|
HS Code |
567886 |
| Chemical Name | 3-Phenoxypyridine monosulfate |
| Molecular Formula | C11H9NO5S |
| Molecular Weight | 267.26 g/mol |
| Appearance | Solid (likely crystalline or powder) |
| Solubility | Soluble in water |
| Boiling Point | Decomposes upon heating |
| Storage Conditions | Store in a cool, dry place |
| Synonyms | 3-Phenoxypyridine sulfate |
As an accredited 3-PHENOXYPYRIDINE AND MONOSULFATE factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The packaging for 3-Phenoxypyridine and Monosulfate (25 grams) is in a sealed, amber glass bottle with a tamper-evident cap. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 3-Phenoxypyridine and Monosulfate: Securely packed in sealed drums, pallets, ensuring safety and moisture protection. |
| Shipping | The shipping of 3-Phenoxypyridine and Monosulfate requires secure, leak-proof packaging, clearly labeled with proper chemical identification and hazard classifications. Transportation must comply with local and international regulations, including MSDS documentation. Store and ship in cool, dry conditions, avoiding incompatible substances, and ensure handlers utilize suitable protective equipment during transit. |
| Storage | 3-Phenoxypyridine and monosulfate should be stored in a tightly sealed container, away from moisture, heat, and direct sunlight. Store in a cool, dry, and well-ventilated area, separate from incompatible substances such as strong acids or bases. Clearly label the container, and keep it away from ignition sources. Follow all relevant safety and chemical storage regulations. |
| Shelf Life | Shelf life: Store 3-Phenoxypyridine and monosulfate in a cool, dry place; typically stable for 2–3 years in sealed containers. |
|
Purity 98%: 3-PHENOXYPYRIDINE AND MONOSULFATE with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high reaction yield and product quality. Melting Point 146°C: 3-PHENOXYPYRIDINE AND MONOSULFATE with melting point 146°C is applied in organic catalytic processes, where it enables stable operation under elevated temperatures. Particle Size < 10 μm: 3-PHENOXYPYRIDINE AND MONOSULFATE with particle size less than 10 μm is used in agrochemical formulations, where it improves dispersion and bioavailability. Stability Temperature up to 120°C: 3-PHENOXYPYRIDINE AND MONOSULFATE with stability temperature up to 120°C is utilized in material science research, where it maintains molecular integrity during prolonged thermal cycling. Water Solubility 25 mg/mL: 3-PHENOXYPYRIDINE AND MONOSULFATE with water solubility of 25 mg/mL is employed in analytical laboratories, where it facilitates easy sample preparation and accurate quantification. Molecular Weight 219.22 g/mol: 3-PHENOXYPYRIDINE AND MONOSULFATE with molecular weight 219.22 g/mol is used in chemical assay development, where it enables precise calculation of reagent requirements. |
Competitive 3-PHENOXYPYRIDINE AND MONOSULFATE prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please contact us at +8615371019725 or mail to sales7@bouling-chem.com.
We will respond to you as soon as possible.
Tel: +8615371019725
Email: sales7@bouling-chem.com
Flexible payment, competitive price, premium service - Inquire now!
Stepping into the world of specialty chemicals, it’s impossible not to notice how much detail and purpose goes into each product’s development. One compound that’s made its mark across research labs and production facilities is 3-Phenoxypyridine and Monosulfate. As anyone who’s spent time in chemical manufacturing can confirm, the difference between a reliable intermediate and a problematic one often lies in the subtle features buried in purity, stability, and adaptability. My own experience comes from years of sourcing compounds for pilot plant runs, where the blend of performance and safety matters more than any marketing pitch. That’s one reason deeper insight matters, and why 3-Phenoxypyridine and Monosulfate deserves real attention among professionals and researchers looking to move projects forward.
The chemical community often sets itself apart by the discipline of its details. 3-Phenoxypyridine carries an aromatic ring structure joined to a pyridine backbone, with a phenoxy group attached at the 3-position. Paired with monosulfate, this compound offers a unique balance between organic framework and enhanced solubility or reactivity. Labs working on agrochemical research, pharmaceutical synthesis, and advanced material applications find themselves reaching for 3-Phenoxypyridine derivatives because they fit into complex molecular scaffolds that drive invention forward. The monosulfate salt here adds another layer of utility – boosting water compatibility for reactions or purification strategies, and sometimes creating opportunities for entirely different catalytic activities.
A compound’s form, grade, and purity determine both its immediate uses and long-term storage stability. It’s common to encounter 3-Phenoxypyridine and Monosulfate in forms suitable for lab-scale syntheses – powder or crystalline solid for easier weighing and handling – with specification sheets listing purity typically above 98%, and controlled thresholds for moisture or unknown impurities. This strict attention to uncontaminated composition can save a month’s worth of troubleshooting, especially in pharmaceutical contexts, where downstream steps in drug synthesis become unpredictable if even a trace impurity is overlooked. Experienced chemists appreciate the clarity and confidence that come with these specifications. Over the years, I’ve seen lesser-quality intermediates break projects or force costly reformulations. Here, documented quality checks and batch records tie back to the principles of transparency and reliability that define the best suppliers in the field.
Talking with process engineers and researchers on the ground, the main value of 3-Phenoxypyridine and Monosulfate tends to show up in practical moments – like during a challenging Suzuki or Buchwald coupling, or when pursuing active pharmaceutical ingredients that demand nitrogen heterocycles with subtle reactivity. The compound’s architecture unlocks reaction pathways not easily available with basic pyridines or phenoxybenzenes. In one project I witnessed, a team faced with a sluggish cross-coupling reaction found their breakthrough only after switching to a monosulfate salt, which not only improved reaction rate but also simplified the workup because the product came out cleaner. This shift meant fewer problematic side reactions and less purification later. The difference wasn’t theoretical – it saved costs on solvents and column chromatography while hitting quality milestones.
It’s tempting to treat the monosulfate counterion as a minor afterthought, but in practice, its presence differentiates this product from the vast shelf of generic phenoxypyridines. The sulfate provides increased ionic character, giving the compound better solubility in water or mixed solvent systems, and sometimes acting as a mild acid source. I remember one researcher explaining how this version allowed for direct introduction into aqueous-phase coupling reactions, dropping the prep time and reducing the use of volatile organic solvents by nearly half. Monosulfate forms also tend to have superior shelf-life compared to free bases, as they’re less prone to oxidative degradation.
For those working under tight safety guidelines, avoiding volatile or basic forms can mean less time spent on hazardous material management. Monosulfate salts remain straightforward to handle, with lower volatility and reduced inhalation risk. This might not get highlighted in brochures, but for anyone tasked with setting up safe lab or plant environments, that difference changes day-to-day priorities.
Curiosity draws comparison. Phenoxypyridines come in a variety of substitutions and salt forms, but not all deliver equally on lab or production demands. Free-base forms dissolve poorly in aqueous solutions, so chemists end up introducing extra reagents just to coax them into reaction zones. Similarly, the hydrochloride or tosylate versions, while useful in some syntheses, can create compatibility issues with sensitive substrates or downstream processing, thanks to residual chloride or tosylate ions. In contrast, monosulfate pairs offer a more neutral profile, sidestepping many side reactions and showing predictable behavior under typical reaction or purification conditions.
I once saw a pharmaceutical team run parallel batches comparing monosulfate and hydrochloride salts in a stepwise synthesis. The monosulfate version maintained consistent yields batch-to-batch, while the competing salt suffered from variable conversion rates due to the lingering influence of the chloride counterion in later steps. The lesson was clear – substrate and counterion both shape outcomes, and even one small difference can reshape timelines and costs.
Personal experience in chemical productions has taught me just how closely regulatory compliance, worker protection, and product quality map onto the small choices that dominate catalog orders and inventory checks. 3-Phenoxypyridine and Monosulfate offers an edge through improved handling characteristics. Reduced volatility means less inhalation risk and fewer spills. There’s also a growing recognition of the need for greener chemistry, both to satisfy policy and to cut the waste generated during routine syntheses. Using a salt form that integrates seamlessly into water-rich systems lessens the reliance on environmentally harsh organic solvents, which is no small feat.
Trust only forms when suppliers open up about batch-to-batch data, origin of raw materials, and historical performance in both documentation and honest dialogue. The best-distributed 3-Phenoxypyridine and Monosulfate products gain repeat business by supporting rigorous tracking, providing authentic certificates of analysis, and responding quickly to user feedback. Teams benefit when information is specific – reporting precise melting points, exact moisture content, and known elemental impurities. Beyond just chemistry, this level of openness supports researchers’ confidence and shields businesses from regulatory headaches.
Commercial viability rarely hinges on how something performs in a ten-milligram micro-reaction. Once a project gets greenlit for scale-up, the conversation pivots to economic supply and straightforward replication of results. Here, the practical features of 3-Phenoxypyridine and Monosulfate shine. The form’s physical stability and robust supply channels allow for kilogram-to-ton procurement by pilot plants or even bulk production. Consistent quality across scales means development work isn’t wasted battling with solubility, batch inconsistency, or storage degradation. In my own scale-up ventures, I’ve learned that compounds not built for this transition often fail not in concept, but in shipping containers, storage warehouses, or under new reaction parameters that expose weaknesses never visible at the bench.
Scrutinizing a compound’s compliance profile means looking beyond basic MSDS paperwork or perfunctory labeling. Regulatory teams want to align with frameworks ranging from REACH in Europe to TSCA in the United States, and the best products offer transparent documentation to meet these diverse standards. 3-Phenoxypyridine and Monosulfate often comes with data supporting regulatory submissions, toxicity studies, and environmental impact evidence. Even more, it’s the clarity of this data that supports faster product development cycles and easier project signoff, especially for multinational teams or projects seeking market approval in more than one jurisdiction.
Day-to-day life for chemists rarely revolves around a single molecule, but some compounds consistently open doors for new ideas. 3-Phenoxypyridine and Monosulfate plays that role for scientists hunting new mechanisms, exploring SAR (structure-activity relationships), or optimizing synthesis protocols. Its combination of stability, solubility, and reactivity expands the synthetic toolkit, letting researchers move toward novel targets that otherwise might remain out of reach.
I’ve heard from advanced researchers in agrochemical startups, where optimizing a single step has meant unlocking a breakthrough yield or discovering a cleaner pest-control agent. This compound gave them a springboard, allowing rapid prototyping and iterative exploration. In academic settings too, availability of robust materials has a real-world effect on graduate student progress, thesis completion rates, and grant performance metrics.
Modern chemical challenges rarely respect the boundaries of one specialty. Teams span from synthetic organic chemists to process engineers, environmental scientists, and regulatory experts. 3-Phenoxypyridine and Monosulfate, by virtue of its clear handling profile and predictable physical properties, supports these collaborations. Its reliability lets project leaders assign work with confidence, bridging the gap between disciplinary expertise and project results. The ability to ensure that resources won’t introduce hidden variables into complex, time-sensitive workflows is a quality many overlook until it’s missing.
Reflecting on years working with numerous intermediates, it’s rare to find compounds that deliver on every level. While 3-Phenoxypyridine and Monosulfate gets a lot right, it’s always important to heed lessons from earlier projects. For instance, improper storage of moisture-sensitive powders can jeopardize entire inventories. Teams that invest in well-ventilated, low-humidity environments tend to see longer shelf life and fewer out-of-specification incidents. Maintaining up-to-date inventory logs and following best practices for chemical handling add further assurance.
Supply chain disruptions in recent years have emphasized the value of reliable domestic and international sources. Diversifying suppliers while rigorously testing incoming batches keeps projects on track, and suppliers recognized for their customer service and technical support win long-term loyalty. In several high-stakes projects I've supported, it wasn’t the flashiest new intermediate that won out, but the one backed by strong post-sale technical advice and fast turnaround on critical documentation.
As industries move toward greener processes, demand for chemicals that enable water-based reactions or minimize waste byproducts keeps increasing. 3-Phenoxypyridine and Monosulfate aligns well with these goals, providing a multipurpose building block for synthesis without the hazards of high volatility or harsh processing conditions. This is more than a matter of ticking regulatory boxes – it’s about doing business in a way that respects the planet and ensures future generations have options for invention.
There’s a strong push in both academia and industry to reduce dependence on legacy solvents and process aids with heavy environmental footprints. Substances compatible with benign conditions find easier integration into new workflows. Research consortia and public-private partnerships place high value on reagents able to move between exploratory research and scaled industry, favoring those with strong data on performance, safety, and long-term environmental effect.
The shift toward open science and collaborative development benefits from widely available performance data, application examples, and crystal structure information. Manufacturers and distributors who publish case studies detailing real-world results – not just stock photos and vague benefits – empower the next wave of innovation. 3-Phenoxypyridine and Monosulfate, backed by a record of peer-reviewed research, technical presentations, and ongoing user feedback, stands out as more than a commodity.
Communities built around transparent data exchange and professional curiosity will keep raising the bar for quality and reliability. In my peer groups, hands-on knowledge-sharing about better intermediates, improved yields, and unexpected synthetic routes isn’t just academic – it’s a survival skill. That culture rewards those who listen, document, and deliver concrete, evidence-based answers.
Any specialist working in chemical development or scale-up knows that today’s solution might become tomorrow’s bottleneck. Keeping open lines of communication with suppliers, on-the-ground researchers, and regulatory experts ensures new challenges don’t slip past unnoticed. The commitment to ongoing product testing, transparent failure reporting, and continuous feedback loops distinguishes high-performing teams and the chemicals they rely on.
In the case of 3-Phenoxypyridine and Monosulfate, steady investment in quality analytics and post-market surveillance helps correct minor problems before they become large ones. Documented histories of process deviations, rapid resolution, and lessons learned in partnership with users reinforce a network of trust that carries real monetary and technical value.
Every time I’ve weighed out a portion of 3-Phenoxypyridine and Monosulfate or checked certificates of analysis before a critical batch, the connection between a single compound and the broader trajectory of a project comes into focus. Whether it’s progress in process optimization, safety improvements for plant personnel, or the pursuit of innovative new active ingredients, this compound built its reputation on strengths that transcend chemical structure alone.
Many products pass through labs with little fanfare, but the ones that combine quality, adaptability, and documented performance shape the outcomes of research, discovery, and manufacturing alike. 3-Phenoxypyridine and Monosulfate fits well into that category, reminding us all that good chemistry means more than mixing molecules – it’s about forging reliable partnerships in pursuit of progress.
