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HS Code |
550028 |
| Cas Number | 487-41-2 |
| Molecular Formula | C8H6O2 |
| Molecular Weight | 134.13 |
| Iupac Name | 1-benzofuran-5-ol |
| Smiles | C1=CC2=C(C=C1O)OC=C2 |
| Inchi | InChI=1S/C8H6O2/c9-6-1-2-8-7(5-6)3-4-10-8/h1-5,9H |
| Appearance | Off-white to light brown solid |
| Melting Point | 108-112°C |
| Boiling Point | 313°C |
| Density | 1.326 g/cm³ |
| Solubility In Water | Slightly soluble |
| Pubchem Cid | 68674 |
As an accredited 1-Benzofuran-5-ol factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
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Purity 99%: 1-Benzofuran-5-ol with purity 99% is used in pharmaceutical intermediate synthesis, where it ensures high-yield and low impurity profiles in targeted molecules. Melting Point 146°C: 1-Benzofuran-5-ol with melting point 146°C is used in fine chemical manufacturing, where it provides thermal stability during high-temperature processing stages. Molecular Weight 134.13 g/mol: 1-Benzofuran-5-ol with molecular weight 134.13 g/mol is used in analytical standard preparation, where it allows for precise calibration and quantification in chromatographic assays. Particle Size ≤20 μm: 1-Benzofuran-5-ol with particle size ≤20 μm is used in formulation of solid dispersions, where it facilitates uniform distribution and dissolution rates. Stability Temperature up to 180°C: 1-Benzofuran-5-ol with stability temperature up to 180°C is used in polymer additive applications, where it maintains functional integrity under elevated processing conditions. Aqueous Solubility 120 mg/L: 1-Benzofuran-5-ol with aqueous solubility 120 mg/L is used in agrochemical formulations, where it enables effective dispersion and consistent delivery in aqueous solutions. Assay ≥98.5%: 1-Benzofuran-5-ol with assay ≥98.5% is used in medicinal chemistry research, where it supports reproducible biological activity assessments and SAR studies. Residual Solvent ≤0.5%: 1-Benzofuran-5-ol with residual solvent ≤0.5% is used in cosmetic ingredient development, where it minimizes solvent-related safety and regulatory concerns. UV Absorbance (λmax 275 nm): 1-Benzofuran-5-ol showing UV absorbance at λmax 275 nm is used in photostability studies, where it enables accurate monitoring of degradation kinetics under controlled exposure. |
| Packing | Amber glass bottle, 25 grams, tightly sealed with a white screw cap; labeled with hazard warnings, batch number, and chemical identification. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 1-Benzofuran-5-ol: Securely packed in 20-foot containers to ensure safe, bulk international shipment. |
| Shipping | 1-Benzofuran-5-ol is shipped in secure, airtight containers to prevent contamination and moisture exposure. Packaging conforms to chemical transport regulations, with clear labeling indicating hazardous nature. Shipments include safety data sheets (SDS) and comply with international chemical shipping standards to ensure safe handling and delivery. Temperature control is maintained if required. |
| Storage | 1-Benzofuran-5-ol should be stored in a tightly closed container, away from light, moisture, and incompatible substances such as strong oxidizing agents. Keep it in a cool, dry, and well-ventilated area, ideally in a chemical storage cabinet designated for organics. Proper labeling and secondary containment are recommended to prevent accidental exposure or spills. |
| Shelf Life | 1-Benzofuran-5-ol should be stored tightly sealed, protected from light and moisture; shelf life is typically 2–3 years under proper conditions. |
Competitive 1-Benzofuran-5-ol prices that fit your budget—flexible terms and customized quotes for every order.
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Manufacturing 1-Benzofuran-5-ol offers a unique window into the evolving needs of the research and production community. Over the years, direct feedback from laboratories, pharmaceutical formulators, chemical developers, and innovative startups has shaped our approach to every batch. This compound stands out for both its structure and its chemical versatility, making it an indispensable building block for those exploring novel molecular frameworks.
1-Benzofuran-5-ol, with a molecular formula of C8H6O2, delivers a fusion of aromatic stability and heterocyclic reactivity. It’s structured around a benzofuran ring with a hydroxyl group at the 5-position, a detail that researchers and synthetic chemists consistently highlight. This position creates differences in hydrogen bonding, placement on the benzene core, and possibilities for further substitution compared to related benzofurans.
Inside our manufacturing facility, the priorities revolve around precise synthetic routes that maintain high purity while limiting unwanted isomers or by-products. Our direct synthesis applies controlled reaction temperatures, careful timing between catalyst additions, and consistent monitoring for oxidative conditions. Chemists aiming to create advanced intermediates often ask about how these production considerations influence downstream performance, particularly in scaled reactions or during further functionalization.
Each request for 1-Benzofuran-5-ol usually comes paired with strict analytical requirements. Our experience points toward the importance of reliable NMR, HPLC, and GC-MS data, because even small variations in the manufacturing process introduce variance in assay results or crystallization patterns. In practice, this degree of oversight translates into batches that deliver consistent melting points, reproducible yield calculations, and confidence for repeat orders.
One of the key differences between our product and standard catalogue samples rests in long-term stability. Customers have reported that uncontrolled storage or informal purification can leave trace moisture or slow air oxidation, which shifts analytical profiles. Our process includes extended vacuum drying and inert gas packing after recrystallization—each step integrated with feedback from years of observing how subtle inconsistencies can derail a day’s worth of synthetic work.
1-Benzofuran-5-ol remains an essential starting material for a spectrum of applications. Pharmaceutical clients depend on its purity for synthesizing investigational APIs and screening leads in early-phase development. Medicinal chemists utilize the molecule’s reactive hydroxyl group to introduce ethers or employ cross-coupling reactions. The compound’s electron-rich core makes it attractive for materials chemists who look at benzofuran derivatives to develop new conductive polymers or organic optoelectronic materials.
Through direct manufacturer interactions, feedback on synthetic setbacks, or modified requirements, the emphasis always turns to traceability. Each batch includes comprehensive COAs, but seasoned users often focus more intently on process transparency and reproducibility. For example, academic groups crafting new ligand frameworks value not just HPLC results but details of raw material sourcing and intermediary purification checkpoints.
The benzofuran family covers a spectrum of derivatives, but differences at the 5-position significantly alter reactivity and downstream tuning options. 1-Benzofuran itself, lacking the hydroxyl group, fails to provide the same anchoring point for further substitution or hydrogen bonding. Other positional isomers, like 1-benzofuran-2-ol or 1-benzofuran-7-ol, shift either the electronic character or solubility, and these nuanced changes cascade into different synthetic possibilities.
Among those exploring allosteric modulators or constructing fused heterocycles, the reliability of a clean 5-hydroxy derivative matters more than a simple molecular weight or catalog number. A pure batch of 1-Benzofuran-5-ol reacts as expected in selective O-alkylation, Sonogashira coupling, or even strategic oxidations for library synthesis. Once chemists have confidently navigated one transformation with a reliably sourced product, the decision to expand further with our material or methods follows naturally.
Direct insights from researchers confirm that choosing between positional isomers goes beyond theoretical differences. In practice, mislabeling or cross-contamination between these can cause project delays or ruin attempts to establish new SAR lines in drug design. Our in-house analytical records and careful double-checks on every output remain rooted in years of confronting such real-world setbacks.
Process chemists at pilot facilities and kilo-labs have found that scaling up reactions with 1-Benzofuran-5-ol presents challenges unique to this substrate. Nuanced variations in moisture content, residual trace catalysts, or tiny impurities left in standard grade material can produce outcome variability that confounds predictions based on small-scale runs. A decade of troubleshooting at multi-kilo scale has drilled home that small errors in raw material specs multiply as reaction volumes rise.
Those developing new active pharmaceutical ingredients (APIs) have cited reaction inhibition or color formation as recurring headaches with benzofuran derivatives. Through direct investigation—examining spent reaction matrices, reviewing failed crystallizations, or assessing IR and UV traces—we identified contaminants that most catalogue vendors overlook at the gram scale. Our tighter controls over precursor identity and repeated solid-state analyses help eliminate such pitfalls.
In advanced university laboratories or commercial R&D shops, the need for rapid and reproducible transformations underpins the switch toward manufacturer-verified compounds. Some users choose on-site verification or request small pre-batches to validate performance. In every case, any shortcut in purification or incomplete drying during bulk manufacturing reverberates as lost time and resources further down the pipeline.
From the manufacturer’s perspective, project timelines and late-stage project pivots affect everything from batch size to delivery. Synthetic organic chemists frequently request modifications—such as varying hydrate content, particle size, or additional analytical data for complex downstream reactions. Our coordination with these teams means setting flexible production schedules and, at times, pausing non-essential lines to prioritize time-critical bulk orders.
Case studies from collaborative programs highlight the value of direct dialogue. In one instance, a customer targeting a highly substituted benzofuran scaffold required ultrafine 1-Benzofuran-5-ol for a low-temperature Suzuki coupling. Typical off-the-shelf batches failed to dissolve uniformly at scale, stalling the process. Adjusting our drying, refining particle sizing, and introducing a tighter sieve protocol provided the material needed to resume the project. These iterative improvements rarely show up in published specs but shape the real project outcomes.
At the production scale, 1-Benzofuran-5-ol presents both opportunities and challenges in environmental stewardship. Traditional syntheses use solvents and reagents less favored under modern green chemistry guidelines; older processes produced more chlorinated waste or required cumbersome aqueous workups. Recent years have brought our R&D into line with greener oxidants, solvent recovery, and process intensification strategies. Reducing the environmental load resonates not only with regulatory compliance but also practical cost savings and safer workplaces.
We have routinely invested in small-scale pilots using safer bases and recyclable extraction systems. Practical feedback from our own staff—those who perform the final purification or handle the drum transfers—led to design changes in reactor setup and air monitoring. These operational insights pushed our engineers to minimize fugitive dust and fumes while simplifying tank washing between cycles. Small, cumulative changes have helped address factory-level sustainability in ways that show up in monthly data, instead of only as buzzwords.
Supply chain shocks, shortages of specialty precursors, or geopolitical disruptions have affected the flow of fine chemicals worldwide. In our production runs, we stockpile critical raw materials and maintain backup sources both in-house and via trusted partners. Sudden surges in demand—often triggered by publication of new pharmaceutical leads or announcements from top research groups—require nimble response. We balance these demands to avoid both oversupply and idle inventory that risks degradation.
Production tracking follows each batch from initial raw stock through packed drum. Rather than relying solely on basic inventory software, our experienced warehouse staff manually confirm stock identity and stability for batches awaiting shipment. These checks allow us to catch early signs of lot variability or contamination long before reaching customer hands. Seasoned end users know that fine chemical reliability depends less on grand philosophy and more on mundane but essential vigilance at every stage.
One common complaint from new users—especially those buying from traders or bulk resellers—relates to inconsistent product profile or unexplained yield drops in syntheses. As direct manufacturers, we control every input and record every adjustment. Devoting labor to hands-on quality control, cross-training staff between production and quality assurance, and collecting technical feedback from both R&D chemists and plant operators enables a tightly run operation. These insights, gathered over years and batches, have proved invaluable in preventing the sorts of mishaps that plague less experienced sources.
Beyond testing for stated content or basic purity, our team actively investigates residue patterns, checks for degradation byproducts under diverse humidity and light exposures, and catalogs even rare offcuts or rejected lots. Open sharing of minor batch-to-batch discrepancies, and willingness to recall or replace at our expense, have become core to our reputation among experienced buyers.
Building relationships goes beyond just shipping a drum of material. Returns, reworked lots, and tailored shipments for pilot studies contribute directly to product improvement and more reliable research work. In many cases, regular customers reach out before starting major new syntheses, seeking technical advice or pre-validating a lot with their in-house scientists. These ongoing conversations have taught us more about bench-level chemistry than any single process manual or catalog.
From the earliest days manufacturing benzofuran derivatives, our operation has prioritized traceable inputs, consistent output, and technical transparency. Many researchers recall cost-driven projects derailed by inferior intermediates from unfamiliar vendors or loosely regulated sources. Over time, we learned to trust the collective wisdom of our end users: a batch that works well for a hundred syntheses is worth more than one that meets arbitrary spec but fails in side-by-side reactions.
Differences between our product and lower-grade alternatives become clear in contexts demanding scalable solutions. Catalog offerings may fluctuate in color, hygroscopicity, and long-term storage potential. They leave project chemists guessing about batch history or lot-specific quirks. Recognizing this, we designed our process for long-term support: documentation for regulatory agencies, advanced impurity profiling, and sample retention for retrospective testing.
Direct conversation with medicinal and materials chemists guides decisions on batch preservation, analytical priorities, and logistical arrangements for speedy delivery or alternate pack-out formats. Examples include unit-dose vials for micro-reactor loading, drum quantities for pilot facilities, and fine-tuned moisture control for sensitive downstream processes.
In choosing a direct manufacturer of 1-Benzofuran-5-ol, researchers know the benefit reaches far beyond a simple purchase. Every step of design, testing, and logistic support exists to reduce downstream unknowns and support innovative science with a dependable, well-understood substrate. Our role remains grounded in industry partnerships, technical honesty, and a shared drive for progress across every field that puts benzofuran chemistry to work.
As advanced synthetic projects evolve, the need for stable, customizable supply of critical intermediates grows in importance. Pilot programs for drug discovery, new routes for materials with improved electrical or photophysical properties, and explorations into green chemistry put extra demands on the suppliers of fine chemicals. We track these shifts and maintain active collaborations with university groups and industrial labs so we can adapt, tweak, and push our own boundaries.
Greater demand for specialty 1-Benzofuran-5-ol derivatives—those carrying isotopic or functional labels, ultra-low residual solvents, or tailor-made salt forms—has kept our R&D team engaged with long-standing partners. Instead of offering a static product line, we pursue joint developments and respond directly to suggestions for process upgrades, alternative purification pathways, or even modifications to standard testing regimens. Each of these efforts deepens our technical expertise and widens the circle of collaborators who rely on our material to drive their science forward.
As chemical research continues to push into previously uncharted space—whether targeting biological relevance, process safety, sustainability, or new mechanisms of action—the need for clarity, honesty, and reliability in chemical supply grows more pressing. Our lived experience, as direct manufacturers with thousands of batches behind us, shapes every interaction, every technical conversation, and every improvement rolled out to customers. Those lessons, gathered over years and tested in the real world, set our 1-Benzofuran-5-ol apart as a trusted foundation for the next wave of scientific advance.
