line—it’s a matter of expertise and trustworthiness. I’ve seen companies make or lose their reputations based on one bad shipment or inconsistent lot. The science underpinning Tetrafluoropropionamide stands up to scrutiny, with peer-reviewed studies, independent third-party testing, and a record of reproducible results. These are the hallmarks of accountable production and knowledgeable development practices that make a difference in everyday lab work as well as broader market presence.
Transparent documentation and traceability matter especially when regulatory frameworks tighten and end-users need assurance about what goes into their products. With Tetrafluoropropionamide, the commitment to these standards shows up in lot certifications, batch analytics, and the willingness of producers to work directly with research and manufacturing customers. This openness reduces the friction of onboarding a new product, aligns with globally recognized best practices, and brings science and commerce closer together.
Modern chemistry can’t be separated from its environmental footprint. Every time a supplier brings in a new fluorinated compound, questions arise regarding its persistence, impact on waste streams, and broader ecological effects. Having chosen and worked with chemicals across various labs, I’ve seen the shift toward low-impact, higher-stability molecules as a win for both process efficiency and waste reduction.
Tetrafluoropropionamide, by offering reliable reactivity and reducing typical by-products, lets teams cut down on resource-heavy processing and post-synthesis cleanup. Fewer chlorinated solvents, less hazardous waste, and better recovery means a lighter touch on the water table and air. This sort of progress is hard to quantify in single anecdotes, but over years of use in scaled settings, better chemical stewardship supports industry growth and protects communities around manufacturing hubs. By reducing the volume and toxicity of waste, Tetrafluoropropionamide quietly supports the sector’s move toward responsible productivity.
Those working in regulatory compliance or in green chemistry initiatives will recognize that every successful reduction in hazardous output makes it easier to hit emissions targets and sustainability milestones. Talking to utility engineers, the ability to use higher-quality reagents that actually lower process burdens complements the drive to improve plant safety and efficiency. In short, this is a chemical that addresses both market and societal pressure points, backing up forward-thinking science with real-world improvements.
No chemical, no matter how advanced, escapes the broader hurdles that confront the field: responsible use, lifecycle assessment, and integration with next-generation technologies. Tetrafluoropropionamide, in this context, serves as a touchstone for how specialty materials companies should approach their products. Transparency and feedback loops with users are part of this equation. For example, some labs push for open data on degradation pathways, solvent compatibility, and end-of-life profiles. Producers that answer these calls not only shape policy but also set industry benchmarks for reliability.
Creating accessible guidance for safe handling and disposal has supported the responsible uptake of Tetrafluoropropionamide across different settings. When companies share case studies detailing best practices—from storage to integration to novel applications—the wider community benefits. This sort of collective intelligence, supported by diligent recordkeeping and publication, sidesteps the pitfalls of fragmented, error-prone adoption that used to dog specialty chemicals in the past.
Investments in recycling and reclamation technologies offer yet another piece of the puzzle. In cases where residual material leaves the process stream, recovery programs save costs and minimize environmental impact. There’s no silver bullet here, but drawing from experience, widespread collaboration between manufacturers and end-users lays the groundwork for continual improvement. Tetrafluoropropionamide’s documented integration within these cycles stands as proof that specialty chemicals can fit within larger sustainability narratives.
Working on interdisciplinary project teams, what often makes or breaks a project comes down to the reliability of key building blocks. Tetrafluoropropionamide comes up again and again in brainstorming sessions, material selection reviews, and strategic planning documents. It occupies this space because the performance metrics hold up, batch histories prove consistent, and teams working at the sharp end of development need to spend their time on invention, not constant troubleshooting.
In closing shop at the end of a project, results speak for themselves. Fewer project delays, lower materials losses, and easier regulatory check-offs form the background to stories of successful product launches and research breakthroughs. Colleagues from across different sectors—pharmaceuticals, materials science, and engineering—speak highly of solutions that integrate cleanly and perform without drama. From firsthand experience and shared conversations alike, Tetrafluoropropionamide clearly belongs among those products that help build progress, meet high safety and quality expectations, and point to a future of smarter, more responsible chemical practice.
