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All Right Reserved
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HS Code |
988359 |
| Cas Number | 1477-55-0 |
| Molecular Formula | C8H12N2 |
| Molecular Weight | 136.2 g/mol |
| Appearance | Colorless to pale yellow liquid |
| Odor | Ammonia-like |
| Melting Point | -54 °C |
| Boiling Point | 257 °C |
| Density | 1.03 g/cm³ at 25 °C |
| Solubility In Water | Miscible |
| Flash Point | 140 °C (closed cup) |
| Refractive Index | 1.591 at 20 °C |
| Vapor Pressure | 0.13 mmHg at 25 °C |
As an accredited M-Xylylenediamine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | M-Xylylenediamine is typically packaged in a 200 kg blue HDPE drum with secure cap, proper labeling, and hazard warnings. |
| Shipping | M-Xylylenediamine should be shipped in tightly sealed containers, clearly labeled, and protected from moisture and physical damage. It is classified as a hazardous material, typically under UN2280, and must be transported according to regulations for corrosive substances. Proper documentation and safety data sheets (SDS) must accompany each shipment. |
| Storage | M-Xylylenediamine should be stored in a tightly closed container, in a cool, dry, and well-ventilated area away from incompatible substances such as acids and oxidizers. Protect from moisture and direct sunlight. Store at room temperature, and ensure proper labeling. Use corrosion-resistant shelves and secondary containment to prevent leaks or spills, and restrict access to trained personnel only. |
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Purity 99%: M-Xylylenediamine with 99% purity is used in epoxy resin curing, where it ensures optimal crosslinking density and improved mechanical strength. Viscosity 60 mPa·s: M-Xylylenediamine with a viscosity of 60 mPa·s is used in adhesive formulations, where it enables efficient mixing and uniform application. Melting Point 43°C: M-Xylylenediamine with a melting point of 43°C is used in polyamide synthesis, where it facilitates controlled polymerization and consistent polymer properties. Molecular Weight 136.19 g/mol: M-Xylylenediamine with a molecular weight of 136.19 g/mol is used in isocyanate curing systems, where it delivers balanced reactivity and enhanced thermal stability. Water Content <0.2%: M-Xylylenediamine with water content less than 0.2% is used in coatings applications, where it prevents undesirable side reactions and ensures high gloss finish. Stability Temperature 150°C: M-Xylylenediamine with stability temperature up to 150°C is used in composite materials, where it maintains structural integrity during high-temperature processing. Aromatic Diamine Content 99%: M-Xylylenediamine with aromatic diamine content 99% is used in thermoset plastic manufacturing, where it provides high heat resistance and dimensional stability. |
Competitive M-Xylylenediamine prices that fit your budget—flexible terms and customized quotes for every order.
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People working in advanced materials, adhesives, and coatings often look for building blocks that deliver real results. M-Xylylenediamine stands out because it handles tough challenges across a range of sectors, making it much more than another raw chemical. In labs and on factory floors, creators trust this diamine to turn imaginative designs into sturdy reality. Its particular molecular structure, simpler than many specialty chemicals, supports both large-scale processes and fine-tuned projects.
Ask anyone who’s spent time formulating epoxy resins or engineering strong adhesives—selecting the right amine hardener changes everything. M-Xylylenediamine, often known as MXDA, brings a balance between reactivity and flexibility. Technical staff appreciate the way MXDA unlocks fast curing times in epoxy systems without heavy tradeoffs in durability. Finished products get improved adhesive strength, shock resistance, and extended weatherability. Whether in protective coatings or composite parts, these are not minor benefits—they drive major advances in performance and reliability.
With MXDA, purity and consistency are not recommendations—they’re requirements. A clear, pale-yellow liquid at room temperature, MXDA delivers solid performance where accuracy matters. It’s typically produced with high assay levels, reducing risk of contaminants that could throw off reaction chemistry. Standard models supply densities at roughly 1.03 g/cm³ and boiling points reaching about 265 °C, letting the compound stay stable through many production cycles. You won’t find it breaking down or losing color under ordinary shop conditions. Most users benefit from a product that stays fluid well below freezing, keeping pipes and valves clear during unpredictable weather.
While technical data may not excite everybody, experience shows these specifications pay off up and down the supply chain. Anyone in charge of bulk shipments, automated dosing lines, or sensitive storage knows how much time and trouble is saved with a liquid amine that won’t thicken or crystallize under moderate cooling. That translates into fewer clogs, easier cleanups, and less downtime for making adjustments.
Epoxy coatings cover bridges, water tanks, and pipelines that face tough punishment from the elements. MXDA boosts the performance of these coatings by supporting tough, flexible finishes. Experience shows that, compared to aliphatic amines, MXDA hardens epoxy faster and more thoroughly, even when working at modest temperatures. For companies racing seasonal deadlines or late-stage design changes, that faster cure time helps keep projects on track. I remember watching epoxy floors in a chemical plant set up overnight—in every case, MXDA made the difference.
Working with composites or high-gloss coatings exposes the need for long-lasting color and chemical resistance. MXDA-based resins offer one of the best protections against fading, chemical attack, and micro-cracking. Managers overseeing critical assets—marine vessels, tanker interiors, wind turbine blades—often aim for just this kind of endpoint. The industrial world puts paints and resins through daily strain, so materials with proven resilience matter most.
Not every customer focuses on bulk utility. Electronic engineers, automotive designers, and even commercial artists rely on smart, responsive materials. MXDA’s fine-tuned amine structure supports this need. It builds quick-setting adhesives for electronics assembly, rapid-repair kits in auto shops, and clear epoxies in sculpture studios. The tolerances may be tighter, but the outcome is the same—dependable bonding and smooth curing, with minimal side reactions.
People working in water treatment, environmental restoration, and infrastructure repair see another side of MXDA. Its compatibility with a range of chemical modifiers lets teams fine-tune mixtures for water resistance and slow release. Grouting compounds, sealants for aquariums, and restoration materials for tunnels all benefit. Through it all, MXDA holds up against tough chemical exposure, keeping critical repairs safe from the inside out.
It’s easy to lump MXDA in with other epoxy hardeners, but practical experience reveals the differences. Many industries recall working with purely aliphatic diamines—known for their quick reactions, yes, but also their high tendency to yellow or become brittle over time. On the other hand, aromatic amines, while durable, often require long cure times and elevated temperatures, slowing down field crews and driving up energy costs. MXDA bridges these extremes. The molecule carries aromatic robustness with just enough flexibility from its methyl groups to enable fast, even curing. Real-world testing shows reduced yellowing, enhanced chemical resistance, and improved wetting on a range of substrates.
Safety teams notice something else. MXDA generates lower vapor pressures compared to volatile diamines, so air quality stays more manageable on shop floors, and workers appreciate the reduced odor. Training staff remark how easier it feels to manage compared to more hazardous compounds common in amine chemistry. In field use, crews gain the confidence to mix batches for critical repairs without racing against too-quick gel times or worrying about uneven finish.
Sustainability has become a daily concern—not just a trending theme. Many builders, property owners, and regulators push for better indoor air quality, longer material lifespans, and greener processing. MXDA fits this agenda by enabling lower-emission formulations, especially in waterborne and low-VOC epoxy systems. Researchers point out its role in reducing the need for solvents and promoting high-solids or solvent-free coatings. These changes cut waste, improve indoor air, and help projects pass stricter environmental reviews.
Recycling facilities and decommissioning teams sometimes struggle with breakdown products from older resins. MXDA, compared to legacy amines, tends to result in resin polymers that are more predictable for sorting and secondary uses. While some cleanup challenges remain, MXDA shows a better track record for recycling and energy-efficient destruction than many common competitors.
It’s easy to discuss chemistry in the abstract, but benefits land hardest in the field. One coatings plant switched to MXDA-based hardeners for an urban water tank project, hoping to avoid winter delays. By using this diamine, teams finished lining jobs ahead of schedule, with the coating handling both rapid temperature drops and wet surfaces. Later inspection, years down the line, revealed fewer microcracks and lasting protection. The result didn’t just save dollars—it strengthened customer trust.
Professional woodworkers and flooring installers also rely on MXDA when pushing for clear, tough finishes that will not fog or soften from daily traffic. In my own renovation work, shifting to an MXDA-cured resin system brought not just better appearance, but eliminated call-backs for soft patches or surface peeling. Over time, these improvements grow into lower life-cycle costs for both contractors and clients.
In another example, wind energy companies replaced old aromatic-cured composites with MXDA-based resin, looking to balance blade toughness and weight. Early test blades survived desert heat, coastal salt, and heavy rain without failure. That positive report filtered into broader adoption, showing how tuned chemical choice improves renewable infrastructure and investment security.
MXDA’s real-world advantages don’t come without some tradeoffs. Like most reactive amines, safe handling is serious business. Storage experts make sure tanks stay sealed, use stainless steel fittings, and maintain cool, shaded stockrooms. Large users invest in good ventilation and fit workers with gloves, goggles, and protective gear. Real progress happens when operational teams pair strong safety culture with updated training. Many companies now rotate MXDA handling duties, keeping exposure low and promoting best practices.
From a supply perspective, MXDA usually enters markets through established bulk chemical distributors. Sudden disruptions can delay projects or raise costs, so organizations paying attention to supplier reliability avoid trouble down the line. Some forward-looking manufacturers hold emergency inventory or partner with multiple vendors to keep projects moving without last-minute stress. For smaller users—students, artists, repair techs—smaller packaging options have opened new doors, letting more people experience the benefits without investing in bulk orders.
Regulatory scrutiny shapes chemical choices today. MXDA has seen global evaluation for workplace safety, shipment, and environmental impact. Experienced safety officials track changing exposure limits, training teams in the right ways to handle spills or accidental contact. In many countries, MXDA earns acceptance for use in construction, coatings, and other demanding fields, provided management follows current rules.
Regulatory guides keep evolving, so professionals monitor new research and update procedures as needed. One strong trend involves labeling and risk communication—clearer hazard identification on MXDA shipments and detailed training materials for production teams. These improvements help new workers enter the field with a sharper eye for risk and safe practice.
Decision-makers face plenty of choices in the chemical raw material market. MXDA gains ground by consistently offering a clear mix of performance and value. Fast-curing, well-balanced epoxy systems grow more important as projects get larger and deadlines shorter. Construction planners, manufacturers, and design engineers weigh these requirements against job cost, material cost, and downtime. MXDA often wins out where blends must deliver without raising complexity or waste.
Experienced plant managers know that cost savings do not always come from the cheapest raw input. Materials that fail, slow down repairs, or require repeat service quickly eat up initial savings. With MXDA, the focus shifts back to long-term savings—cleaner installations, trimming labor costs, and defending against weather, wear, and outside attack for years longer.
There’s ongoing research into making MXDA production more energy efficient and exploring bio-based feedstocks. Chemists in both big and small companies test new reaction routes, hoping to rely less on petroleum inputs. Such shifts could shrink environmental footprint well beyond what is possible with older compounds. The end goal is to build a supply chain for MXDA that meets tough green standards without sacrificing the attributes users rely on.
Investments in process automation and better waste recycling continue across the industry. A few large producers have begun reclaiming side-products, reusing them for other applications or as energy sources, and cutting down waste. These steps not only protect the bottom line, they let buyers feel better about the environmental impact of their material selections.
Legacy industries like transportation, utilities, and heavy construction often change slowly. Shifting from an old, familiar hardener to MXDA felt risky at first, especially among long-time supervisors and maintenance leads. Once new projects rolled out, old caution gave way to appreciation for consistent results and fewer call-backs. MXDA isn’t just a lab curiosity—it functions day in and day out where breakdowns are too costly to accept.
Now, newer companies, start-ups, and youthful inventors keep pushing MXDA into new territory. From sports gear to consumer electronics to eco-friendly packaging, every year brings more examples of what careful chemistry combined with creative engineering can deliver. By bridging practical needs and new ambitions, MXDA becomes less a specialty product and more a quiet partner in steady progress.
Engineers and project planners ask the same questions every budget cycle—does this material make sense for today’s job, and will it hold up for the life of the asset? MXDA earns its reputation with experience. Its performance is not locked to ideal lab conditions or only for specialized crews. Everyday users across different industries see the benefit in smaller repairs done right the first time, durable protective coatings, or assembly lines that don’t have to shuffle schedules around slow chemical reactions. In each case, the outcome is measured where it matters—in jobsite quality, customer satisfaction, and bottom-line gains.
Raw materials like MXDA rarely get the spotlight, overshadowed by the flash of finished products or grand design ideas. In truth, they’re where quality starts. Choosing MXDA is less about chasing fashion and more about sticking to lessons learned through hands-on experience. As marketplace demands shift toward speed, resilience, and lower emissions, bets on proven, adaptable materials help organizations stay ready for whatever comes next.
