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HS Code |
440492 |
| Product Name | 2,4-Dichlorobenzonitrile |
| Synonyms | 2,4-DCBN; Benzonitrile, 2,4-dichloro- |
| Cas Number | 1194-65-6 |
| Molecular Formula | C7H3Cl2N |
| Molecular Weight | 172.01 g/mol |
| Appearance | White to off-white crystalline powder |
| Purity | ≥99.0% |
| Melting Point | 74-77 °C |
| Boiling Point | 298 °C |
| Density | 1.41 g/cm³ |
| Solubility In Water | Insoluble |
| Flash Point | 138 °C |
| Smiles | C1=CC(=C(C=C1Cl)Cl)C#N |
| Storage Temperature | Room temperature, tightly closed |
As an accredited 2,4-Dichlorobenzonitrile (≥99.0%) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 2,4-Dichlorobenzonitrile (≥99.0%), 100g, is supplied in a sealed amber glass bottle with hazard and identification labeling. |
| Shipping | 2,4-Dichlorobenzonitrile (≥99.0%) is shipped in tightly sealed containers that comply with relevant hazardous goods regulations. Packaging ensures protection from moisture, physical damage, and contamination. Transport typically follows guidelines for toxic solids, with labeling and documentation in accordance with international and local shipping standards for chemical substances. |
| Storage | 2,4-Dichlorobenzonitrile (≥99.0%) should be stored in a tightly closed container, in a cool, dry, and well-ventilated area away from direct sunlight and incompatible substances such as oxidizing agents. Keep the chemical away from moisture and ignition sources. Ensure appropriate labeling and access restricted to trained personnel. Follow all relevant safety guidelines and chemical storage regulations. |
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Purity: 2,4-Dichlorobenzonitrile (≥99.0%) is used in the synthesis of herbicides, where high purity ensures optimal yield and minimal byproduct formation. Molecular Weight: 2,4-Dichlorobenzonitrile (≥99.0%) is used in pharmaceutical intermediate manufacturing, where precise molecular weight contributes to accurate dosage formulation. Melting Point: 2,4-Dichlorobenzonitrile (≥99.0%) is used in industrial crystallization processes, where a consistent melting point achieves uniform crystal morphology. Stability Temperature: 2,4-Dichlorobenzonitrile (≥99.0%) is used in polymer modification, where high stability temperature maintains integrity during high-temperature reactions. Particle Size: 2,4-Dichlorobenzonitrile (≥99.0%) is used in chemical reagent preparation, where controlled particle size enables rapid and uniform dissolution. Water Content: 2,4-Dichlorobenzonitrile (≥99.0%) is used in agrochemical formulations, where low water content reduces hydrolysis risk and maintains shelf life. Solubility: 2,4-Dichlorobenzonitrile (≥99.0%) is used in specialty chemical research, where high solubility enables efficient compound screening and reaction setup. Assay: 2,4-Dichlorobenzonitrile (≥99.0%) is used in analytical reference materials, where certified assay value provides reliable calibration results. |
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Throughout my years working alongside both researchers and production teams, I’ve seen certain compounds quietly underpin the successes of entire projects. 2,4-Dichlorobenzonitrile (≥99.0%) belongs to this unsung group. Chemists reach for this chemical again and again, not out of habit, but because it gets results where precision matters. Its chemical structure, with two chlorine atoms set at the 2 and 4 positions on the benzene ring—combined with a cyano group—brings a kind of versatility that’s hard to replace.
There’s a world of difference between a generic intermediate and a product offering ≥99.0% purity. In my own lab experience, lower-purity reagents often introduce headaches by feeding trace impurities into reactions. Over time, these impurities pile up, affect product purity, complicate downstream purification, and—frankly—cost more in lost time and resources than any savings from buying cheaper material. This extra measure of purity can be the difference between clear, reproducible results and a lingering doubt about where that odd peak on the NMR came from.
Model specifications for this grade of 2,4-dichlorobenzonitrile typically describe a fine, crystalline solid. The sharp melting point and stable physical form allow easy creation of standard solutions, crucial for anyone working on analytical method validation or quality assurance in pharmaceutical and specialty chemical settings. During scale-up, I’ve watched how lower-purity batches lead to sticky residues or off-white solids—nothing inspires confidence like a batch that pours clean and matches reference spectra without question.
Uses for 2,4-dichlorobenzonitrile expand across several industries. Synthetic organic chemists often turn to the molecule as an intermediate—its dual reactivity (from both the nitrile and the chloro substitutions) enables a range of transformations. I’ve seen it take a starring role in the creation of agrochemicals, dyes, and advanced materials. In one memorable case, our team used it as a key building block for a new class of herbicide, trusting its solid track record for reliable reactivity. The nitrile group, less prone to unwanted side reactions, carries a sort of quiet stability that allows it to survive multiple synthesis stages without trouble.
Engineers in industrial settings appreciate its consistent handling and storage parameters. 2,4-Dichlorobenzonitrile doesn’t demand elaborate containment—standard cool, dry, ventilated storage covers most needs. This practical side of things can sometimes get overlooked, but ask any plant operator: stable supplies and easy storage matter just as much as chemical properties.
When I compare this product’s high purity with alternatives, I always think about the end user. Cheaper commercial grades often skimp on purification, leaving trace contaminants—unreacted chlorobenzene or byproduct isomers—that can trigger a cascade of problems. In antioxidant synthesis, for example, researchers might notice yield drops or unwanted byproducts when using lower-purity materials. ≥99.0% purity means these worries fade into the background, letting teams focus on optimizing their process instead of troubleshooting avoidable mistakes.
If you’ve ever run a pilot batch only to discover persistent color issues in the final product, there’s a good chance trace contaminants are the culprit. The clean performance of this high-grade 2,4-dichlorobenzonitrile reduces such risks in everything from pharmaceutical APIs to high-value pigments. From my perspective, investing in top-purity reagents returns its value many times over in the time saved during both bench work and scale-up. Avoiding repeated purification steps or unexpected side reactions pays off not just in fewer headaches, but in actual cost savings—a fact too often ignored in procurement discussions.
Working with 2,4-dichlorobenzonitrile on a day-to-day basis teaches respect for its properties. This isn’t a compound that demands constant vigilance, but that doesn’t mean handling should get lax. Its powdery nature lends itself to tidy weighing and dissolution, but I’ve seen open containers left uncovered, only for ambient humidity to clump the material. Good practice—double-bagging, careful use of desiccators—preserves product quality and eases every measurement. Proper ventilation minimizes any discomfort from dust or vapor, a small thing that makes a long day’s work easier for staff down the line.
Factory and warehouse teams tend to prefer chemicals that won’t surprise them with drastic changes in heat or moisture, and 2,4-dichlorobenzonitrile’s dependable stability—you won’t see it decompose unless grossly mishandled—means less training time and fewer accidents. Routine PPE and standard good lab practices serve well here. In my view, fostering a culture of respect rather than fear around such chemicals builds better habits and safer workplaces.
It’s easy for non-chemists to overlook how a single impure batch can send a domino line of problems down a long supply chain. Having supervised pilot plants for several drug development programs, I’ve learned not all costs show up in initial invoices. One pilot batch failed release specifications due to a sub-standard intermediate purchased for “cost savings” reasons—a lesson that stuck with management months after the project’s deadline slipped.
By choosing 2,4-dichlorobenzonitrile at ≥99.0% purity, both upstream reliability and downstream usability get a major boost. Chemists can troubleshoot synthesis issues faster, knowing their building blocks are what they claim. In analytical settings, clean baselines reduce the need for extensive method redevelopment. Final products shine brighter, with fewer background contaminants muddying HPLC or GC analyses.
Decades in both industrial and academic environments taught me that trust builds slowly, batch by batch. 2,4-Dichlorobenzonitrile at this purity consistently meets the expectations set by serious users. Regulatory filings lean heavily on reliable lot histories and repeatable results; surprises—even rare ones—erode confidence, so tight control over process impurities becomes non-negotiable. I’ve witnessed regulatory teams breathe easier knowing their chain of custody includes high-purity reagents with matched certificates of analysis. Auditors move on quickly when documentation matches real-world performance.
Academic researchers, focused on mechanism or synthesis innovation, see this product’s purity as a baseline, not a luxury. Cleaner starting materials mean fewer unexpected variables. As a postdoc, I once wasted weeks isolating what turned out to be an impurity from a sub-par raw material. These lessons stay with you: buy the best, do better science.
A lesser-discussed benefit of top-purity chemicals lies in waste minimization. Waste disposal remains both a regulatory and an environmental concern in modern operations. I’ve seen plenty of plants forced to ramp up secondary treatments or solvent cycles just to clean up after poor-quality starting materials. High-purity 2,4-dichlorobenzonitrile goes further per unit added, leaving behind less unreacted material and byproducts.
In green chemistry initiatives, minimizing process waste begins right at reagent choice. With strict environmental targets growing ever tighter, there’s wisdom in picking products that simplify both the process and clean-up. Cleaner inputs result in cleaner outputs, fewer unexpected residues, and smaller environmental footprints. This holds true whether a company is pursuing ISO certification or simply aiming to reduce its hazardous waste streams.
Ask any operations manager and you’ll hear the same story: consistent supply trumps everything. 2,4-Dichlorobenzonitrile with ≥99.0% purity tends to come from suppliers who recognize the cost of variability. These professionals know that a single off-spec batch can delay an entire production run, lose a key client, or, in some regulated fields, put a whole product line in jeopardy.
During the global disruptions of recent years, sourcing managers learned hard lessons about building redundancy into supply chains. Reliable sources for this product build strong relationships by delivering on both purity and logistical promises. I’ve watched teams scramble to recertify new suppliers only to return to their original source for dependable quality. In my view, that trust pays dividends beyond any single transaction.
It seems like every successful R&D department hosts regular meetings reviewing material specs and past performance. Conversations often pivot around products like 2,4-dichlorobenzonitrile, not just for technical details, but for shared learning. When chemists share real-world feedback—how a product behaved under process stress, or how its purity sped up method development—the quality cycle improves for everyone. Such feedback circles keep both supplier and user honest and focused on continuous improvement.
In academic collaborations, higher-purity reagents encourage faster reproducibility between groups. Results travel cleanly between research labs, making collaborations less about troubleshooting and more about pursuing new questions.
Some might look at the higher sticker price for ≥99.0% 2,4-dichlorobenzonitrile and balk. From firsthand experience, though, the upfront difference becomes insignificant compared to time saved in rework or lost material. In several projects, underperformance started at the raw material phase, multiplying small errors into big problems. Project managers often revisit earlier steps only to realize a modest increase in source material quality would have kept the whole timeline on track.
Laboratory and plant budgets operate in the real world, where every cost must show value. The case for premium-grade inputs grows stronger as processes scale up. Instead of spending staff hours on extra purifications or impurity tracking, those hours go towards improving product, shortening process time, or advancing new development. This focus on high-value work, not repetitive cleanup, marks the difference between an efficient operation and a resource-draining one.
With industries becoming more global, alignment with international standards grows ever more important. Regulatory bodies keep raising the bar for documentation, traceability, and raw material consistency. Here, 2,4-dichlorobenzonitrile (≥99.0%) stands out as a sure bet for companies looking to serve both domestic and overseas clients. Reliable compliance keeps contracts running and products moving without interruption. My time working with multinational firms taught me a good reputation in raw material sourcing translates directly into expanded business and smoother audits.
Feedback from global customers often highlights the same strengths: consistent batch-to-batch quality, traceable origins, and unambiguous specification sheets. High-quality products simplify cross-border transfers, too, avoiding arguments over minor test results or retesting delays. For growing firms, these little advantages add up quickly.
Whether you’re running small-bottle benchtop reactions or scaling up to tonnage in a flow reactor, working with 2,4-dichlorobenzonitrile at this level offers practical benefits across every role. Speaking as someone who’s moved between both types of work, it’s clear that pure raw materials reduce troubleshooting time and build staff morale. Repeatedly contending with avoidable contaminants drains even the most dedicated teams. Clean starts let creativity and efficiency shine.
For process engineers, it’s easier to model reliable yields and expect consistent behavior when starting points don’t shift with every batch. For new technicians, experience with premium chemicals builds good habits—demonstrating that careful measurement and attention to quality are not corner-cutting, but foundational scientific principles. Over time, these expectations raise the whole enterprise, setting high standards for incoming staff and long-term partners alike.
Trust in high-purity chemicals depends on more than the product inside the bottle. Transparent, complete labeling and certificates help everyone from warehouse clerks to regulatory reviewers. Each time I’ve worked with suppliers who stood behind their assay data, my own confidence—and that of my team—grew. Prompt answers to technical queries, clear batch traceability, and full-access documentation form the backbone of modern professional chemical use.
Problems inevitably surface, but clarity about what’s inside the drum or vial gives users better tools to solve them. Reputable producers of 2,4-dichlorobenzonitrile at ≥99.0% purity know their reputation hinges not just on chemistry, but on this honesty. As user demands outpace old-fashioned practices, transparency takes on greater value than ever.
Science never stands still. As new fields emerge—materials science, specialty polymers, advanced agrochemicals—demand grows for clean intermediates with documented history and performance. 2,4-Dichlorobenzonitrile finds itself drafted into ever-more challenging projects where reliability trumps all. Projects requiring robust, multi-stage synthesis use it not simply because it’s available, but because it’s proven, decade after decade, to do the job right.
With pressure mounting for more sustainable, efficient, and transparent production, industry leaders turn more and more to products with solid pedigrees and measurable results. New applications in fields like OLED materials or fine chemicals continue to emerge, leveraging the dual reactivity that 2,4-dichlorobenzonitrile brings. Teams combining creativity with rigorous process control reach for products with predictable structure and performance—cutting down on future work and opening new avenues for innovation.
Every year brings new challenges in the chemical industry. The teams I’ve worked with—spanning everything from small startups to multinational giants—agree that the foundation for quality always starts with trusted raw materials. High-purity 2,4-dichlorobenzonitrile doesn’t promise to solve every problem or transform production all by itself, but it does what it claims: lets professionals focus on the craft and science, rather than fixing basic avoidable issues.
It’s easy to overlook these everyday heroes of chemistry, yet without them, progress slows and risk creeps in. For any team looking to advance production, improve yields, or meet global regulatory standards, making the right choices at the start of the process makes all the difference. In my experience, that’s where genuinely high-purity products have always earned their keep—and continue to do so, batch after batch, project after project.
