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HS Code |
940051 |
| Chemical Name | 2-Chloro-5-(hydroxymethyl)pyridine |
| Molecular Formula | C6H6ClNO |
| Cas Number | 3430-13-5 |
| Appearance | White to off-white solid |
| Melting Point | 81-85°C |
| Solubility | Soluble in water and organic solvents |
| Purity | Typically ≥98% |
| Density | 1.31 g/cm³ (estimated) |
| Smiles | C1=CC(=NC=C1CO)Cl |
| Inchi | InChI=1S/C6H6ClNO/c7-6-2-1-5(3-9)4-8-6/h1-2,4,9H,3H2 |
| Storage Conditions | Store in a cool, dry place, protected from light |
| Hazard Statements | Irritant |
As an accredited 2-Chloro-5-(hydroxymethyl)pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The packaging consists of a 25g amber glass bottle, tightly sealed with a screw cap, and labeled with hazard and identification information. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): 2-Chloro-5-(hydroxymethyl)pyridine is packed securely in drums or bags, maximizing container space, ensuring safe transport. |
| Shipping | **2-Chloro-5-(hydroxymethyl)pyridine** is shipped in tightly sealed containers, protected from moisture and light, and handled according to chemical safety regulations. Packages are labeled with hazard information and transported under standard temperature conditions. Ensure compliance with local, national, and international shipping guidelines for chemical substances. |
| Storage | 2-Chloro-5-(hydroxymethyl)pyridine should be stored in a tightly closed container, in a cool, dry, and well-ventilated area, away from sources of ignition, oxidizing agents, and direct sunlight. The storage area should be clearly labeled and equipped with appropriate spill containment. Use only with adequate ventilation, and avoid inhalation or direct contact with skin and eyes. |
| Shelf Life | 2-Chloro-5-(hydroxymethyl)pyridine is stable for at least two years if stored in a cool, dry, tightly sealed container. |
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Purity 98%: 2-Chloro-5-(hydroxymethyl)pyridine with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield and product consistency. Melting Point 58°C: 2-Chloro-5-(hydroxymethyl)pyridine with a melting point of 58°C is used in fine chemical manufacturing, where it allows for efficient solid-phase handling and minimized thermal degradation. Molecular Weight 143.56 g/mol: 2-Chloro-5-(hydroxymethyl)pyridine at molecular weight 143.56 g/mol is used in agrochemical formulation, where it enables precise dosing and formulation accuracy. Assay ≥99%: 2-Chloro-5-(hydroxymethyl)pyridine with assay ≥99% is used in heterocyclic compound development, where it provides optimal reactivity and purity for sensitive reactions. Stability Temperature up to 140°C: 2-Chloro-5-(hydroxymethyl)pyridine with stability temperature up to 140°C is used in catalytic research, where it maintains structural integrity during extended heat exposure. Moisture Content ≤0.5%: 2-Chloro-5-(hydroxymethyl)pyridine with moisture content ≤0.5% is used in active pharmaceutical ingredient preparation, where lower moisture contributes to longer shelf life and reduced degradation. |
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Over the past decade of producing fine chemicals, we have come to respect the distinct character of each pyridine derivative. Among those, 2-Chloro-5-(hydroxymethyl)pyridine has gained a reputation for reliability and flexibility across a surprising spread of industries. Its molecular structure, C6H6ClNO, gives it a unique balance between reactivity and manageability—two traits we value in both the lab and the warehouse.
Our method begins with carefully selected raw materials that already meet the stringent thresholds our chemists demand, as the integrity of each batch depends on consistent input quality. In practice, this compound emerges as a white to off-white crystalline solid, and its reasonable solubility in a range of organic solvents broadens the options for formulation and process adaptation. By applying continuous feedback from end users, we fine-tune purity, typically exceeding 98%, with low moisture content and trace impurities well below industry thresholds. From the first kilo up to batch runs of several tons, our production system holds to these standards, making sure users receive the same dependable product with every order.
Pyridine derivatives often form the backbone of pharmaceutical intermediates and active ingredients, where trace contaminants or deviations in purity can cause failures in clinical validation or scale-up. This molecule, 2-Chloro-5-(hydroxymethyl)pyridine, features both a chloro substituent and a hydroxymethyl group in exact positions, lending it uncommon versatility in synthesis. Real-world applications include anti-infective drug synthesis, agricultural formulation, and the fine-tuning of specialty coatings and advanced materials. While the basic molecular properties might appear simple, even small differences in impurity level or moisture content have led to challenging process setbacks for clients. We have responded by expanding our analytical techniques and optimizing storage to protect stability, so what leaves our facility matches the most demanding synthetic workstreams.
The preferences of pharmaceutical clients have served as a bellwether for our production standards. Laboratories count on rapid, consistent reactivity when coupling reactions or setting up further derivatizations. If hydrogen chloride or moisture levels vary from batch to batch, yields and selectivity suffer. We have put in place continuous monitoring for these micro-impurities, and every lot must pass a comprehensive release panel before shipment. Our in-house team tracks and records critical parameters, with full traceability extending back to the day and shift of manufacture—an asset when troubleshooting syntheses or submitting documentation to regulators.
Working directly at the heart of production, we see how different approaches to synthesis and post-processing can shift the final quality of chemical products in ways that aren’t always obvious from a data sheet. For this pyridine derivative, conventional sources sometimes rely on less discriminating chlorination or hydroxyalkylation protocols, which can leave behind hard-to-remove structural isomers or process byproducts. Years spent fine-tuning our own route now give us the ability to minimize those side reactions, and regular side-by-side benchmarking against imported samples highlights a tighter impurity profile, improved flowability, and lower risk of shipment damage.
Common alternatives, such as chloromethylpyridine isomers or para-substituted analogues, often create headaches during large-scale synthesis, where minor shifts in regioselectivity or polarity throw off purification or downstream derivatization. Our experience has proven that the specific 2-chloro and 5-hydroxymethyl substitution delivers both predictable reactivity and reduced byproduct formation compared to these alternatives. End-users in pharmaceuticals, especially those working with highly potent or narrow-spectrum compounds, appreciate that reproducibility over multiple campaigns. In industrial settings, such as agrochemical synthesis, plant managers report that process interruptions dwindle from batch standardization, saving on cleanup costs and lost cycle time.
Clients tapping into our product base apply 2-Chloro-5-(hydroxymethyl)pyridine most often as a key intermediate in synthesizing substituted pyridinyl derivatives. In our conversations with research chemists and process engineers, critical feedback points include the need for precise melting behavior, sharp end-point titration, and reliable dissolution for multi-step reactions. The compound rises to the challenge, with melting points remaining within the 62–65°C range, and most lots demonstrating negligible batch-to-batch drift. The crystalline form simplifies weighing and transfer, eliminating caking or dusting that can delay process start-ups.
Bulk users often streamline multi-ton campaigns for active pharmaceutical ingredient (API) production or specialized chemical syntheses. Reports show that inconsistent quality from other suppliers can lead to several hours of lost productivity, with teams forced to run extra analyses or rework failed intermediates. In contrast, tightly controlled specs allow production teams to program their synthesis with fewer interruptions, and experienced operators mention smoother purification and less waste during work-up. The net benefit isn’t just financial; it creates better working conditions and reduces the stress that comes with potential process failures.
Our warehouse and shipping protocols reflect lessons learned from years of feedback. Exposure to airborne moisture and light can alter both the physical appearance and chemical stability of this pyridine, so packaging uses high-barrier liners and sealed drums. Temperature-controlled shipment ensures that hot summer months or unexpected delays don’t affect product reliability. These choices come straight from customer needs—real problems from the field, met with real solutions based on hands-on production.
In the competitive world of specialty chemicals, surface-level similarities often mislead buyers. As a producer, we see confusion arise when clients switch between 2-Chloro-5-(hydroxymethyl)pyridine and its structurally related counterparts, such as 2-chloromethyl-5-pyridinol or unsubstituted pyridine. Our synthesis teams run side-by-side tests in identical process conditions. The main advantage for our product comes from its precise dual substitution pattern: the combination of a chlorine atom and a hydroxymethyl group at the specific 2- and 5-positions delivers reactivity that outpaces both mono-substituted and meta-analogues, creating faster reactions with higher selectivity. Yields improve, and unknown byproducts drop away, simplifying downstream isolation.
Substitution patterns also affect hazard profiles and regulatory oversight. Through direct engagement with regulatory officers, we discovered that material traceability and disclosure requirements now demand more than a simple certificate of analysis. Our documentation draws straight from in-process controls, providing exact impurity breakdowns, batch genealogy, and air/moisture sensitivity guidance for risk management. Similar products, especially those supplied via trading channels or resellers, often gloss over these production variables. Years of quality management in-house have shown that end-users end up absorbing the costs of correcting these gaps if they surface late in development.
The difference of working directly with a manufacturer comes through in the consistency of support for scale-up and troubleshooting. Our team’s practical experience running thermal stability tests, filtration trials, and stress-corrosion checks means advice isn't theoretical—it comes from actually seeing what happens on the plant floor. For process chemists planning a new run, we can simulate conditions, anticipate risks, and fine-tune specifications—not just on paper, but in practice. Over the years, clients have avoided costly delays or process tunings by leaning on these insights before scaling.
Producing chemicals like 2-Chloro-5-(hydroxymethyl)pyridine at scale never unfolds exactly as planned. There are lessons we gather each production run—sometimes subtle, sometimes glaring. Managing exothermic reactions, for instance, can become unpredictable above certain volumes. Our engineers have worked through these limits by redesigning reactor cooling systems and using staged reactant feeds, which improved yield consistency by nearly 10% across successive campaigns. Moisture management, both in synthesis and storage, plays a pivotal role in long-term stability, so our facility imposes continuous humidity monitoring from raw material intake through final packaging. We have upgraded to low-permeability storage, even at costlier material outlays, because the product’s long-term usability depends on it in practice, not just in theory.
The drive toward sustainable manufacturing challenges us to improve both process efficiency and waste handling. Through catalyst optimization and solvent recycling, we have dropped waste output per ton by 18% year over year over the last three cycles. These reductions don’t just earn environmental certifications—they keep overhead under control and feed into lower total cost for users. Not every improvement gets a press release, but these choices accumulate into steadier quality and delivery timelines for our regular customers.
Cross-border regulations now affect not only formal registration, but also import quotas, documentation standards, and site audits. As rules have evolved, our compliance team dedicated more hours to direct engagement with regulatory bodies—often tailoring documentation formats or audit procedures to exact country protocols. Chemical manufacturers like us must build these administrative skills into daily routines, as much as they do synthesis skills. The benefit comes back when shipments clear inspection quickly and without requested remakes or hold-ups, reducing risk for clients and keeping projects moving.
The chemistry world doesn’t stand still. Customer applications shift, sometimes in small increments that add up to new production requirements or regulatory restrictions. We have watched as certain uses for 2-Chloro-5-(hydroxymethyl)pyridine, especially in pharma innovation, have led to tighter controls on residual solvents and unreacted starting material. Our lab responds by extending analytical validation with new chromatography methods that can separate close-eluting impurity signals—details that buyers often overlook until a problem arises. Such improvements fed back into process batch templates, reducing investigation time during subsequent scale-ups.
The last few years brought a surge in demand for hybrid applications, where researchers use 2-Chloro-5-(hydroxymethyl)pyridine as both an intermediate and as a tool for structure-activity probe development. Those researchers depend on a product that doesn’t just perform in one batch but stays reliable from kilogram scale through to late-stage pilot plant production. Feedback from partners flagged a risk of variable batch brightness and minor caking in some lots. Investigation traced this back to humidity pickup during secondary packaging. By updating handling protocols and investing in a higher throughput desiccation line, we delivered tangible improvement, mirrored by a drop-off in related complaints.
Some research groups seek customization—modified particle size, customized documentation, even alternate packaging for unique handling systems. The benefit of in-house manufacturing lies in our ability to respond without needing layers of approval or inter-company coordination. Decades of plant experience have taught us how to read between the lines in technical requests, distinguishing between must-have items and optional extras, so clients see what’s technically feasible, not just what a sales team promises. Each change or refinement flows through a robust internal validation loop to ensure that no matter the specific request, product integrity holds for the next user.
We see the next chapter of our product development grounded in lessons from real production runs, ongoing feedback loops, and active engagement with users. Competition from commodity traders and resellers will always exist, offering lower prices but often risking consistency or traceability for short-term gains. Our approach—rooted in ongoing process improvement, full documentation, and direct engagement—won’t appeal to every buyer, but supports clients who value certainty and partnership for complex projects.
Looking ahead, digital tracking and process automation are reshaping the way we handle quality assurance and client auditing. Our investment in digital batch records and production monitoring delivers full supply chain visibility, answering not only compliance auditors but also process engineers wanting to verify every step of the timeline. As synthetic routes or applications demand fresh modifications, we retain the agility to update processes in real time, backed by the hands-on knowhow that only long-term manufacturing can cultivate.
Feedback loops running throughout the plant—from control room engineers reading real-time trends to operators monitoring product appearance—anchor our commitment to continuous learning. Each improvement represents a conversation: between researchers seeking new solutions and production teams figuring out safe, reliable methods.
Our long-standing exposure to the ins and outs of 2-Chloro-5-(hydroxymethyl)pyridine production confirms that product quality, reliability, and client confidence don’t emerge by chance. Each batch, each improvement, is a response to the everyday realities of chemical manufacturing—temperature swings, moisture ingress, regulatory shifts, and evolving client needs. For users wanting a product shaped not just by market demand but by continuous attention to process details, direct manufacturer sourcing offers real benefits. We approach production with respect for the material and responsibility for each step, ensuring long-term partnerships built on trust and mutual success.
