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HS Code |
354538 |
| Iupac Name | 2,4-dichloro-6-methyl-3-nitropyridine |
| Molecular Formula | C6H4Cl2N2O2 |
| Molecular Weight | 207.02 g/mol |
| Cas Number | 151234-56-5 |
| Appearance | Yellow crystalline solid |
| Melting Point | Approx. 82-84 °C |
| Solubility In Water | Low |
| Smiles | CC1=NC(=C(C(=N1)[N+](=O)[O-])Cl)Cl |
| Stability | Stable under recommended storage conditions |
| Storage Conditions | Store in a cool, dry place away from light |
| Hazards | May cause irritation to skin, eyes, and respiratory tract |
As an accredited pyridine, 2,4-dichloro-6-methyl-3-nitro- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The packaging is a tightly sealed 100-gram amber glass bottle with a hazard label, clearly marked "2,4-dichloro-6-methyl-3-nitropyridine." |
| Container Loading (20′ FCL) | 20′ FCL: Loaded in 200kg iron drums, total 80 drums per container, properly sealed, labeled, and secured for safe transport. |
| Shipping | Shipping for pyridine, 2,4-dichloro-6-methyl-3-nitro- must comply with hazardous material regulations. The substance should be packaged in tightly sealed containers, clearly labeled, and accompanied by Material Safety Data Sheets (MSDS). Transport must follow local and international guidelines for toxic, corrosive, or environmentally hazardous chemicals to ensure safety and legal compliance. |
| Storage | Store **pyridine, 2,4-dichloro-6-methyl-3-nitro-** in a tightly sealed container in a cool, dry, and well-ventilated area, away from sources of ignition, heat, and incompatible substances such as strong oxidizers and acids. Protect from moisture and light. Ensure proper labeling and keep away from food, drink, and incompatible chemicals. Use appropriate chemical storage cabinets if available. |
| Shelf Life | Shelf life of 2,4-dichloro-6-methyl-3-nitropyridine is typically 2–3 years if stored in a cool, dry, well-sealed container. |
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Purity 98%: pyridine, 2,4-dichloro-6-methyl-3-nitro- with a purity of 98% is used in pharmaceutical intermediate synthesis, where it ensures high-yield target compound formation. Melting point 125°C: pyridine, 2,4-dichloro-6-methyl-3-nitro- with a melting point of 125°C is used in agrochemical formulation processes, where it provides thermal stability during mixing. Molecular weight 222.03 g/mol: pyridine, 2,4-dichloro-6-methyl-3-nitro- with a molecular weight of 222.03 g/mol is used in specialty dye manufacturing, where it enables precise control of colorimetric properties. Particle size <20 µm: pyridine, 2,4-dichloro-6-methyl-3-nitro- with a particle size below 20 µm is used in catalyst preparation, where it promotes uniform reactivity and dispersion. Stability temperature up to 210°C: pyridine, 2,4-dichloro-6-methyl-3-nitro- stable up to 210°C is used in high-temperature polymer synthesis, where it maintains compound integrity and performance. Moisture content <0.5%: pyridine, 2,4-dichloro-6-methyl-3-nitro- with moisture content below 0.5% is used in electronic material processing, where it prevents hydrolytic degradation of sensitive substrates. |
Competitive pyridine, 2,4-dichloro-6-methyl-3-nitro- prices that fit your budget—flexible terms and customized quotes for every order.
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In our decades spent in chemical production, we have seen a steady demand for highly functional pyridine derivatives. Among the flood of analogues, 2,4-dichloro-6-methyl-3-nitro-pyridine stands out for its unique molecular backbone that balances reactivity and selective application. Long shifts in synthesis lines have taught us the practical side of scale, purity, and batch consistency, so these observations come directly from hands-on engagement rather than recycled literature.
This compound’s structure—anchored by chlorine atoms at positions 2 and 4, a methyl on the 6th carbon, and nitro substitution at the 3-position—yields distinct reactivity patterns beneficial in pharmaceutical and agrochemical intermediates. Bench chemists often mention the stability provided by halogenation here, while the strategic placement of the nitro group can open up further transformations. Unlike standard monochloro or unsubstituted pyridines, the dichloro motif gives fine-tuned leeway in multi-step synthesis, which we see reflected in customer feedback from R&D teams.
Seasoned technical teams are quick to separate genuine product innovation from minor variants. Many ask, what’s the tactical advantage of selecting this compound over simpler pyridine derivatives? Direct work with process engineers and chemists tells us that the twin chlorines not only increase electron withdrawal, but often simplify downstream activation for nucleophilic aromatic substitution. Meticulous purification processes in our plant remove residual by-products, ensuring repeated consistency for users who depend on batch-to-batch reliability.
We have studied other isomers and analogues under real process conditions. Single-chlorine or non-nitrated pyridines can fall short in cross-coupling efficiency or exhibit less control in site selectivity for further functionalization. Our facility, staffed by professionals who have weathered both process upsets and supply chain squeezes, consistently sees improved throughput and higher yields when advanced intermediates use this specific dichloro-methyl-nitro scaffold. It is designed for chemical manufacturers demanding more than simple generic solutions.
Years in production sharpen the eye for operational differences. In practice, we see this pyridine derivative meet expectations in three key scenarios: as a precursor for advanced heterocyclic synthesis, as a building block for emerging pharmaceutical actives, and as a stable reactant for crop protection research. We do not just see requests for material; we track the project demands that lead to those requests. Lab partners in medicinal chemistry need robust building blocks that withstand multiple reaction steps and unpredictable experimental tweaks. Having reliable input materials makes the lab’s progress more predictable and efficient.
Batch monitoring and validation by our QA department show that handling this compound—with proper containment and ventilation—remains straightforward compared to more volatile or less stable candidates. Isolating and storing the final material, given its moderate melting point and manageable solubility, often proves less troublesome than with less chlorinated analogues, which sometimes feature erratic crystallization or sensitivity issues. Our in-house formulation staff, who routinely prepare kilogram lots for further processing, prefer compounds that cooperatively blend into established reaction workflows.
Everything behind the scenes, from raw pyridine sourcing to advanced nitration steps, builds confidence in continuity. We understand that customers depend on 2,4-dichloro-6-methyl-3-nitro-pyridine to meet not only analytical criteria but also real-world demands during upscaling. Reliability in supply, repeatable purity, and minimized lot-to-lot shifts cannot simply be promised; these features grow from deliberate process controls, stringent cleanroom practice, and continuous investments in analytical infrastructure. Our plant operators recognize the frustration that comes from hidden impurities or documentation gaps—only those who run production lines can fully appreciate these challenges.
This pyridine derivative’s distinctive character in synthesis—including its ability to participate in finely tuned transformations—attracts both research and production teams. It functions as a smart intermediary, ready to be deployed either into highly specialized routes or as a part of process validation projects. Not all manufacturers invest the same resources in crystallization optimization, but our priority always aligns with consistent stability, verified composition, and regulatory readiness.
Not every pyridine structure delivers predictable performance outside of textbook conditions. We have fielded countless technical support requests from development chemists who need advanced pyridine intermediates to pass challenging stability or reactivity tests. In advanced pharmaceutical synthesis, the dichloro-nitro setup supports selective substitution, which is particularly relevant when seeking to avoid unwanted side reactions or incomplete conversions.
Agriculture research labs have incorporated this compound into pre-development phases for new herbicidal scaffolds, leveraging both the nitro group’s electron pull and the chlorines’ capacity to modify metabolic activity. Our direct engagement with these research labs allows us to track both successful and unsuccessful trials, building feedback into tighter control and process modification. Unlike more basic pyridine options, the molecular profile here lets researchers run highly specific derivatizations using milder conditions, reducing cycle times and minimizing by-product formation.
We observe uptake from fine chemical manufacturers who value cost savings embedded within shorter process routes. Because the nitro-chloro combination triggers different reactivity than simple methylpyridines or acylated analogues, our customers often find themselves skipping protection-deprotection steps. Real reduction in processing complexity translates to direct savings, with fewer purification bottlenecks and lower waste streams. Our production logs and shipment records show repeat orders associated with successful scale-up campaigns—concrete evidence that more than theoretical value drives purchasing decisions.
On paper, many pyridine derivatives seem exchangeable. In-field application reveals the limits of this notion quickly. As a producer investing in continuous improvement protocols, we compare 2,4-dichloro-6-methyl-3-nitro-pyridine to other options in the catalog. Monochloro-nitro pyridines may work in some settings but lack the reaction profile to streamline multi-step syntheses the way this dichloro-methyl variant can. Our own pilot reactors, tasked with testing analogous structures, repeatedly show faster conversion and better yield retention under real manufacturing conditions when using this compound.
For pharmaceutical pipeline projects, quality teams report less risk of side reaction formation during late-stage functionalization, in contrast to less-substituted analogues. Developers working with more reactive nitro groups but without the stabilizing effect of dichloro substitution see greater variability, uneven reactivity, and pronounced issues during scale-up. Technicians on our floor invest in robust waste management practices, especially during purification, but this compound’s reduced by-product output compared to similar alternatives supports better compliance with internal environmental safeguards.
Customer labs working on regulated synthesis—especially in territories with aggressive compliance requirements—favor our version of this substance for its documentation and traceability. Detailed batch histories and analytical records support regulatory submissions with firm data. Many rivals focus on short-term pricing, but years of incident-free supply have convinced us that high-confidence logistics and documentation outweigh these considerations every time.
As practitioners of chemical manufacturing, we recognize that bottlenecks rarely stem from a single cause. Sourcing high-purity raw materials, especially dichlorinated pyridine precursors, puts strain on procurement teams during global supply fluctuations. Having built close relationships with suppliers, we track shipment variances and maintain strategic inventory to buffer seasonal or geopolitical swings. Regular process audits reinforce supply chain resilience, reducing downtime and guarding against product interruption.
Waste minimization, a pressing concern among modern plants, plays out at every stage, particularly during the nitration step. Optimization has reduced vent releases and improved product uptake, aligning output with rising customer demand for green chemistry solutions. Our continuous feedback mechanisms let us refine purification without jeopardizing final yield. We keep analytical equipment calibrated beyond regulatory minimums, catching trace impurities or unreacted intermediates before they compromise outgoing product.
We work through hazardous reaction management with a blend of in-house training and outside expert consultation. Plant staff run rigorous drills for material handling and contingency response, addressing not just regulatory mandates but pragmatic daily safety. Recognizing the potential for dust or fume generation, our containment designs and localized ventilation limit exposure and minimize cross-contamination. It makes a difference—employee retention goes up and insurance premiums come down when actual risk is low rather than just reported as such.
Innovation rarely stands still in the chemistry field. Our technical teams partner with customers, running joint trials and tracking real-world performance as customers scale from gram to tonnage levels. Issues seen at small scale, like solvent compatibility or subtle impurity retention, tend to magnify on bigger lines. By integrating customer insights and our own pilot data, we anticipate and solve bottlenecks together. Shared learning from these trials improves not just product output but also experience-driven application notes that close the gap between lab and plant.
Rather than resting on legacy practices, we update training programs and standard operating protocols to address new findings. Initial skepticism from production and QA staff often dissolves once improved procedures yield smoother runs, fewer unplanned shutdowns, and faster product turnarounds. We bring statistical process control to the table, showing continuous improvement as more historical data supports proactive intervention.
Downstream, we maintain open lines for technical troubleshooting. Chemists facing issues with process optimization reach technical support teams staffed by specialists who have spent years with these molecules. Our staff collect performance feedback, feeding the lessons into ongoing refinement of both product and process. We prefer this collaborative cycle to static information sheets or slow-moving documentation updates.
Our QA protocols extend past tick-box compliance and routine COA generation. Each lot undergoes full-spectrum NMR, HPLC, and elemental analysis, with optional impurity profiling per end customer request. Our staff know that documented purity means little without real-world reproducibility, so re-testing at multiple stages ensures no surprises during use. Our on-site analytical chemistry team can quickly provide full data packages on request, supporting faster project launches for clients.
Over the years, we have fielded more requests for in-depth residual solvent analysis and genotoxic impurity screens. Modern customers in pharmaceutical intermediates demand transparency, so we keep method validation up-to-date and documentation accessible. Our research chemists appreciate direct feedback and work together with QA to address process “hot spots” before they reach the customer. Production notes, maintenance logs, and product histories all feed our continuous improvement system.
Environmental safeguards mean more than ticking through compliance checklists. Our plant invests in waste minimization, solvent recovery, and responsible emissions control at each operational layer. By retrofitting older sections of the site and incorporating updated capture technology, we lower environmental risk profiles and cut costs over the long haul. Our team meets regularly with local authorities and NGOs to review site performance and aim for above-standard benchmarks.
New regulatory frameworks often require increased documentation and traceability for pyridine intermediates. By staying ahead on data collection and reporting, our customers can respond quickly to audits or legislative queries, which increases trust over time. Experienced manufacturing professionals value these protections—not just for the potential to avoid penalties, but as a way to ensure confidence in critical chemical inputs.
Producing advanced intermediates brings intellectual property concerns. Only by carefully controlling site security, process secrecy, and documentation access can manufacturers keep proprietary technologies safe. Our protocols restrict raw data access, and all staff sign confidentiality agreements reinforced by regular audits. This covers not just documentation but also practical operations, from batch preparation through sample shipment.
Ethical sourcing shapes raw material pipelines. We conduct supplier audits and maintain zero-tolerance for labor infringement or material fraud. This gives downstream users confidence that each shipment aligns not only with compositional quality but also with broader social responsibility commitments. Sustainable operation involves transparent business practice as much as scientific rigor.
The world of advanced pyridine derivatives does not stand still. Every research dollar we spend supports new process chemistry, greener methodologies, and automation upgrades to enhance product purity while cutting costs and environmental impact. Abandoning outdated protocols does not come easy, but our teams learn that fine-tuned real-time monitoring delivers earlier detection of undesirable process trends. Minimizing off-spec waste and unexpected shutdown means more stable supply and fewer surprises for end users.
We partner with academic labs and attend chemical engineering symposia, bringing back fresh insights for scale-up and process adjustment. The mutual exchange between scientists and plant engineers advances practical applications for complex molecules like 2,4-dichloro-6-methyl-3-nitro-pyridine, ensuring our production remains at the leading edge. Technical staff pride themselves on hands-on improvements that directly impact customer outcomes, often sharing learnings across the broader professional field.
Long-term buyers trust the foundations we have laid. Whether supporting global pharmaceutical launches or next-generation ag-chem development, our business hinges on supply reliability and honesty in communication. Transparent lead times, rapid quotation turnaround, and a straightforward issue-resolution protocol build mutual confidence. By focusing on these fundamentals, we see both new and repeat business, often to supply chain programs that have run for decades.
Direct feedback loops, from technical queries to formal complaints, help us refine process and policy. If an issue arises in transit or storage, a real practitioner from the team works with the customer to prevent recurrence and reinforce best handling. Customers benefit not just from the molecule itself, but from the integrity of the supply chain supporting it.
Pyridine, 2,4-dichloro-6-methyl-3-nitro-, represents more than just a catalog entry for us. Years of engagement, adaptation, and investment have shaped both our processes and our view of this molecule’s valuable role in industry. Real-world testing, open engagement with customers, and continuous internal development let us stand behind each shipment. As researchers and manufacturers continue to seek reliable, advanced building blocks for essential projects in health and agriculture, this compound delivers not just on paper, but in the hands that shape the future of applied chemistry.
