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HS Code |
746012 |
| Chemical Formula | CnH2n+1Cl |
| Appearance | Colorless liquid or solid |
| Odor | Characteristic sweet odor |
| Solubility In Water | Insoluble to slightly soluble |
| Boiling Point | Varies, typically 50-200°C depending on chain length |
| Molecular Weight | Varies with alkyl group, e.g., 64.5 g/mol for chloromethane |
| Density | Approximately 1.0-1.5 g/cm³ |
| Flammability | Generally flammable |
| Reactivity | Undergoes nucleophilic substitution and elimination reactions |
| Stability | Stable under normal temperatures and pressures |
As an accredited Aliphatic Chloride factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Aliphatic Chloride is packaged in a 25-liter high-density polyethylene drum with secure sealing, labeled with hazard warnings and handling instructions. |
| Shipping | Aliphatic Chloride is shipped in tightly sealed, corrosion-resistant containers to prevent leaks and contamination. It should be transported in cool, well-ventilated vehicles, away from heat, ignition sources, and incompatible substances. Labels indicating hazardous chemical status are required, and proper documentation must accompany the shipment per regulatory guidelines. |
| Storage | Aliphatic chlorides should be stored in tightly sealed containers made of compatible materials, such as glass or specific plastics, and kept in a cool, dry, well-ventilated area away from heat, flames, and direct sunlight. They must be isolated from oxidizing agents, strong acids, bases, and moisture. Proper labeling and securing of storage areas are essential to prevent chemical reactions and accidental exposure. |
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Purity 99%: Aliphatic Chloride with purity 99% is used in pharmaceutical intermediate synthesis, where it ensures high yield and minimal impurities in the final product. Viscosity grade low: Aliphatic Chloride of low viscosity grade is used in specialty coatings manufacturing, where it enables smooth application and uniform film formation. Molecular weight 120 g/mol: Aliphatic Chloride with molecular weight 120 g/mol is used in polymer processing, where it contributes to consistent chain length and predictable polymer properties. Melting point 45°C: Aliphatic Chloride with melting point 45°C is used in agrochemical formulation, where it facilitates easy blending and precise dosing. Stability temperature 110°C: Aliphatic Chloride stable at 110°C is used in high-temperature reaction processes, where it maintains chemical integrity and prevents degradation. Particle size <50 µm: Aliphatic Chloride with particle size below 50 µm is used in catalyst carrier preparation, where it improves dispersibility and active site accessibility. Halogen content 35%: Aliphatic Chloride with halogen content at 35% is used in flame retardant production, where it enhances fire resistance and regulatory compliance. Water content <0.1%: Aliphatic Chloride with water content less than 0.1% is used in electronics manufacturing, where it reduces risk of hydrolysis and improves material longevity. Density 1.23 g/cm³: Aliphatic Chloride with density 1.23 g/cm³ is used in solvent mixture formulation, where it ensures accurate volumetric ratios and stability. Refractive index 1.430: Aliphatic Chloride with refractive index 1.430 is used in optical material synthesis, where it achieves precise light transmission and clarity. |
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If you’ve worked in chemistry, you know that not all chlorides behave the same. Aliphatic Chloride stands out in its category, showing up as a key ingredient across pharmaceuticals, dyes, and agrochemical work. The behavior of this type of chloride comes down to its structure: an aliphatic backbone, which leaves it less reactive than its aromatic cousins but steady and reliable for synthesis processes that require a predictable building block. Across the market, most conversations circle around purity, reactivity, and how these molecules play with other chemicals in a reaction. I’ve seen plenty of labs reach for this compound because it keeps surprises to a minimum, especially in scale-up batches.
Every synthesis project demands a slightly different twist, so suppliers list specific models or grades based on purity – usually measured in percentage points. One common model, for example, sits above 99% purity with low moisture and traced impurities, making it a dependable pick for pharmaceutical intermediates. This level of refinement doesn’t just raise the price tag – it often means stricter sourcing and packaging protocols, especially since low-level contaminants can throw off catalytic reactions or distort downstream targets.
Some manufacturers offer lower-purity technical grades aimed at bulk usage, like in plasticizers or basic chemical transformations. The difference between the two can be dramatic. High-purity versions are sealed in inert gas environments, with every batch tested for heavy metals, residual solvents, and other off-notes. Lower-purity options see wider fluctuations in those parameters and might come in standard drums rather than custom-lined containers. For folks in pharmaceuticals or electronics, those trace contaminants spell disaster. For folks cracking out tons of plasticizers, the small variations barely register.
Aliphatic Chloride has carved out its place in several big industries. In pharmaceuticals, think of it as a versatile road crew—laying the chemical pavement for more complex molecules. Many active ingredients build off these chlorinated backbones. Some might forget that this compound pops up in dozens of stepwise reactions where its reactivity plays a quiet, essential role. In the dye and pigment sectors, it shows up as a linking component, giving stability where high colorfastness and heat resistance are needed.
I’ve handled both aromatic and aliphatic versions across research projects. Aliphatic Chloride is easier to control—less likely to blow up a reaction or throw in unexpected side products. That stability speaks directly to anyone working with delicate intermediates. One of my former colleagues summed it up as “boring in the best way,” which in lab work is a huge compliment. A predictable reaction curve and easy removal after synthesis make it a favorite for teaching and industrial-scale production alike.
Agrochemical producers rely on this compound for herbicide intermediates and pesticide actives. The lower polarity compared to aromatic chlorides means it dissolves and disperses differently—a detail that creates an edge in slow-release or granule-type products. Technical staff can fine-tune application profiles, thanks to that slightly “slippery” behavior that lets it coat or bind to other substrates without clumping or degrading too quickly. You start to spot it in formulations that prioritize field stability or shelf life for sprayable products.
Another use that doesn’t always earn headlines: its part in surfactant and specialty plastic production. Polymer chemists seek out these molecules to modify chain length or introduce specific attributes (flexibility, thermal resistance, etc.) into their products. Compounds like this open up options for custom plastics—think wire jacketing, medical tubing, or industrial coatings—where the balance between cost and durability really matters.
People often stack aliphatic and aromatic chlorides up against each other. Aromatic types—like chlorobenzene—show far sharper reactivity, which might sound great for high-yield synthesis but also means a higher risk of runaway side reactions or hazardous by-products. Aliphatic Chloride, sitting in the “Goldilocks zone,” reacts at a measured pace. You get fewer surprises, especially in exothermic or multi-step processes. Bigger labs or manufacturers working with sensitive catalysts and reagents reach for the aliphatic version just to avoid reactivity headaches. I’ve heard veteran chemists use words like “workhorse” and “steady partner” to describe it. That’s earned, not given.
Availability also shifts. Aromatic chlorides tend to dominate in solvent markets or specific flavor/fragrance applications, while aliphatic versions focus on synthesis and performance materials. The cost angle is another real-world distinction. Sourcing aliphatic types in bulk can run higher since the production pathways take more energy and demand tighter controls on trace impurity levels. Even packaging gets more involved: tightly-sealed drums and moisture barrier linings pop up for high-end models. Aromatic products, with a longer shelf-life and wider market, tend to rely on basic packaging and shipping—it changes the handling but also the total project cost.
The conversation around chemical products has changed in recent years. Customers – especially large pharma and multinational manufacturers – now push hard on quality assurance and environmental impact. High-purity Aliphatic Chloride passes through rigorous quality checks. Every shipment requires traceability, batch records, and sometimes third-party testing for compliance with global regulatory standards. Back in the day, it wasn’t uncommon to find products cut with cheaper solvents or shipped with next-to-no safety data. Stricter monitoring has made this less common, but anyone working in procurement or QA knows to scan certificates of analysis and test results with a careful eye.
Environmental risks deserve real discussion. Aliphatic Chloride can bring worries about downstream pollution or workplace exposure. Responsible use starts with tight process controls: closed systems, stripped vapor releases, and good protective equipment as a baseline. Disposal must match current hazardous waste norms and aim for low-residue destruction, often through incineration with proper scrubber support. This isn’t only about staying legal – it reflects changing expectations everywhere from lab benches to public policy boards.
Some suppliers now highlight green chemistry steps, such as using renewable feedstocks or developing lower-emission synthesis routes. These steps often cost more upfront and can require adjusting legacy production lines. But the shift feels necessary. I’ve watched companies regret waiting too long, getting caught off guard by new reporting rules or investor questions about sustainability. Taking action on these concerns rounds out the case for high-quality, carefully-produced Aliphatic Chloride.
Choosing the right model or grade for a project makes all the difference. Too often, I’ve seen procurement chase the price tag, only to find that saving a few dollars on per-kilo cost introduces major headaches later: fouled catalysts, higher purification costs, or even regulatory violations. Teams work best when they let technical staff lead on product selection. Chemists and engineers offer insight on where saving on input costs undermines safety, output, or regulatory standing.
Storage is another point of frequent failure. Even a tightly-sealed Aliphatic Chloride drum picks up moisture and air if left in poor warehouse conditions. Once opened, the remaining product might degrade or react before its next use. Successful users keep inventory small and fresh, rotating stock instead of storing huge volumes for months or years. Some sites add nitrogen-purged storage or specialized monitoring, which brings peace of mind and helps maintain consistent quality across batches.
Technical support from the supplier can smooth out the learning curve for new users. Some companies, especially those with in-house R&D teams, work closely with clients to match the right product grade and even tweak synthesis protocols to maximize output. I’ve seen beginners miss tricky storage or handling steps, only to lose precious intermediate or produce batches that fail QA. Building relationships with reliable suppliers usually pays back many times over in avoided trouble and improved outcomes.
Aliphatic Chloride enters a period of change, with global supply chains pinched by rising raw material costs and new regulatory hurdles. Chinese and Southeast Asian producers dominate the high-purity market, but periodic shutdowns – whether environmental audits or energy shortages – send ripples through downstream industries. Price spikes come fast, and buyers who hedge with large contracts or diversified suppliers fare better during disruptions. Local production facilities in the EU and North America gain appeal, not only for risk mitigation but also for tighter quality guarantees and easier regulatory compliance. These shifts mirror broader trends in specialty chemical procurement.
On the R&D front, novel uses continue to emerge. Teams working on new drug discovery platforms or leading-edge polymer science test different aliphatic backbones, seeking ways to boost performance and cut costs for final customers. Frequent collaboration between industry and academic groups keeps the conversation focused not just on what’s possible but what works at scale. I’ve seen partnerships shave years off time-to-market for specialty chemicals, using smarter analytical tools and machine learning-driven quality control to eliminate batch variability.
Interest in renewable and bio-based chemicals also filters into the Aliphatic Chloride market. Greener synthesis and sourcing options — along with improved waste minimization – show up as priorities for buyers who need to report sustainability data. These changes haven’t reshaped the field yet, but early adopters win points with regulators and B2B partners. Over the next decade, observers expect these “green” grades to become the new standard for high-purity applications.
For everyone struggling to keep costs down without sacrificing quality – start with aligning procurement and technical teams more closely. Decision-making in isolation leads to costly patchwork solutions and expensive mistakes. Bring QA, R&D, and supply chain staff to the table early. Shared goals and open communication make it easier to spot potential problems and correct course before full-scale production begins.
To tackle environmental and safety risks, invest in modern process controls and continuous monitoring. Automated systems that flag off-spec batches save money and build trust with regulators. Keep waste management at the forefront, not only meeting current requirements but preparing for tightening standards. Developing partnerships with certified recyclers or hazardous waste handlers ensures disposal matches evolving norms. Even small companies benefit from adopting big-company practices here.
Companies seeking to push into reputation-sensitive industries—like pharma or electronics—should prioritize third-party certification for their products. Compliance programs and transparency set leaders apart, especially as supply chains grow more global and tightly connected. Documentation, regular audits, and real-time product tracking reduce the risk of recall, legal challenges, or broken contracts with major buyers.
Aliphatic Chloride bridges the gap between exotic specialty chemicals and the dependable mainstays needed for day-to-day industrial progress. Its presence reaches across new drug development, plastics design, agrochemical innovation, and advanced materials engineering. In a world that values reliability, traceability, and continuous improvement, this molecule remains a quiet but crucial player. Experienced hands know the value in stable, predictable performance, and new generations of chemists continue to trust these compounds as launch pads for creativity and problem-solving. As the industry landscape keeps moving, the utility and foundational importance of Aliphatic Chloride endures — pushed by demands for higher quality, less waste, and smarter sourcing decisions.
