|
HS Code |
459647 |
| Product Name | 2-(1H-1,2,4-triazol-3-yl)pyridine |
| Salt Data | FREE |
| Molecular Formula | C7H6N4 |
| Molecular Weight | 146.15 |
| Appearance | Solid |
| Solubility | Soluble in DMSO and methanol |
| Smiles | c1ccncc1c2ncn[nH]2 |
| Inchi | InChI=1S/C7H6N4/c1-2-4-10(7-8-3-1)6-9-5-11-12-6/h1-5H,(H,11,12) |
| Purity | Typically >98% |
| Storage Conditions | Store at room temperature, protected from light and moisture |
| Synonyms | 2-(1,2,4-Triazol-3-yl)pyridine |
As an accredited 2-(1H-1,2,4-triazol-3-yl)pyridine(SALTDATA: FREE) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The chemical is packaged in a 25g amber glass bottle with a tamper-evident cap, clearly labeled with chemical name and hazard codes. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 2-(1H-1,2,4-triazol-3-yl)pyridine: Standard 20-foot container, securely packaged, suitable for bulk export shipments. |
| Shipping | Shipping of 2-(1H-1,2,4-triazol-3-yl)pyridine (salts: free base) is conducted in compliance with chemical safety regulations. The compound is securely packed in sealed containers, labeled appropriately, and transported using certified carriers. Special care is taken to prevent moisture, contamination, and exposure during transit. Delivery includes safety and handling documentation. |
| Storage | 2-(1H-1,2,4-triazol-3-yl)pyridine (SALTDATA: FREE) should be stored in a tightly closed container, in a cool, dry, and well-ventilated area, away from sources of ignition and incompatible materials such as strong oxidizers. Protect from moisture and direct sunlight. Ensure proper labeling and segregation from acids and bases. Store at recommended room temperature or as specified by the manufacturer. |
| Shelf Life | Shelf life: Stable for at least 2 years when stored in a tightly sealed container, protected from light, moisture, and heat. |
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Purity 98%: 2-(1H-1,2,4-triazol-3-yl)pyridine(SALTDATA: FREE) with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield and process consistency. Molecular weight 146.15 g/mol: 2-(1H-1,2,4-triazol-3-yl)pyridine(SALTDATA: FREE) at molecular weight 146.15 g/mol is used in heterocyclic compound development, where it enables precise stoichiometric reactions. Melting point 117-121°C: 2-(1H-1,2,4-triazol-3-yl)pyridine(SALTDATA: FREE) with melting point 117-121°C is used in organic synthesis workflows, where it provides reliable thermal processing. Particle size <50 μm: 2-(1H-1,2,4-triazol-3-yl)pyridine(SALTDATA: FREE) at particle size below 50 μm is used in catalysis research, where it maximizes reaction surface area and efficiency. Stability temperature up to 150°C: 2-(1H-1,2,4-triazol-3-yl)pyridine(SALTDATA: FREE) with stability up to 150°C is used in high-temperature reaction environments, where it maintains compound integrity. Moisture content ≤0.5%: 2-(1H-1,2,4-triazol-3-yl)pyridine(SALTDATA: FREE) with moisture content ≤0.5% is used in fine chemical manufacturing, where it prevents unwanted side reactions. UV absorbance (λmax 297 nm): 2-(1H-1,2,4-triazol-3-yl)pyridine(SALTDATA: FREE) exhibiting UV absorbance at λmax 297 nm is used in analytical reference standards, where it ensures accurate spectroscopic quantification. |
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At our production site, 2-(1H-1,2,4-triazol-3-yl)pyridine is more than an item on a catalog. It is the product of careful choice of raw materials, constant monitoring, and the lessons of years at the bench and in the plant. We focus on this reagent for its reliable structure and the practical range it gives synthetic chemists, both in lab settings and at scale. Our quality control starts at the door: unrefrigerated stock oxidizes, so we keep our storage at a steady, monitored temperature, protected from light and moisture every hour of every day.
This compound’s popularity among research and industrial partners lies in its blend of pyridine and triazole structures. For us, the challenge always centers on producing a solid, free-flowing, salt-free powder that moves swiftly off the line and into dried, airtight drums. Contaminants and byproducts like triazole sulfoxides or incomplete pyridine ring closures expose themselves quickly during analytical checks. Each batch runs through high-performance liquid chromatography and NMR before ever reaching the packing area. We set the benchmark at >99% purity for our standard model, which appears as a pale, almost white solid. If the sample collects static or clumps, we chalk up the process error and start over; no batch containing irregular crystals leaves our facility.
Customers return to this compound because it does what others in the triazole-pyridine family do not. In our own scale-ups for contract partners, we repeat coupling reactions, metal coordination trials, and heterocycle-fusion sequences using this base ingredient. Medicinal chemists ask us not just for purity, but for specific lot properties—crystal habit, residual moisture levels, trace metals. It turns out that small shifts in synthetic procedures show up in downstream pharmaceutical reactions. Through repeated runs, we have learned that reactors with precise airflow and humidity control yield a batch that performs predictably for ligand design, agrochemical intermediates, and small-molecule catalyst development. We avoid using ambiguous terms like “versatile” and speak instead about where this structure proves itself. For Suzuki couplings or as a scaffold for fine-tuning hydrogen bond donors, 2-(1H-1,2,4-triazol-3-yl)pyridine delivers more reproducible results than triazole-free aromatic substrates or substituted pyridines.
Many buyers ask why our trays look so uniform and why powder flow remains easy, even after transit. This comes down to the way we quench reactions and dry the product. Slow, temperature-controlled cooling, monitored by experienced technicians, locks in the correct particle size. Blending and sieving take hours, not minutes. Some manufacturers undercut drying time, but that shortens shelf life and leads to buyer complaints that surface after shipment. We monitor water content and routinely check stability across six months. Experience has taught us that neglected batches with higher-than-standard residual solvent fail to meet even the basic standards of pharmaceutical applications. This difference matters when a developer is staking an entire project timeline on the next compound in their medicinal chemistry campaign.
Most triazole-pyridine compounds on the market come as a salt. This helps with handling but alters reactivity. Our salt-free, “free” version means customers start with the parent compound, not a protonated, counterion-bound form. In many syntheses, this cuts out extra neutralization steps, avoids side reactions, and saves time—valuable for R&D and large-scale production alike. We have fielded questions about why not simply use a methylated version, or a halogenated analog; in countless direct applications, those variants add steric hindrance or fight for coordination with metals, affecting yields just enough to annoy plant chemists under pressure. Our batch history includes more than a hundred iterative process improvements. From in-line monitoring, we know that even a 0.2% impurity level throws sensitive ligand formation off and can spoil an entire kilogram-scale step for specialty chemicals or crop protection agents.
The world of chemical supply is turbulent: interruptions in feedstock shipments, regulatory changes, freight slowdowns. During the pandemic, most disruptions hit base chemicals; we kept running by having backup suppliers for our key starting pyridine. Documentation is kept up to date for every consignment, and we maintain several weeks’ buffer stock. We don’t cut corners by mixing batches—each run is traceable, which appeals to customers carrying out method validation or scale-up for compliance work.
Over the years, our conversations with buyers echo similar frustrations: inconsistent quality from one lot to the next, vague specifications, slow communications with resellers or traders unable to answer technical questions about batch history. As the actual producer, we walk buyers through process changes and provide spectral data, water content, and heavy metals contamination reports for each batch. No need to chase up details through layers of middlemen. Reliable feedback loops help us improve; if one customer finds an unexpected byproduct after a scale-up, we review and replicate their reaction in-house to track sources of the impurity. The process never stops with just shipping out containers. We actively solve issues as they appear in our customers’ labs or pilot plants.
Each handling instruction provided to clients springs from the reality on our line. Dry powder can produce fine dust—operators wear respirators and work behind shields. Our plant team limits exposure and contains fugitive material by investing in modern extraction and filtration. This attention to real-world safety pays returns in feedback: customers report fewer issues with skin and airway irritation. We test environmental impact by reviewing all effluents. Water used in purification is treated and regularly checked to stay below discharge thresholds for triazole derivatives. This routine shapes a culture of accountability, as safety mistakes in production show up quickly in both product quality and the well-being of those who make it.
There are easy ways to meet minimum purity claims, but those shortcuts rarely survive the demands of advanced fine chemical work. We set aside a portion of each lot for long-term stability checks; retention samples are stored for several years. Potassium, sodium, iron, and chromium levels stay under tight controls, a lesson learned after one partner saw a whole series of failed catalyst formations traced back to 20 ppm iron contamination. Spectroscopies—FTIR, NMR, LC-MS—record the actual peaks; we share raw data on request. We have found that making raw data readily available helps scientists in both industry and academic labs build trust and avoid duplication of costly confirmatory analyses. Our investment in state-of-the-art analytical equipment grew out of repeated requests from buyers who simply needed to “see the peaks” for themselves before committing to bulk quantities.
We cannot escape growing pressure from green chemistry initiatives. Our engineering staff work with chemists to replace hazardous solvents and minimize process waste. As a responsible manufacturer, recovering and reusing solvents such as acetonitrile cuts both costs and impact. More than a slogan, this approach shows up in lower emissions and regulatory compliance that, frankly, makes it easier for buyers operating under strict regional restrictions. Our compound never contains phthalates, alkyl or aryl halide byproducts, or non-disclosed carriers—each of these has triggered recalls by others in the supply chain. We log every raw material’s origin and make documentation available for buyers undergoing regulatory audits or GMP investigations.
Many synthetic processes function well in small glassware but stumble at 50-liter reactors. As a plant-based team, we keep detailed records on scaling, noting heating rates, mixing speeds, and pressure drops. For this compound, uniform heat transfer and agitation make a tangible difference, directly affecting crystallization and product dryness. We have learned that long reaction times or insufficient mixing lead to colored, oily residues, which give headaches to downstream chemists seeking a clean, odor-free free base. Not every batch comes out right on the first try; our focus turns to adjustments, and we invite customers to try sample lots before full-scale ordering. The trust earned from reliable trials often leads to ongoing business relationships, with partners comfortable enough to share their full process goals and constraints. This openness helps us spot and eliminate production bottlenecks—sometimes before they even reach the customer.
Shipping regulations for this compound do not change much between markets, yet border inspections and storage in hot or humid climates can introduce problems. Our approach involves sealed, moisture-proof drums, clear labeling, and temperature loggers inside major shipments. We’ve replaced cardboard cartons with steel drums for international freight, after a single incident of moisture incursion caused borderline impurity rises. Feedback from ports in Southeast Asia and Latin America helped us design crates and inner liners that survive weeks at sea. By keeping real-time connections with our logistics partners, we track shipments, solve issues before they escalate, and help buyers keep their project timelines on track. Missed deadlines from a customs delay or weather-induced storage problems can wipe out a research budget in a hurry; we treat every drum as critical cargo, not just a statistic.
Manufacturing transparency means more than ticking boxes. Buyers have grown rightfully cautious of vague certificates or missing lot numbers. We supply direct spectra, batch history summaries, proof of storage conditions, and, when necessary, impurity breakdowns. Storage advice, handling instructions, and worker protection measures stem from what works day-in and day-out in the same facility making the product. Many academic partners return with requests for process outlines or minor changes in drying or dispersion, based on their own research needs—and working directly with the plant allows for a nimble response, never bogged down by distant headquarters or non-technical sales staff.
The distinction between a salt and a free base has consequences in how researchers and engineers design their synthetic routes. In our own experience working with pharmaceutical and agricultural innovation teams, a free base opens the door to more selective modifications and removes the work of deprotonating a salt form. Beyond that, solubility differences and the avoidance of ion-exchange residues give the free base a real advantage in sensitive or demanding syntheses. We back every lot with real-world feedback: if a batch performs differently in solution, we welcome the opportunity to trace the cause, adjust protocols, or reformulate as necessary. Our commitment to delivering the genuine article wins repeat business in sectors where reliability counts for more than marketing promises.
Repeat customers often come to us with new project requirements, sometimes seeking tighter particle size distributions, sometimes purer crystals, sometimes lower metal content. By delivering batches that meet these changing requests, we build working relationships, not just transactions. With direct feedback loops, real-time sample testing, and transparency through every stage of production—these are values learned over decades in chemical manufacturing, not written in marketing playbooks. Supporting innovators means standing behind our production runs, learning from mistakes, and making sure the next lot always performs a notch better than the last.
Even with years of continuous improvement, every synthesis run brings a new takeaway. Moisture ingress through a hairline drum flaw, unanticipated color change from a shift in catalyst source, subtle shifts in yield from a hot summer season—every one of these incidents leads to process adjustments, operation bulletins, and, if necessary, updated specifications. Instead of hiding process surprises, we use each event as a chance to level up controls and inform our customers honestly of what to expect. Building a reputation on results, not just words, requires this kind of openness at every step.
From our vantage point, chemical manufacturing succeeds where substance, consistency, and rock-solid partnership align. 2-(1H-1,2,4-triazol-3-yl)pyridine remains a core building block for pharmaceutical, catalyst, and agrochemical chemists seeking both flexibility and rigorous quality. In the coming years, tighter environmental expectations, new synthetic methods, and even more detailed traceability will shape how this compound reaches those exploring the frontiers of molecular design. We stay committed to building this future together with our partners, every day, in the lab and on the line.
