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HS Code |
414421 |
| Chemical Name | 2,6-Dibromoaniline |
| Molecular Formula | C6H5Br2N |
| Molecular Weight | 250.92 g/mol |
| Cas Number | 608-31-1 |
| Appearance | Light yellow to brown solid |
| Melting Point | 63-67 °C |
| Boiling Point | 285-287 °C |
| Density | 2.08 g/cm3 |
| Solubility In Water | Slightly soluble |
| Refractive Index | 1.694 |
| Smiles | Brc1cccc(Br)c1N |
| Purity | Typically ≥98% |
| Storage Conditions | Store in a cool, dry place, tightly closed |
| Hazard Classification | Irritant |
As an accredited 2,6-Dibromoaniline factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | A 25g amber glass bottle labeled “2,6-Dibromoaniline,” tightly sealed, with hazard warnings and product details printed clearly in black text. |
| Shipping | 2,6-Dibromoaniline should be shipped in a tightly sealed, chemically resistant container, clearly labeled according to relevant regulations. Package must be cushioned and protected from moisture, heat, and physical damage. Ship with appropriate documentation and in compliance with hazardous material transport laws (e.g., DOT, IATA). Handle as a toxic, irritant chemical. |
| Storage | 2,6-Dibromoaniline should be stored in a tightly closed container, in a cool, dry, and well-ventilated area, away from incompatible substances such as strong oxidizing agents and strong acids. Keep away from sources of ignition and direct sunlight. Proper labeling and secure storage should be ensured to prevent accidental exposure. Use a chemical storage cabinet if available. |
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Purity 99%: 2,6-Dibromoaniline with purity 99% is used in pharmaceutical intermediate synthesis, where it ensures high yield and reduced impurities in final products. Melting Point 70°C: 2,6-Dibromoaniline with a melting point of 70°C is used in the preparation of agrochemical derivatives, where controlled melting characteristics enable efficient process scalability. Molecular Weight 250.99 g/mol: 2,6-Dibromoaniline with molecular weight 250.99 g/mol is used in specialty polymer manufacturing, where precise molecular consistency facilitates reliable polymer chain integration. Particle Size <10 µm: 2,6-Dibromoaniline with particle size less than 10 µm is used in dye precursor formulations, where increased surface area leads to improved reaction kinetics. Stability Temperature 120°C: 2,6-Dibromoaniline with stability temperature of 120°C is used in high-temperature catalyst production, where thermal resilience enhances process safety and catalyst performance. Water Content <0.1%: 2,6-Dibromoaniline with water content below 0.1% is used in electronic chemical synthesis, where minimized moisture prevents undesirable side reactions. Color Index Pale Yellow: 2,6-Dibromoaniline with a pale yellow color index is used in pigment precursor manufacturing, where color consistency supports uniform end-product quality. |
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2,6-Dibromoaniline stands apart in the family of halogenated aromatic amines, and it’s not just its structure that speaks volumes. This compound, with its two bromine atoms snuggled onto the aromatic ring, has quietly threaded itself into several industries, from pharmaceuticals to colorants. Speaking as someone who has traced the journey of fine chemicals from their raw, powdery forms in the lab to their roles in finished products, I’ve come to appreciate not just the science, but also the reliability and unique value compounds like 2,6-Dibromoaniline bring to the table.
Chemists see C6H5Br2N and know exactly what’s at stake: you’re dealing with a compact molecule that brings both reactivity and stability. You’ll usually find 2,6-Dibromoaniline in the form of pale crystalline solids. Purity often runs higher than 98 percent as low impurity levels matter when pushing for precision in synthesis work. Contaminants throw off yield or reaction results, so a clean sample becomes the foundation on which many small miracles in product development rest. This matters more than people sometimes realize; a subpar input here can mean costly mistakes down the road.
From my perspective, watching researchers in pharmaceuticals and dyes, or engineers on production lines, 2,6-Dibromoaniline finds purpose at several intersections. As an intermediate, it bridges the gap between raw starting materials and high-value end products. For example, it frequently steps into the synthesis of active pharmaceutical ingredients, where it helps introduce the right functional groups at just the right positions. Skillful use of 2,6-Dibromoaniline paves the way for tailor-made molecules—a vital point in drug discovery, where alterations in the molecular backbone often decide the difference between a treatment and a dead end.
Colorant developers also lean on this compound heavily. The bromine atoms shift the reactivity, making 2,6-Dibromoaniline more than a simple aniline derivative. In azo dye synthesis, for instance, its inclusion helps generate more stable, vivid pigments that end up in inks, plastics, and textiles. As someone who has seen both faded fabrics and sharp, lasting colors, I find the step up in quality from smarter chemical building blocks hard to ignore.
Comparing 2,6-Dibromoaniline to its relatives—plain aniline, monobromoanilines, or other dibromoanilines—the differences are not just academic. The positioning of the bromine atoms significantly shapes reactivity and usefulness. With both halogens sitting right next to the amino group, reaction conditions can be more finely tuned, opening doors to a range of transformations and coupling reactions. This positional specificity also allows for more predictable and consistent yields when scaling up from bench-top work to industrial-sized runs. Many of us who have done process scale-ups understand how one seemingly small structural difference can mean nights without frantic troubleshooting calls.
There are many derivatives from this chemical ‘family,’ but not all offer the same versatility. Take 2,4-Dibromoaniline: similar name, distinct properties. Sometimes differences in melting points or solubility affect blending or separation steps. With 2,6-Dibromoaniline, the molecular symmetry adds an added layer of predictability in crystallization, which is a big help when the purity plays such a significant role in subsequent reactions. Watching production teams, a compound that behaves the same way in kilo-scale batches as it does in gram quantities wins appreciation fast.
In the world of specialty chemicals, quality is tied as much to process as to paperwork. It is one thing to read about a product's specifications, entirely another to watch laboratory and production staff run incoming material through their own checks—infrared spectra, thin-layer chromatography, melting points, and other standard tests. Every lot of 2,6-Dibromoaniline that meets or exceeds published standards builds trust between suppliers and users. Problems with consistency can not only sabotage a day’s work, but also compromise safety, especially in pharmaceutical settings where downstream reactions are not forgiving.
Experience has taught me that reliable documentation, coupled with the ability to trace batches through their chain of custody, supports safe, efficient product development. Having ingredients you can trust lets teams focus innovation on what really matters: developing better treatments, more vibrant colors, or new advanced materials, not firefighting problems caused by erratic quality.
Every synthetic chemist I’ve met shares stories about the gap between theoretical yields and what comes out of reactors. 2,6-Dibromoaniline offers value because its reactivity is well-characterized and its stability under a range of conditions means fewer surprises. Whether used in Suzuki-Miyaura or Buchwald-Hartwig coupling reactions, its predictable behavior paves the way for successful scale-up. Experienced chemists know the headaches caused by mystery side products or inconsistent reactions; I’ve seen time and again how a pure, reliable starting material improves the bottom line for entire research and manufacturing projects.
On the other end of the spectrum, because we’re seeing bigger demand for electronics and specialty polymers, more firms draw on 2,6-Dibromoaniline’s structure for applications in functional material design. The ability to introduce two bromines and an amino group lets scientists fine-tune material properties like solubility, flexibility, and even electronic characteristics. This shows on the manufacturing floor as fewer process interruptions and a smoother transition from R&D to product launch.
No discussion about specialty chemicals feels complete without looking at environmental and supply chain issues. Sourcing fine chemicals remains an ongoing challenge for businesses that rely on regulatory compliance and traceability. 2,6-Dibromoaniline typically falls under a tighter regulatory framework than some of its basic cousins, mostly due to its roles in downstream drug and dye manufacture. This makes it important that suppliers not only offer pure product but also show commitment to responsible production and transparency.
There is real progress in “greener” chemical processes. Some facilities now design their synthesis routes to use less energy, generate fewer by-products, or run on solvents that are less harmful to workers and the environment. For 2,6-Dibromoaniline, these process tweaks can lower a company’s carbon footprint or simplify waste treatment, ticking boxes for both compliance and long-term sustainability. My own experience in process optimization projects taught me the value of even small changes, since a tweak that reduces hazardous waste carries benefits from the shop floor to compliance departments—and on to the communities surrounding production facilities.
2,6-Dibromoaniline does demand respect in handling. Safety doesn’t just come down to what’s written on a data sheet. Lab veterans, especially those who work with aromatic amines or halogen compounds, understand that even a reliable chemical brings its own set of risks. Proper PPE, good ventilation, and routine equipment checks are part of daily life—hard-earned lessons from people who have seen firsthand what can go wrong.
Regular safety briefings and honest discussions about risk build a culture where workers stay vigilant, not just compliant. I’ve seen shop floor teams spot problems early because they understood how even a small change in the chemical's appearance or odor might signal a storage or transport issue. Building a team with hands-on awareness always beats relying solely on labels and checklists.
For firms sourcing 2,6-Dibromoaniline, price isn’t the only factor, though it’s always part of the equation. The global market still feels ripples from fluctuations in raw material costs, as bromine supply depends on mining and refining trends, regulatory policies, and logistics costs. In my own work, I’ve seen firsthand how unpredictable price swings can disrupt R&D timelines or even product launches. The companies that plan ahead, maintain strong supplier relationships, and stay agile weather these storms with less disruption. Investing in good forecasting matters as much as investing in the right reagents.
On the user side, the decision to pick 2,6-Dibromoaniline over similar compounds often comes down to a balance of yield, process stability, and the desired characteristics in the final product. Some companies have pivoted quickly to alternatives during supply crunches, but when consistency and specific downstream properties are at stake, sticking with proven intermediates often wins out. Long-term, these calculations influence not just procurement, but also research direction and staff training.
What excites many in this industry is watching how a molecule like 2,6-Dibromoaniline inspires new reactions and products. Creative chemists leverage its unique reactivity to develop methods that produce less waste, use milder conditions, or unlock new product lines entirely. Cross-coupling reactions that seemed out of reach a decade or two ago now run more predictably and with higher yields, in part because the input chemicals offer higher purity, better stability, and well-understood behavior.
In practice, the quest goes on to find even better routes: catalytic systems that avoid heavy metals, alternative starting materials sourced from renewables, and partnerships across borders to streamline production and shipping. Often, 2,6-Dibromoaniline finds itself as a testbed for these new technologies, as companies search for the sweet spot between cost, safety, environmental impact, and performance.
My years in the field have reinforced a simple truth: the best progress comes from open, honest collaboration. Chemical buyers, process chemists, safety officers, and suppliers all have a stake in the quality and stewardship of products like 2,6-Dibromoaniline. Open communication, detailed product histories, and a willingness to share information build long-term business and technical relationships.
I have seen innovation flourish in settings where companies share successes and setbacks around process improvements, regulatory compliance, or safety issues. This exchange not only builds institutional knowledge, but also leads to fewer repeated mistakes and safer, more efficient production environments. Companies willing to share production data and safety practices offer not just a product, but peace of mind—and that counts for more than most marketing words will convey.
Addressing challenges in sourcing, safety, and sustainability isn’t just about responding to problems as they arise—it’s about building resilience and foresight into every step of chemical handling and production. One solution I’ve seen make a real difference lies in working directly with a small pool of trusted suppliers who demonstrate commitment to best practices. Robust supplier audits, detailed batch documentation, and responsive customer support create a support network that can catch problems early.
On the technical side, investment in automated, real-time analytics can turn reaction monitoring from an afterthought into a proactive step. Such investments allow production and quality teams to spot deviations early, avoiding full-batch failures and keeping product release schedules on track. I’ve been impressed by labs that put as much effort into continuous monitoring as into process optimization.
From a regulatory angle, building compliance into the DNA of company culture keeps staff alert to changing requirements and looming audits, which for intermediates like 2,6-Dibromoaniline can mean the difference between broad market access and lost contracts. Involving teams directly in policy updates and inviting their input ensures a sense of ownership that no compliance officer alone could foster.
Day-to-day, 2,6-Dibromoaniline likely escapes public notice, yet its presence shapes products across industries. Users downstream rely on the unique properties it brings—its reactivity, stability, and the precision allowed by its unique configuration. The value extends beyond cost per kilogram; it appears in higher yield, cleaner reactions, fewer hiccups during scale-up, and a smoother path through regulatory reviews.
Companies choosing 2,6-Dibromoaniline weigh not just the price, but also reliability, supplier support, environmental footprint, and alignment with long-term research or business goals. In a field where a single impurity or reactive hiccup can throw off months of work, that kind of dependability stands out. In several projects, I’ve watched the right input—one that’s well-documented, consistently sourced, and known behaviorally—turn a tricky process into a reliable production run, turning lab promise into market reality.
Today’s challenges in specialty chemicals rarely yield to off-the-shelf solutions. The best outcomes usually come from thoughtful integration of field experience, open data sharing, persistent improvement, and a clear-eyed look at real-world needs and risks. With 2,6-Dibromoaniline, as with other building block chemicals that quietly underpin entire industries, sustainable progress depends on this mindset. It’s about more than sales volumes or technical specs; it’s about understanding what matters to everyone along the chain, from those measuring out grams in the lab to those signing off on shipping blenders of final product. From this perspective, building a future on transparent relationships, responsible manufacturing, and real technical expertise is not just good business—it’s the only way forward.
