© 2026 Sinochem Nanjing Corporation,
All Right Reserved
|
HS Code |
696848 |
| Cas Number | 99-30-9 |
| Chemical Formula | C6H4Cl2N2O2 |
| Molecular Weight | 207.02 g/mol |
| Appearance | Yellow crystalline powder |
| Melting Point | 188-192 °C |
| Solubility In Water | Slightly soluble |
| Density | 1.67 g/cm³ |
| Synonyms | 2,4-Dichloro-6-nitrobenzenamine |
| Purity | Typically ≥98% |
| Odor | Odorless |
As an accredited 2,4-Dichloro-6-Nitroaniline factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 100g package is a sealed amber glass bottle, labeled with hazard symbols, product name, formula, batch number, and manufacturer details. |
| Shipping | 2,4-Dichloro-6-nitroaniline should be shipped in tightly sealed, clearly labeled containers, away from incompatible substances such as strong oxidizers. It must be protected from moisture and physical damage. Comply with all regulatory requirements, including proper hazard labels and documents. Handle the chemical with care, using appropriate personal protective equipment during shipping and handling. |
| Storage | 2,4-Dichloro-6-nitroaniline should be stored in a tightly sealed, labeled container in a cool, dry, and well-ventilated area. Keep it away from incompatible substances such as strong oxidizers, acids, and bases. Protect from moisture and direct sunlight. Store at room temperature and segregate from food and drink. Ensure access to appropriate spill containment and safety equipment. |
|
Purity 98%: 2,4-Dichloro-6-Nitroaniline with 98% purity is used in pharmaceutical intermediate synthesis, where it ensures high yield and consistent product quality. Molecular Weight 207.02 g/mol: 2,4-Dichloro-6-Nitroaniline of molecular weight 207.02 g/mol is used in agrochemical active ingredient preparation, where it provides standardized dosing and reactivity. Melting Point 160°C: 2,4-Dichloro-6-Nitroaniline with a melting point of 160°C is used in high-temperature pigment manufacturing, where it offers thermal stability and color retention. Particle Size < 50 µm: 2,4-Dichloro-6-Nitroaniline with particle size less than 50 microns is used in formulation of specialty coatings, where it allows uniform dispersion and smooth surface finish. Stability Temperature up to 120°C: 2,4-Dichloro-6-Nitroaniline stable up to 120°C is used in industrial resin applications, where it maintains chemical integrity during processing. Water Content ≤ 0.2%: 2,4-Dichloro-6-Nitroaniline with water content lower than 0.2% is used in fine chemical synthesis, where it minimizes the risk of hydrolysis and enhances reaction efficiency. |
Competitive 2,4-Dichloro-6-Nitroaniline 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!
Chemistry drives so many of the things we take for granted, whether it’s the vivid pigments in a favorite shirt or the compounds that shield crops from ruin. 2,4-Dichloro-6-Nitroaniline carries itself quietly but brings a lot to the table, especially across the textile, dye, and agricultural sectors. As someone who’s spent years keeping an eye on how building-block chemicals cycle through laboratories to everyday use, I see this compound as a telling example of how targeted innovation meets precise demand.
This compound stands out because it combines two chlorine atoms and a nitro group with an aniline core, making it more resilient and adaptable for a range of chemical synthesis tasks. At a molecular level, these features grant it the structure that dye-makers and crop scientists look for – a structure that brings stability when mixing with other chemicals. Over the years, experienced chemists have learned that this particular setup isn’t just more effective, it also interacts more predictably with other components.
In real terms, most companies seek out 2,4-Dichloro-6-Nitroaniline as a yellowish powder, known for its high melting point and remarkable thermal stability. Most lots are tightly controlled for purity, often exceeding 98%, because contaminants can throw off the performance in finishing applications, especially when pigments or herbicide intermediates are at stake. Every batch typically gets tested for moisture content, particle size, and the absence of volatile organic residues, since these factors shape how the compound will blend, react, or store.
Back in the lab, we used to spar over whether the extra spent on a higher-purity lot would pay off down the line with better color yield or a cleaner reaction. It always did. Consistently high-purity material made work easier and results more reliable. From a practical perspective, having a compound like this in the right form means you’re not gambling with hours of processing or with a full reactor of product, just because one reagent didn’t come through. Long story short, high-purity and precise particle size matter not only for quality but for saving time and reducing waste in scaled-up processes.
Most people outside of specialty chemistry haven’t heard of 2,4-Dichloro-6-Nitroaniline by name, but if you look at the pigments used in outdoor paints or technical textiles, you’ll see its legacy. Developers prize it for synthesizing disperse dyes because its particular molecular makeup helps anchor colors more sturdily to synthetic fibers. From sportswear to car interiors, the fastness and weather resistance of color often trace back to this compound somewhere down the manufacturing pipeline.
In the realm of crop protection, this compound forms an intermediate in herbicide production. We’ve seen it help control weed growth, giving more breathing room to cultivated plants in crowded fields. Chemical intermediates like this get lots of scrutiny, but 2,4-Dichloro-6-Nitroaniline often passes rigorous tests for efficacy and compatibility with other formulation agents. The agricultural sector likes it because it can take a beating in the soil and break down at rates that make sense for modern stewardship practices.
Through experience, it’s clear that not all aniline-based intermediates wear the same shoes, so to speak. Some alternatives may deliver on pigment vibrancy but lose out on long-term fading or chemical resistance. Others mesh poorly with downstream processing, causing stubborn residues or clogging up filtration systems. 2,4-Dichloro-6-Nitroaniline strikes a practical balance. The dual chlorine substitutions bring finer control over how the molecule couples in multistep syntheses, cutting down on unwanted side reactions. In my work, I’ve seen competitors opt for single-chlorine or mono-nitro variations to save cost, then turn back once the performance gap widens.
By comparison, some dye intermediates lack the thermal stability to handle high-temperature fiber processing without distorting the final color. 2,4-Dichloro-6-Nitroaniline runs longer under heat without decomposing, which keeps the production line moving and the rejects pile smaller. It’s a small detail, but over thousands of meters of processed fabric or acres covered with protective formulations, the savings add up.
Anyone sourcing chemicals for a business faces constant choices. Is it worth partnering with a manufacturer who’s transparent about quality control, or do you roll the dice with a cheaper, bulk supplier? From personal experience, transparency wins. Reliable suppliers document their synthesis routes, run batch-level analytics, and guarantee impurity profiles, so downstream users don’t get hit with recalls or off-spec material. Whether used in dyes or crop aid, the source and purity level of 2,4-Dichloro-6-Nitroaniline can spell the difference between a year of smooth production and a headache of lost business or brand damage.
This matters even more with regulations evolving every year around safety and environmental responsibility. Sourcing from suppliers who offer clear origin documentation and batch traceability isn’t just a box-ticking exercise; it keeps buyers out of trouble and protects workers. During audits and third-party inspections, clear records on lot specifications, heavy metal testing, and absence of banned residues make compliance much easier.
The thing about 2,4-Dichloro-6-Nitroaniline is that it often travels a long road before landing in a finished product. Some see just a drum of powder, but behind each lot are workers blending and isolating the compound, lab specialists confirming purity, and end users expecting consistent performance. On factory floors, safe handling rules take precedence because, like many chlorinated aromatic compounds, it demands respect. Safe storage in cool, dry environments and attention to dust and spill control aren’t optional. My time in chemical manufacturing showed again and again how simple diligence in handling could reduce workplace exposure and keep shipment delays at bay.
Shipping and storage conditions also have more impact than folks might think. Exposure to moisture or heat doesn’t just weaken an active ingredient; it can transform how predictably it behaves in a formula. To this day, I check that inventory teams monitor lot turnover and keep detailed records, preventing issues where an out-of-date drum spoils a new product batch.
Every buyer in the sector faces a familiar tug-of-war. Do you spring for the higher-priced, purer lot, or stick with the minimum quality to meet specs? In my experience, the answer emerges clearly in the lab and on the manufacturing floor. Problems with inconsistent color, unexpected reaction byproducts, or poor herbicide shelf life almost always trace back to compromising on starting materials. Sure, bottom-line pressure runs high. Customers demand better performance without price hikes. But over the long haul, investment in cleaner and more predictable intermediates like 2,4-Dichloro-6-Nitroaniline really pays off—lower rework rates, fewer batch failures, and a stronger reputation.
I recall a textile partner who initially sourced lower-grade intermediates for disperse dyes, only to face mounting complaints over color fading and uneven fabric lots. The cost of remediating products, coupled with customer returns, ate into any initial savings. Only by switching to a higher-quality supply chain for the chemical intermediates did performance stabilize. You learn quickly that saving a few dollars per kilogram upfront rarely matches the cost of a reputation hit or loss of a key customer.
Handling and using chlorinated intermediates raises understandable questions about workplace safety and environmental stewardship. No one should brush off these risks. Modern production standards rely on proper ventilation, protective gear, and rigorous monitoring to limit exposure. The reality is that the risk control practices seen today reflect decades of hard-learned lessons. For instance, having clear emergency procedures, spill containment plans, and employee training sessions keeps accident rates down and ensures everyone heads home safe.
On the environmental front, countries and regions increasingly demand lifecycle transparency. That means full disclosure about how a chemical is manufactured, used, and eventually broken down or disposed. With growing regulatory oversight, suppliers must document not only safety data but also analytics about biodegradability and potential for environmental persistence. In my view, the industry has moved in the right direction by focusing on lower-emission processes for producing intermediates like 2,4-Dichloro-6-Nitroaniline and by developing improved waste capture and treatment methods.
The story of 2,4-Dichloro-6-Nitroaniline doesn’t stand still. New research in dye chemistry leans on this compound for brighter, more wash-resistant colors on tough synthetic fibers. As technical fabric markets grow for sportswear, outdoor gear, and industrial safety clothing, the properties of dyes made with this intermediate get put to the test. Each improvement, such as finer powder grades for easier dispersion or modified derivatives for lower toxicity, opens new avenues.
In crop protection, shifts in climate and pest resistance patterns push researchers to revisit known intermediates and tweak their utility for safer, more targeted action. It’s not just about boosting yield anymore; it’s about doing it responsibly, with formulas that leave fewer residues in soils and waterways.
Looking ahead, demand for smaller production footprints and cleaner reaction processes may drive changes in how this compound gets produced and applied. Tech advances such as continuous flow chemistry, green solvents, and better recycling of chlorinated wastes are gaining traction. The companies leaning into these improvements may set a new bar for sustainability without compromising on performance.
Addressing challenges around 2,4-Dichloro-6-Nitroaniline calls for practical changes in sourcing, usage, and lifecycle management. On the supply side, buyers can work with producers who deploy real-time quality analytics and full disclosure on origin and manufacturing processes. This lets everyone from lab technicians to procurement managers make better decisions and quickly flag any inconsistencies.
For handling and storage, best practices revolve around regular employee training and investments in better inventory systems. Facilities that log batch use and institute clear cycle-count routines avoid the pitfalls of using degraded or out-of-spec lots. Even small improvements here prevent bigger downstream issues.
Process engineers can play a role by pushing for innovations such as solvent recycling, recovery of processing byproducts, and optimization of reaction conditions. In many facilities where I’ve consulted, such shifts not only improved safety and reduced environmental impact, but also trimmed energy costs and improved bottom lines.
For regulatory compliance, teams must stay up to date on evolving standards in every market they serve. Subscribing to reputable regulatory alerts or working with compliance consultants keeps a company ahead of rule changes, especially in heavily regulated sectors like agriculture and textiles. Documentation—clear, complete, and regularly updated—goes a long way during audits and helps maintain trust with supply partners and customers.
Lastly, downstream users—whether dye formulators or field agronomists—can demand more transparency, better customer support, and real-world data from suppliers. Such feedback loops push everyone in the value chain to up their game, from synthesis to final application.
Experience teaches that trust is earned daily, from the way suppliers respond to a question about batch origin to the consistency of a product’s performance over time. In my career, providers who offered extra context—explaining not just the specs but the thought process behind a manufacturing change—got more business and sparked deeper partnerships. At the end of the day, those closest to the details, whether on the lab bench or in the purchasing office, want reassurance that each purchase moves their goals forward.
The chemical supply world keeps shifting, with trends in green chemistry, tighter safety expectations, and greater international scrutiny. Rather than stick with the bare minimum or cut corners, suppliers and buyers alike can see more value in sharing knowledge, documenting improvements, and supporting upgrades that benefit users and the broader public.
Choosing and working with 2,4-Dichloro-6-Nitroaniline isn’t just a technical call. It touches on safety, environmental responsibility, efficient plant operations, and end user satisfaction. The difference lies in treating the compound as more than a commodity, giving attention to where and how it’s made, and adjusting operations as the sector matures. For those who care about consistent results, responsible sourcing, and real-world performance, this approach clears the path for solid growth and lasting trust—qualities that, in my experience, mean as much to a successful business as any single product feature.
