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HS Code |
461972 |
| Product Name | 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride |
| Cas Number | 59121-52-3 |
| Molecular Formula | C11H12ClN5 |
| Molecular Weight | 249.70 g/mol |
| Appearance | Red to orange solid |
| Solubility | Soluble in water |
| Melting Point | Decomposes before melting |
| Purity | Typically ≥98% |
| Storage Conditions | Store at 2-8°C, protected from light |
| Synonyms | Fast Orange G Monohydrochloride |
| Hazard Classification | Irritant |
| Inchi Key | QAQCBXKJZFUAVG-UHFFFAOYSA-N |
As an accredited 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle with a secure screw cap, clear hazard labels, containing 10 grams of 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride. |
| Container Loading (20′ FCL) | 20′ FCL container holds up to 10 MT of 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride, securely packed in fiber drums. |
| Shipping | 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride should be shipped in tightly sealed containers, protected from light and moisture. It must be labeled as a laboratory chemical, packed according to relevant hazardous material regulations, and accompanied by the appropriate safety documentation (SDS). Handle with care and avoid exposure to heat or incompatible substances. |
| Storage | Store 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride in a tightly sealed container, protected from moisture and light, at room temperature (15–25°C) in a dry, well-ventilated area. Keep away from incompatible substances such as strong oxidizers and acids. Ensure proper labeling, and avoid exposure to heat and sources of ignition. Use personal protective equipment when handling to prevent contact and inhalation. |
| Shelf Life | 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride typically has a shelf life of 2 years when stored tightly sealed, cool, and dry. |
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Purity 98%: 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride with a purity of 98% is used in precision organic synthesis reactions, where it ensures high yield and minimal impurities. Melting Point 220°C: 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride with a melting point of 220°C is used in high-temperature dye manufacturing, where it maintains molecular integrity during processing. Particle Size <10 µm: 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride with particle size less than 10 µm is used in inkjet ink formulations, where it provides superior dispersion and homogenous color distribution. Stability Temperature 100°C: 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride with stability up to 100°C is used in pigment applications, where it offers consistent color stability under elevated thermal conditions. Molecular Weight 249.70 g/mol: 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride with a molecular weight of 249.70 g/mol is used in analytical standard preparations, where it ensures accurate quantification and reproducibility in assays. Azo Content 15%: 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride with 15% azo content is used in chromogenic sensing systems, where it improves sensitivity and selectivity for target analytes. Hydration Level Monohydrate: 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride monohydrate is used in controlled-release pharmaceutical formulations, where it provides predictable solubility profiles. Solubility in Water 25 mg/mL: 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride with solubility of 25 mg/mL in water is used in aqueous dye solutions, where it permits higher concentration formulations without precipitation. |
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Years on the manufacturing floor have shown that each fine chemical has its own personality, purpose, and quirks. 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride stands out in our benchwork as a compound that has proven its value in serious research and demanding production settings. With experience spanning decades, our team sees this molecule appearing again and again in projects that demand accuracy, consistency, and solid traceability.
Researchers and development scientists often seek out 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride for its versatility as an azo coupling component, a property that lends itself well to the creation of complex dyes and pigments. Synthetic chemists have a fondness for its highly recognizable chromophore, which allows for predictable color responses in formulations. The monohydrochloride form not only enhances solubility but also supports tight control over ionic balance and purity in solution-phase reactions.
Working in chemical manufacturing means spending a good deal of time in dialogue with both bench scientists and process engineers who have real-world demands. Our in-house production model for 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride prioritizes batch-to-batch reliability, which comes from direct oversight at every purification step. Avoiding trace metallic contaminants and keeping the water content tightly within specified ranges are part of daily practice, not just marketing claims. Our production lines leverage quantitative analytical checkpoints at varied stages, favoring HPLC and UV-Vis consistent with the functional requirements of azo chemistry.
Clients sometimes ask about the practical side of scaling this compound. Our approach centers on controlling particle size distribution and minimizing dust formation—a real nuisance for operators and research assistants alike. From drum filling to final sampling for shipment, the aim is to keep product consistency high while limiting the potential for cross-contamination. Tough lessons in quality come not from reading specs but from seeing firsthand how a batch with poor filtration can set back an entire R&D program.
This compound has become a backbone in development of specialized dyes, particularly those intended for textile and plastics coloration under demanding fastness conditions. Industrial clients often rely on our product line for pilot batches of heat-resistant and light-fast pigments, where the integrity of the azo linkage is central. We frequently consult on adjustments to the synthetic pathway that improve yield without sacrificing purity, informed by real use in ton-scale operations.
Richness of color, consistent body, and minimal side-product generation matter greatly in dye chemistry. Customers doing high-throughput screening for potential pharmaceutical conjugates or molecular imaging agents have welcomed the monohydrochloride version for its reliable dissolution profile. Our own R&D has tested over a hundred preservation and transport scenarios, ensuring that color shifts do not occur from warehouse to client lab bench.
In analytical chemistry, this molecule supports the robust detection of metal ions by acting as a complexing reagent. Quality control managers have relayed that sensitivity and selectivity spring from the high degree of ligand fidelity, a detail that trace analytes can exploit to great effect. Long-term collaborations with academic teams have driven us to refine crystallization and drying techniques, closing the gap between theory and shipped product.
Direct control over the manufacturing floor has taught us what gives this product a real edge in practice. Our 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride is differentiated by attention to trace impurities, not just headline purity numbers. Many producers focus only on nominal assay values; we train our analytical teams to recognize the subtle contaminants that can derail a sensitive chromogenic test. That includes residues from incomplete diazotization, unreacted starting components, and instabilities from improper drying.
Compared with generic 2,6-diamino-3-(phenylazo)pyridine salts, the monohydrochloride form behaves optimally under buffered aqueous conditions, which opens up applications that would otherwise struggle with inconsistent pH or reactivity. Many standard grades offered in the market show variability batch to batch, evidenced by drifting spectroscopic baselines and unreported water content. We’ve encountered clients who, after trying bargain options, faced unpredictable yields and color shifts during downstream processing.
We produce this compound under robust process control regimes, with traceability from raw material lot codes to final release documentation. Open-chamber synthesis lines and manual transfers are phased out in favor of semi-automatic systems, reducing opportunities for contact-based contamination. Our engineering team also tracks solvent recovery rates and residual solvent screening not to check boxes, but to keep product integrity high across a wide thermal storage range.
Every specialty compound brings its own hurdles. In the case of 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride, moisture uptake remains a recurring issue post-synthesis. Managing this risk calls for not just desiccant packs in final packaging—though that remains standard—but careful monitoring as soon as vacuum drying completes. We keep environmental controls strict, using sealed transfer systems between driers and filling lines. This careful stewardship offers real value because moisture impacts not just handling, but downstream assay reproducibility.
Safety is often top of mind for our technicians. This molecule’s strong coloration can mask physical contamination and presents an inhalation nuisance if not handled with localized extraction. We invested early on in a hybrid dust and vapor extraction unit on our main production suite, a detail reflected in remarkably low workplace accident statistics. These sorts of decisions have kept downtime to minimum and built trust with clients who depend on reliable project timelines.
Waste management also cannot be ignored. Effluents from azo chemistry are treated via advanced oxidation pipelines before discharge. The process captures not just primary effluent, but minor by-products that can escape standard monitoring. We divert significant resources to training and process optimization, which translates into a lower overall environmental impact and smoother permitting from local regulators. Customers seek out suppliers with verified green credentials; we apply these best practices to maintain that trust year after year.
Bench-level trials carry weight in the chemical world because they mirror the translation from gram-scale curiosity to kilogram or even ton-scale production. We support customers by offering small pilot samples, drawn from actual process streams rather than post-hoc reconstitutions. This practice allows researchers to see how our 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride performs under real reaction pressures, thermal loads, and mechanical agitation.
Our analytical team documents every pilot run using validated SOPs, highlighting observable outcomes like color development, filterability, and product recovery. We encourage feedback from client labs, using this insight to fine-tune batch sizes and drying cycles. This approach means fewer surprises for clients moving into scale-up, with more reliable data sets to support regulatory submissions or in-house reporting.
Academic partners have pointed to our willingness to share practical details—temperature ramp rates during diazotization, choice of buffer in recrystallization, post-reaction hold times. These details can make the difference between an easy scale-up and repeated failed runs. Our own manufacturing staff take pride in identifying sources of batch failure, such as local pH hotspots or inadequate agitation. Real fixes come from honest reporting and a willingness to modify procedures in service to both safety and product value.
New hires in our plant spend weeks learning process-specific details for compounds like 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride. That includes organizing plant safety walks, joining troubleshooting sessions on the production line, and observing finished product sampling. We pair them with experienced technicians who can spot a poorly formed crystal or identify off-odors from a mismanaged batch. This hands-on involvement builds more than technical skill; it forms the backbone of a quality-focused manufacturing culture.
We also see real value in cross-training our analytical and production teams. Those who run purification columns inform those who prepare inventory and fill bags, and vice versa. Sharing knowledge this way shortens response times when equipment or formulation changes become necessary. It is not uncommon for someone in QA to spot an unusual parting line in a sample and trace it back to a specific day’s humidity spike during finishing, leading to quick adjustments in environmental controls.
Technical documentation in our facility aims for real clarity, describing common failure modes, detailing color ranges under sunlight versus filtered light, and listing known interferences with major analytical techniques. In collaborating with client labs, transparency remains crucial: no test passes without paired documentation of batch conditions, storage times, and in-house assay results. This discipline has meant fewer miscommunications and more effective problem solving on both sides of the table.
Over time, we notice trends in client feedback. Research chemists report that reactions involving 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride sometimes fail at scale, a challenge rarely seen in lab-sized trials. Our staff have learned to investigate these issues by digging deeply into not just the compound’s spec table, but also its real behaviors under process heat, pressure, and recycled solvents. By listening to these stories, we steadily update our own in-house guidelines for batch-making and sampling.
Differences in product from supplier to supplier show up dramatically in sensitive work like solid-phase peptide synthesis or chromophore engineering. Our clients in these sectors benefit from the fact that our production team captures not just yield data, but also color curve profiles over time and under different storage regimes. These practical benchmarks offer something more meaningful than a simple purity certificate, guiding client labs toward both immediate and long-term process improvements.
We frequently revisit our quality benchmarks with a focus on what matters most to the working scientist: reliable response in spectrophotometric assays, stable dissolution in buffered media, and easy integration into existing synthetic pipelines. Staff experienced in troubleshooting real-world failures provide critical insights that shape investment in equipment upgrades and QC procedure redesign. In the end, the measure of success for us is a shipment that enables discovery, not just meets published standards.
Production environments are never static. The journey from raw material intake to finished, fully labeled kilo-pack takes teamwork, foresight, and rigorous testing. Our in-house R&D drives continual process refinement, introducing enhanced filtration beds, alternative drying regimes, and more selective buffer systems as the evidence supports their benefit. We also commit real resources to root cause analysis for every defective or off-spec batch, sharing lessons learned both internally and with our client base.
Regulators and downstream partners rely on transparent documentation. We maintain full audit trails for each batch of 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride, including supplier qualification records and on-site analytical logs. Our history with third-party audits demonstrates that straightforward communication and comprehensive recordkeeping form the backbone of trust between manufacturer and end user. This approach matters because each kilogram not only represents a financial investment but also underpins high-value R&D and commercial projects.
Maintaining consistent product attributes takes vigilance. We review and verify key attributes such as color fastness, solubility thresholds, and impurity panels before shipment. Packing associates use moisture-sensitive indicators and tamper-evident seals, building further confidence for customers who receive material months after its production. In this industry, earning repeat business starts with a promise kept through honest attention to detail.
Over the past generation, our clients have emphasized the importance of more than just product supply—they value real access to technical support and transparency during troubleshooting. We host regular review sessions to examine client experiences using our 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride in ongoing projects, using feedback loops to drive process or documentation improvements. Stories from the field get weighed and responded to promptly, not just entered into a database and forgotten.
Strong partnerships mean sharing the practical realities, not just selling molecules from a catalog. Our process engineers often provide input on solvent consumption, waste minimization, or reaction scale-up based on our lived experience with this compound. We support site audits and joint technical teams, knowing that a shared problem-solving approach leads to more reliable outcomes for both manufacturer and end user.
In a world where electronic records and digital traceability are becoming the norm, we have standardized all lot tracking and shelf life data, making data transparent to partners at every step. These systems reflect a deep-seated belief in open communication—a belief that every reputable chemical operation sees as central to good science and good business.
Scientific fields using 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride continue to evolve, demanding both higher purity and adapted physical forms. We keep strict tabs on changing industry standards, especially in regulated environments like pharmaceutical and advanced materials development. Our teams have responded actively to calls for lower residual solvent content and improved lot profile consistency. This means not just incremental tweaks but periodic requalification of entire process streams, always documented to support traceability.
Feedback from both multinational customers and start-up ventures feeds into our annual process review meetings. We have shifted to greener solvent systems where possible and adopted packaging designs that improve handling for clients working at both research and manufacturing scales. Our investment in robust, validated test methods directly reflects the evolving best practices in specialty organic chemistry.
Our quality department routinely benchmarks against global standards, reporting findings directly to production and management for continuous improvement. This real-time feedback has enabled us to catch process drift early and respond before batches move out of spec, supporting our downstream partners in achieving greater efficiency and confidence in their own workflows.
Long-standing relationships with scientific and industrial users give a deep appreciation for what matters most: a product that supports repeatable, reliable results in the hands of demanding professionals. 2,6-Diamino-3-(Phenylazo)Pyridine Monohydrochloride produced on our lines has enabled research discoveries, robust quality assurance programs, and safe, efficient manufacturing in dozens of application spaces.
Backed by daily experience, our commitment stays simple: deliver a high-integrity compound that helps users do better science, faster development, and safer operations. By staying close to real problems faced in the lab and in production, and using those challenges as fuel for improvement, we offer value beyond a typical supplier relationship. In the evolving landscape of specialty chemicals, firsthand manufacturing know-how makes the difference between disappointment and success, both for us and the people counting on our products.
