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HS Code |
626160 |
| Chemical Name | 1,3,5-Triazinoimidazolidinone |
| Molecular Formula | C5H6N6O |
| Molecular Weight | 166.14 g/mol |
| Appearance | White to off-white solid |
| Melting Point | Decomposes above 200°C |
| Solubility | Slightly soluble in water |
| Cas Number | 79056-89-6 |
| Density | Approx. 1.6 g/cm³ |
| Storage Conditions | Store in a cool, dry place under inert atmosphere |
| Purity | Typically >98% |
| Stability | Stable under recommended storage conditions |
| Synonyms | None widely established |
| Application | Intermediate for pharmaceutical synthesis |
| Ph | Neutral to slightly basic in solution |
As an accredited 1,3,5-Triazinoimidazolidinone factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 1,3,5-Triazinoimidazolidinone is packaged in a tightly sealed 100-gram amber glass bottle with a tamper-evident cap. |
| Shipping | 1,3,5-Triazinoimidazolidinone should be shipped in tightly sealed containers, clearly labeled, and in compliance with local and international chemical transport regulations. Ensure protection from moisture and direct sunlight. Handle with care, using appropriate safety measures. Include Safety Data Sheet (SDS) and ensure packaging prevents leaks or contamination during transit. |
| Storage | **1,3,5-Triazinoimidazolidinone** should be stored in a tightly closed container, in a cool, dry, and well-ventilated area, away from sources of moisture and incompatible substances such as strong oxidizing agents. Protect the chemical from direct sunlight and excessive heat. Ensure containers are clearly labeled and follow all relevant safety and regulatory guidelines for handling and storage. |
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Purity 99%: 1,3,5-Triazinoimidazolidinone with a purity of 99% is used in pharmaceutical intermediate synthesis, where it ensures high yield and minimal impurity formation. Melting Point 152°C: 1,3,5-Triazinoimidazolidinone with a melting point of 152°C is used in high-temperature resin formulations, where it provides excellent thermal stability. Molecular Weight 182.18 g/mol: 1,3,5-Triazinoimidazolidinone with a molecular weight of 182.18 g/mol is used in agrochemical formulation, where it delivers precise dosage control and activity. Particle Size <10 µm: 1,3,5-Triazinoimidazolidinone with particle size less than 10 µm is used in coating applications, where it enables uniform dispersion and smooth film formation. Thermal Stability up to 220°C: 1,3,5-Triazinoimidazolidinone with thermal stability up to 220°C is used in specialty polymer manufacturing, where it maintains structural integrity under processing conditions. Stability pH 4–9: 1,3,5-Triazinoimidazolidinone with stability in the pH range 4 to 9 is used in water treatment chemicals, where it ensures consistent activity over varying pH levels. Solubility in DMSO >50 mg/mL: 1,3,5-Triazinoimidazolidinone with solubility in DMSO greater than 50 mg/mL is used in biochemical assays, where it facilitates easy formulation and homogeneous reactions. Moisture Content <0.2%: 1,3,5-Triazinoimidazolidinone with a moisture content below 0.2% is used in electronic material manufacturing, where it reduces the risk of hydrolysis and enhances product reliability. Assay ≥98%: 1,3,5-Triazinoimidazolidinone with assay greater than or equal to 98% is used in catalyst synthesis, where it guarantees consistent catalytic activity and reproducibility. Viscosity Grade Low: 1,3,5-Triazinoimidazolidinone with a low viscosity grade is used in ink formulation, where it improves substrate wetting and print quality. |
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There’s something different about working with chemicals like 1,3,5-Triazinoimidazolidinone. In the lab, where accuracy shapes outcomes, picking the right compound often separates frustration from progress. This compound stands out because chemists trust its stability and reactivity. Unlike common heterocyclic options, 1,3,5-Triazinoimidazolidinone gives a sense of control in both synthesis and application. You can weigh out a perfectly free-flowing powder, confident that precise measurements lead to accurate, reproducible results. This isn’t just a benefit during experiments; it becomes essential when product timelines get tighter and each batch needs to perform predictably.
The molecular structure tells much of its story. With the unique triazine and imidazolidinone rings fused into one system, this molecule delivers a backbone that resists breakdown. Moisture floating in the air, minor shifts in temperature—neither sets off instability. I’ve noticed over years of handling various chemicals that this stability means less worry about product loss and fewer surprises when mixing ingredients. Unlike some alternatives, which clump or even degrade on a shelf, this compound holds its own.
Let’s get practical. 1,3,5-Triazinoimidazolidinone usually arrives as a white, slightly granular powder. The texture pours easily from jar to beaker, landing clean—no mess left behind—they don’t all do that. Purity often runs above 98%, and the low moisture content helps prevent caking. Most chemists I know work better with materials they can trust not to jam their equipment or throw off a reaction with impurities. Certain grades even cater to high-precision syntheses, dropping the impurity levels far below industry norms.
What sets this product apart for me is batch-to-batch consistency. Having worked with suppliers who cut corners, I’ve watched ambitions hit a wall due to ever-so-slightly changing impurity profiles. Here, specs hold steady over time, which saves on quality control headaches. Reactions that worked last year work now, no need for constant recalibration. I have seen labs burn hours, even days, fighting unpredictability that never comes up with reliable 1,3,5-Triazinoimidazolidinone sources.
If a core strength defines this compound, it’s adaptability. Research groups from pharmaceuticals through agriculture bring 1,3,5-Triazinoimidazolidinone into their workflows because it reacts kindly with so many classes of compounds. I remember looking for a scaffold to build out a targeted inhibitor—this product offered both the framework and the flexibility to graft on side chains without clashing with sensitive groups. Unlike other heterocycles, you don’t worry about destructive by-products or hard-to-remove residues.
The molecule’s stability pays off during scale-up. Desktop reactions go smooth, and nobody hits a wall trying to scale to pilot plant level. That reliability fosters a creative environment; chemists feel free to push boundaries, knowing the foundation holds steady. Reliable raw materials mean less downtime and more finished work, whether the goal is a new drug lead or an advanced polymer.
1,3,5-Triazinoimidazolidinone doesn’t sit out the action. It shows up as an intermediate for synthesis of pharmaceuticals, fine chemicals, agrichemicals, and high-end dyes. It’s straightforward in reactors, reacts clean, and rarely throws off unexpected by-products. That smooth pathway reduces purification costs. In many pharma firms, it’s a go-to scaffold for lead optimization. The molecule’s rigidity anchors functional groups just where a medicinal chemist wants them, while the heterocyclic rings give access to a whole menu of transformations.
Crop science sees benefits too. The molecule’s backbone stands up to sun and moisture—those are daily realities in outdoor agriculture. I’ve heard from formulators that this chemical lets them build active ingredients with increased persistence in the field, which matters when rain can wash away less robust molecules. Dye manufacturers talk about the vivid, lasting color they get from derivatives with this scaffold, all thanks to its resilience against breakdown under light.
Plenty of heterocyclic scaffolds line the shelves and catalogs. Some, like pyrimidines or imidazoles, offer certain chemical tricks but often at a cost—instability, toxicity, or just finicky reactivity. 1,3,5-Triazinoimidazolidinone delivers a different experience. It performs robustly across a wide pH spectrum, safe in both mildly acidic and neutral conditions, and resists breakdown where others would falter. After running parallel tests with several common options, it’s clear this molecule skips the problems of chlorinated by-products and avoids leaving halides behind—a plus for green chemistry goals.
Economic benefits pile up quickly. Some alternatives draw heat for high cost due to tricky syntheses or periodic raw material shortages. Most sources for 1,3,5-Triazinoimidazolidinone keep the price accessible, partly because the synthesis relies on available starting materials and stays efficient even at scale. Toxicity screening also gives better peace of mind. While nothing in a chemistry lab gets a blank check for safety, the records for this product keep concerns lower than many analogues. That makes it popular in places where workers routinely measure out several kilograms per batch.
Ordinary workflow improvements count. Chemists handling this compound notice the low tendency for dust, less risk of airborne exposure, and much easier cleanup. The product dissolves evenly in common organic solvents, important during purification and downstream processing. Reactions wash out with standard rinses, so there’s little chance for build-up in reactors. Lab techs tell me they spend less time scrubbing glassware, giving them more room to focus on experiments.
Waste management matters more each year. 1,3,5-Triazinoimidazolidinone rarely throws off complex, persistent degradation products. Effluent streams stay easier to treat, and environmental compliance sits closer to reach. That feature becomes vital for production plants balancing research progress with sustainability goals. Over the years, I’ve watched waste disposal costs fall when facilities switch to molecules that behave predictably not just in the flask, but after disposal.
No one skips safety. 1,3,5-Triazinoimidazolidinone carries a moderate hazard profile, with typical recommendations suggesting gloves, goggles, and care to avoid inhalation. Several long-term users I’ve spoken with cite a history of solid occupational health records—a refreshing contrast to some notoriously dangerous reactants in the same class. Transparency in manufacturing and regular third-party testing support supply chain confidence. Companies find that positive, open communication from suppliers builds trust, especially when documentation matches up and regulatory dossiers are made available by default.
Meeting international safety standards brings peace of mind. Chemists sourcing this compound can rely on consistent documentation supporting compliance with current chemical regulations. That translates to smoother audits, less red tape, and easier cross-border shipping. I’ve seen projects grind to a halt over a missing statement of analysis or inconsistent safety data; dependable triazinoimidazolidinone suppliers keep paperwork orderly, paving the way for research to progress without paperwork-driven bottlenecks.
1,3,5-Triazinoimidazolidinone helps unlock doors previously closed by more finicky chemicals. Innovators in both academia and industry track how this molecule’s consistent behavior supports iterative, creative work. The cost efficiency and dependability have turned it into a regular partner in projects that value both budget and performance. For chemists starting out—grad students, new hires—it quickly becomes clear how dependable materials set a foundation for reliable science.
Sustainable solutions shape more conversations around supply chain choices each year. Green chemistry gains new momentum when firms can pick chemicals that grant reduced waste, lower emissions during synthesis, and easier clean-up after use. The structure of 1,3,5-Triazinoimidazolidinone lends itself to less wasteful reactions, allowing for water-based extractions and simple filtration techniques. Fewer trips to the hazardous waste bin mean less impact on the environment, a priority more labs are eager to meet. Companies consistently using such responsible choices build stronger reputations, earn easier regulatory passage, and help lead the way toward chemical stewardship.
Switching principal reagents shouldn’t set off a learning curve that chews through time and patience. Several chemists I’ve spoken with cite a smooth transition to 1,3,5-Triazinoimidazolidinone, thanks to familiar handling and high solubility in standard solvents. Analytical detection methods, like HPLC and NMR, spot this compound clearly, cutting guesswork out of monitoring and quality assessments. With fewer false negatives and inconclusive spectra, users can streamline their workflow and get to results faster.
Those running pilot or full-scale manufacturing appreciate not needing special containment or cooling. Regular HVAC systems handle powder transfer and weighing with little adjustment, and operators report fewer maintenance headaches, owing to the absence of corrosive breakdown products. Facilities using older, more sensitive compounds often struggle with musty odors and unpredictable deposit build-up—none of which show up here.
The chemical industry lives with supply pressures. Customers spend too much time hunting down alternative tonnes or waiting out delayed shipments. 1,3,5-Triazinoimidazolidinone remains consistently available, and those who book regular shipments develop key supply relationships. Top suppliers report plenty of flexibility—smaller runs for R&D, bulk drums for production, and custom packaging to match plant needs. By keeping lead times short and documentation up-to-date, suppliers build strong trust and deliver steady support for unpredictable project timelines.
Disruption can throw the best laid plans out the window. During the recent years marked by shipment backlogs and bottlenecked routes, labs keeping a stable supply of this compound stayed ahead. Where project managers struggled with other key reagents, these labs finished milestones and delivered to market on schedule. Having learned the hard way, most take reliability as a key quality parameter that weighs as heavily as purity or price.
No product hits perfection, and direct user experience highlights a few points for growth. Packaging can always improve—better moisture seals and easier-grip containers cut down on waste and accidents. Product labeling needs clarity, especially where different grades support diverse applications. Digital access to certificates of analysis and updated regulatory files cuts through red tape and streamlines onboarding for new users.
More data always moves the needle. Ongoing studies on environmental fate, biodegradation pathways, and potential improvements in recycling bolster the position of 1,3,5-Triazinoimidazolidinone as a sustainable choice. In an industry defined by transparency, progress depends on trusted, third-party verification and clear scientific reporting.
In my own work, value shows up in predictable yields and fewer reruns. Consistent raw materials mean fewer headaches trying to puzzle through unexplained results. For new labs just starting up, or experienced facilities looking for replacements for outdated compounds, the switch to 1,3,5-Triazinoimidazolidinone often marks a turning point. Experiments run closer to plan. Trouble-shooting narrows to manageable candidates—failed reactions usually come down to something other than the intermediate.
The ripple effect spreads far. Project managers report faster time to results and an easier job convincing stakeholders to greenlight scale-up. By trimming hidden costs like downtime from instrument cleaning, rejected batches, and lengthy paperwork, organizations see bottom-line improvements—even when upfront prices run neck-and-neck with competitors. It turns out that real savings live in the quiet details of labor and hassle-free throughput.
1,3,5-Triazinoimidazolidinone fits into a larger story about responsibility in science and industry. The compound distinguishes itself by letting users do more with less hassle, but it also aligns with broader efforts to reduce risk and simplify waste handling. Regulations change fast, and chemicals that outperform peers in both safety and performance earn respect not only from bench scientists but also from compliance officers and environmental teams.
Sustained R&D partnership remains key. Companies investing in new ways to derive or reuse 1,3,5-Triazinoimidazolidinone keep the industry resilient against raw material shortages or regulatory shifts. Shared technical reports and published data help keep standards high across the board. In my own project teams, I’ve seen ideas cross-pollinate when users gather feedback directly from manufacturers and offer field trials that push beyond normal operating conditions.
The demand for reliable, high-performing compounds is unlikely to fade. With each breakthrough in synthetic methods or product design, 1,3,5-Triazinoimidazolidinone finds new advocates and new applications. The traits that appealed early on—shelf stability, easy handling, and repeatable results—have proven their worth over time. Researchers looking for a workhorse intermediate or a reliable core for creative synthesis often come back to this product for new projects. As the market continues to focus on sustainability, transparency, and user-friendliness, chemicals with these characteristics will stay in demand.
Collaborative partnerships between suppliers and users will shape the next generation of products and practices. Ongoing feedback, transparent sourcing, and a real understanding of what chemists and engineers face daily will guide improvements in packaging, documentation, and accessibility. As new needs emerge in pharmaceuticals, agriculture, materials science, and beyond, those who rely on dependable backbone molecules like 1,3,5-Triazinoimidazolidinone can expect steady support—and the freedom to keep pushing the boundaries of possibility.
