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HS Code |
820596 |
| Iupac Name | 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine |
| Molecular Formula | C4Br2N3S |
| Molecular Weight | 291.94 g/mol |
| Cas Number | 850568-86-6 |
| Appearance | Off-white to pale yellow solid |
| Boiling Point | Decomposes before boiling |
| Solubility | Slightly soluble in organic solvents such as DMSO, DMF, and chloroform |
| Smiles | C1=CN2C(=NN=C2S1)Br |
| Inchi | InChI=1S/C4Br2N3S/c5-2-1-7-4-8-9-3(6)10-4 |
| Purity | Typically >97% (commercial samples) |
| Storage Conditions | Store in a cool, dry place, away from light and moisture |
| Hazard Classification | May cause skin and eye irritation; handle with care |
| Uses | Intermediate in synthesis of organic electronic materials |
As an accredited 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | A 1-gram sample of 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine is packaged in a tightly sealed amber glass vial. |
| Container Loading (20′ FCL) | 20′ FCL is loaded with securely packed 25 kg fiber drums of 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine, ensuring safe transport. |
| Shipping | **Shipping Description:** 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine is shipped in tightly sealed containers, protected against moisture and light. It is classified as a research chemical, not listed as hazardous for transport. All shipments comply with relevant local and international regulations, including safety labeling and documentation. Store at room temperature upon arrival. |
| Storage | 4,7-Dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine should be stored in a tightly sealed container, away from moisture, light, and incompatible substances such as strong oxidizers. Store at a cool, dry, and well-ventilated location. Avoid heat sources and direct sunlight. For added safety, keep in a designated chemical storage cabinet, following institutional and regulatory guidelines for hazardous materials. |
| Shelf Life | Shelf life: 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine remains stable for at least two years when stored dry, cool, and protected from light. |
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Purity 98%: 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine with a purity of 98% is used in organic electronics synthesis, where it ensures high charge carrier mobility in semiconducting devices. Melting Point 250°C: 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine with a melting point of 250°C is utilized in OLED material development, where it provides thermal stability during device fabrication. Molecular Weight 278.94 g/mol: 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine with a molecular weight of 278.94 g/mol is used in high-performance polymer synthesis, where it allows precise monomer ratio control for targeted polymer structures. Particle Size <10 µm: 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine with a particle size below 10 µm is applied in thin-film deposition processes, where it promotes uniform layer formation for electronic devices. Stability Temperature 180°C: 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine with stability up to 180°C is employed in photovoltaic material research, where it maintains molecular integrity during solar cell processing. Solubility in DMSO 15 mg/mL: 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine with solubility in DMSO at 15 mg/mL is used in solution-based nanomaterial fabrication, where it enables high-concentration ink formulations for printing electronics. Moisture Content <0.5%: 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine with moisture content less than 0.5% is utilized in pharmaceutical intermediate synthesis, where it reduces the risk of hydrolytic degradation during reaction stages. |
Competitive 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine prices that fit your budget—flexible terms and customized quotes for every order.
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Email: sales7@boxa-chem.com
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As a company that puts daily effort into shaping complex molecular structures, we know every batch and every detail in our line of specialty organics means everything to chemists and project managers counting on consistent results. Among our range, 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine stands out for those pushing boundaries in organic electronics, specialty polymers, and advanced material R&D.
Producing 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine demands careful handling and deep process understanding. Our line operators and process chemists have spent years refining conditions, paying close attention to issues like solubility drift, bromination side reactions, and precise crystallization to avoid inclusion defects. We never cut corners by batch blending or hasty purification, and every kilogram comes with a track record through our QC logs.
No two synthesis runs are identical, though many in the market make it sound simple. Temperature profile fluctuations and uncontrolled humidity can swing impurities by orders of magnitude, so we deliberately lock down these variables. Inline monitoring and frequent human checks—using equipment calibrated daily—keep results true. If a run doesn't meet the right standards, we don't ship it. In high-stake electronics and advanced polymer applications, downstream reproducibility hinges on this kind of integrity.
Most of our 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine buyers already know their targets: cutting-edge molecule libraries, heterocyclic motif exploitation, or semiconducting material synthesis. In these settings, there’s rarely time or budget to troubleshoot batch variability. We supply this compound to several labs and companies working on organic field-effect transistors, photoactive layers, and intricate donor-acceptor conjugated systems.
We have seen significant growth in requests for higher-purity, bromine-enriched building blocks. Quite a few new projects rely on this exact scaffold to access innovative functionalized pyridines or for late-stage diversification via palladium-catalyzed cross-coupling. Our production lines must meet those standards or risk becoming a source of delay and extra cost in larger value chains. Projects depending on high charge mobility, stability under light or heat stress, and batch-to-batch uniformity often point to trace byproducts or sub-ppm halide contamination as culprits in performance drift. That’s where our process control really pays off for users.
Most users expect high chemical purity—98-plus percent, with low residual bromide and minimal solvent inclusion—but what’s less frequently discussed is the need for a consistent particle profile and moisture control. Through multiple customer feedback cycles, we realized even minor variations in moisture trapped in the lattice affect solubility in scale-up Suzuki or Stille reactions. Frequent and repeated Karl Fischer titrations ensure we keep water below the levels problematic to catalyst systems. Changes to particle size from variations in crystallization speed or drying conditions can slow or accelerate reaction rates in downstream chemistry, which complicates process uptake. We must keep morphology consistent to avoid batch-to-batch headaches for users scaling from grams to kilograms.
We also keep an eye on color, flow, and static buildup—subtle but practical details that can disrupt automated dispensing or complicate glovebox handling. Internally, we run both HPLC and NMR on fresh batches and do spot checks from storage to monitor for any slow degradation or spontaneous hydrolysis, especially during humid months.
Having produced many halogenated heterocycles and thiazole derivatives in the same facility, we can say that 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine ranks among the more temperamental. Cheaper versions flooding some markets often show evidence of shortcut syntheses: unclarified mother liquors, color smears indicating mixed halos, or incomplete purification with persistent aromatic impurities. Many of these batches work for initial screening but fail in scale-up or under stringent end-use QC. We see it all the time when customers come to us after wasted effort with lower-cost imports. Our solution lies not just in raw purity, but in meticulously aligned analytical data and shipment samples retained for long-term reference in our own archives.
We don’t rely solely on certificates on paper. In our labs, we test across various common reaction setups with our own inventory, screening integrations into typical Buchwald–Hartwig or Suzuki couplings, and carrying through to actual device performance on test substrates. If problems arise, we can pinpoint them, since we keep real samples of previous runs. We welcome feedback and have steadily updated protocols based on direct troubleshooting with some of the most demanding customers in research and industrial innovation.
One of our large-volume clients in optoelectronics repeatedly cited instability issues using alternative sources. Their concern wasn’t only visible purity, but hidden batch contaminants revealed during high-sensitivity MOSFET device tests. After sample swaps and several months of comparative side-by-side device tracking, their technical teams found our batches cut device failure by nearly two-thirds. Those kinds of results come from the work behind the scenes: continuous feedback loops, staff training, and refusal to release inconsistent lots. We build more than molecules—we support the progress of entire platforms in advanced materials science.
For academic users, who often have inconsistent grant cycles or variable funding, we support flexible scale delivery—from just enough for core motif screening up to drum-sized shipments for multi-stage industrial process trials. The whole cycle from customer inquiry to shipment has been shaped by our real-world bottlenecks: customs documentation, climate issues, and storage quirks. No two syntheses, and no two end-users, experience the same challenges. By sharing our insights directly, we help our clients avoid common pitfalls, whether in purification, storage, or downstream modification steps.
Some suppliers blend small-batch lots to make minimum order mass, but we insist on single-run consistency for industrial customers. Any given batch trace comes with notes on reaction temperature controls, maximum applied vacuum during drying, and any deviations. This transparency shapes not just immediate outcomes, but also downstream project reliability. When questions arise later—about a solubility problem, an unanticipated impurity in a coupled product, or a storage anomaly—having access to meticulous batch histories and collaborative ongoing customer relationships proves its worth over and over.
Polishing each production run costs more in time and attention, but pays compound dividends for customers scaling research to pilot lines or commercial-scale runs. Moving from benchtop to pilot plant often reveals issues no datasheet predicts—particle bridging in feeders, static clumping, or fine particulate settling that disrupts automated powder-to-liquid systems. We have worked alongside equipment engineers resolving such challenges and have adapted our drying and milling lines to address them without introducing extra silica or stabilizers that might cause issues in delicate downstream catalysis.
Many other products, especially those sold by generic chemical outlets, tend to sacrifice in-depth project support for raw price points. The trade-off often goes unseen until a crucial batch fails downstream QC in a manufacturing run. We avoid batch-mixing different syntheses, so customers ordering multiple kilos receive a uniform profile, not an averaged-out mishmash. Our preserved batch samples and traces offer assurance—enabling customers to backtrack issues to exact runs, rather than arguing with faceless QC admins about hypothetical batch blends.
Customers tell us direct technical support adds unforeseen value—answers from our process chemists come from recent batch records, not distant third-party databases. If a research team runs into trouble, we check retained reference samples, walk through possible pathways of change, and, if required, reproduce critical conditions in our labs to validate findings. Our analytical setup is tuned closely to this product family, so we don’t depend on generic parameters—peak integration, baseline drift, or minor byproduct signatures are tracked specifically for this therapy. This investment of care is rooted in decades of hard-won experience working with sensitive intermediates and high-purity halogenated heterocycles.
We run regular after-action reviews on batches flagged for deviation, sharing lessons internally in training to avoid repeat errors. Some lessons come the hard way—one run last year was jeopardized by an unexpected airborne contaminant traced to a neighboring process. This incident led us to isolate process loops and upgrade air filtration for all sensitive synthetic steps. Another time, minor variances in crystalline needle formation translated to slow filtration rates for one key user. As a result, we improved both our seeding procedure and final product sieving, solving persistent operational headaches for a demanding project scaling up non-linear optical material production.
Out in the real world, practical problems like static charge build-up or fine-powder caking matter as much as spectroscopic purity. Teams unable to handle or dose compound easily risk workflow breakdowns and lost days. By tracking and addressing every complaint—from magnetic stirring behavior in gloveboxes to the flow dynamics in vibratory feeders—we evolve our own operations and, in turn, make life easier for our customers. We accept that molecules don't just exist as numbers or structures on a page—they're handled, weighed, dissolved, and transformed into vital materials for displays, Organic LEDs, or future battery chemistries.
Sourcing the right raw brominating agents, ensuring their safe use, and managing effluent in line with both local and international standards are not catchphrases in our operation—they’re the daily routines that keep our facility running and local regulators satisfied. All waste streams are closely monitored for halogen content, and we actively recycle solvents with an eye to reducing overall process intensity. We have never suffered a regulatory breach on effluent or waste gas emissions, because we invest as much in safe operation and environment as in product quality. Our operators are trained not just for compliance but for vigilance—it matters when you handle sensitive halogenated compounds and care about your community.
We offer full traceability in sourcing and batch processing, because major industrial clients, and ever more often, universities, ask for clear sustainability records. Some forward-looking partnerships even require cradle-to-gate energy consumption disclosures. We do not hide behind paperwork; batch data, waste reports, and solvent recovery logs are available when justified. Project partners can sleep a little easier knowing that every drum or bottle from our plant arrives with the background to support tech transfer, logistics, and compliance far beyond what is typical in commodity-style sourcing.
After years in the chemical manufacturing business, we have come to appreciate that high-purity advanced intermediates are not simply a matter of technique, they are a matter of long-term dedication and incremental improvement. Every change in a parameter—temperature ramp, drying speed, or even the grade of glassware—finds its mark in the final analysis. Down-to-earth conversations with clients, analytic chemists, bench scientists, and purchasing managers shape how we iterate and re-examine our approaches.
4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine sits now at the crossroads of pioneering research, novel electronics, and next-generation functional materials. We listen to stories from customers who have seen projects sidetracked by invisible trace impurities, by awkward physical profiles, or by lack of process documentation. Our goal is always to remove hurdles and add value—one batch, one solution, one tech-support call at a time. The voice of experience in real manufacturing matters most, and that is what guides us every day working with the teams that depend on our products to power their innovations.
The industries we support—whether they focus on electronics, photonics, molecular devices, or tailored functional polymers—are unforgiving of error and deeply appreciative of reliability. Our reputation grows not only by the sales we make, but by the challenges we help solve. Each lot of 4,7-dibromo-[1,2,5]thiadiazolo[3,4-c]pyridine represents hundreds of decisions, tests, and quality checks that others may overlook but our customers rely on. We know this product better with each passing year, and we never stop adapting based on your feedback and real-world project needs.
Working directly with end-users, we build not just molecules, but lasting trust and a living repository of knowledge that helps you go further, faster, and with fewer obstacles. For every lab in search of a reliable synthetic partner, and every business working to scale new materials from bench to production, our doors stay open. We meet every challenge backed by the experience and care that can only come from true manufacturing expertise.
