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HS Code |
695203 |
| Cas Number | 500-86-3 |
| Molecular Formula | C10H16O2 |
| Molecular Weight | 168.23 g/mol |
| Synonyms | Adamantane-1,3-diol |
| Appearance | White crystalline powder |
| Melting Point | 244-248 °C |
| Solubility In Water | Slightly soluble |
| Boiling Point | Decomposes before boiling |
| Density | 1.22 g/cm³ |
| Pubchem Cid | 10742 |
| Smiles | OC1CC2CC3CC1CC(O)(C2)C3 |
| Inchi | InChI=1S/C10H16O2/c11-9-3-1-7-4-2-8(5-9)10(12,6-7)9/h7-12H,1-6H2 |
| Ec Number | 207-919-6 |
| Applications | Intermediate in organic synthesis |
As an accredited 1,3-Dihydroxyadamantane factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The chemical 1,3-Dihydroxyadamantane is supplied in a 100g amber glass bottle with a secure screw cap and detailed labeling. |
| Container Loading (20′ FCL) | Container loading (20′ FCL) for 1,3-Dihydroxyadamantane typically accommodates 8-10 metric tons, packed in secure, moisture-proof drums or bags. |
| Shipping | 1,3-Dihydroxyadamantane is typically shipped in tightly sealed containers, protected from moisture and direct sunlight. It should be handled according to standard chemical safety protocols. Ensure containers are clearly labeled and kept upright during transit. During shipping, comply with local regulations regarding chemical transportation and provide appropriate documentation. |
| Storage | 1,3-Dihydroxyadamantane should be stored in a tightly closed container, in a cool, dry, and well-ventilated area. Keep away from sources of heat, moisture, and incompatible substances such as strong oxidizing agents. Store at room temperature and avoid direct sunlight. Ensure proper labeling and prevent contamination to maintain chemical stability and safety. |
| Shelf Life | 1,3-Dihydroxyadamantane typically has a shelf life of 2–3 years if stored in a cool, dry, and tightly sealed container. |
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Purity 99%: 1,3-Dihydroxyadamantane with purity 99% is used in pharmaceutical intermediate synthesis, where it ensures high yield and minimal impurities in active compound production. Melting Point 175°C: 1,3-Dihydroxyadamantane with a melting point of 175°C is utilized in resin formulation applications, where it promotes enhanced thermal stability of the polymer matrix. Molecular Weight 184.24 g/mol: 1,3-Dihydroxyadamantane with molecular weight 184.24 g/mol is applied in organic electronics manufacturing, where it enables precise calculation of stoichiometry in material blends. Particle Size <100 μm: 1,3-Dihydroxyadamantane with particle size less than 100 μm is used in specialty coatings, where it provides uniform dispersion and improved surface smoothness. Stability Temperature 200°C: 1,3-Dihydroxyadamantane with stability temperature of 200°C is deployed in engineered composite materials, where it maintains structure integrity under high-heat processing conditions. Viscosity Grade Low: 1,3-Dihydroxyadamantane of low viscosity grade is employed in ink formulation, where it enables optimal flow characteristics and reduces printhead clogging. |
Competitive 1,3-Dihydroxyadamantane prices that fit your budget—flexible terms and customized quotes for every order.
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In our years of producing complex intermediates for specialty chemicals, 1,3-Dihydroxyadamantane has proven to be a staple for several advanced applications. Known to many as a robust building block, it bridges requirements in pharmaceuticals, coatings, high-performance plastics, and advanced research. By carefully controlling the quality and source of every feedstock, we maintain purity and consistency that form the backbone of our reputation in the industry.
The product stands out with its crystalline white appearance, offering a melting point that supports various synthetic processes. Our standard model, drawn from demand in both research and manufacturing, features a purity exceeding 98%. Each lot goes through multiple verification steps under strict cGMP or technical standards, depending on the customer need. Strong attention to raw material traceability ensures the final material does not introduce contaminants or variability, which can threaten delicate downstream manufacturing or formulation tasks.
Speaking directly as a manufacturer, the synthesis of 1,3-Dihydroxyadamantane involves disciplined, monitored steps. Starting with high-purity adamantane, we carry out controlled hydroxylation—a sequence we’ve optimized over many campaigns to avoid over- or under-hydroxylation. This tight process, which uses custom glass-lined reactors and calibrated reaction times, means lower impurity levels and less by-product formation. Each run gets evaluated by our in-house analytical chemists using HPLC, GC, and mass spectrometry for both content and trace-level side products. These extra verification steps set our material apart in reliability, particularly for regulated uses or projects with elevated quality demands.
1,3-Dihydroxyadamantane serves as a foundation in pharmaceuticals, especially for certain antiviral and neuroprotective drugs. Process development teams count on our batches for their consistent reactivity, which translates to stable API yields and predictable process scale-up. The limited batch-to-batch variability simplifies regulatory approval documentation since analytical profiles remains tight. In polymer chemistry, researchers turn to this molecule as a crosslinker or monomer component, taking advantage of its rigid adamantane core for impact-resistant, chemically stable polymers.
Another application comes from coatings. Chemists looking to build hydrophobic barriers or durable surface finishes value the controlled hydroxyl groups—these give formulators a simple route to anchor onto more complex resin systems or siloxane modifiers. Our customers who work in R&D or scale-up labs frequently remark on ease of mixing and predictable reaction kinetics, points that result from the way we tightly monitor moisture and residual solvents in finished lots.
Getting 1,3-Dihydroxyadamantane straight from the manufacturer brings several concrete benefits. We maintain direct control over every process step, from raw material sourcing to final packaging. This gives us agility to customize according to project requirements, such as producing alternate particle sizes, implementing stricter endotoxin screening, or tailoring packaging for high-sensitivity environments.
Direct feedback from customers feeds into our process improvements as well. If a synthetic chemist raises an issue with particle flow or dissolution speed, we tweak the drying or crystallization phase to improve the next batch. Access to firsthand data—rather than relying on distributor feedback loops—helps us pinpoint and eliminate bottlenecks quickly. We do not dilute our product with offspec lots or randomize batches for resale. Clients receive a single-lot, fully traceable consignment, reducing unexpected surprises in critical processes.
On the market, you’ll see a handful of hydroxyl-functional adamantane derivatives. While each has its place, 1,3-Dihydroxyadamantane delivers unique advantages. For one, its controlled symmetric substitution pattern means reactants attach just where chemists expect, which is not always the case with higher-substituted or randomly functionalized adamantanes. When using 1,3,5-trihydroxyadamantane, for example, side reactions and crosslinking can increase unpredictably, complicating process control. Our experience shows that most users prefer 1,3-Dihydroxyadamantane for precise, two-point attachment or for downstream conversion to esters, ethers, or urethane linkages.
There are also one-hydroxyl analogues on the market. These sometimes suit simple substitutions, but 1,3-Dihydroxyadamantane opens the door to bidentate reactivity and structured network materials. Its lower melting point compared to fully substituted analogues makes dissolution and handling more reliable in large-scale processes. Rigorous moisture specification gives us an edge in applications such as polymer synthesis or pharma intermediates, as uncontrolled water traces can scuttle yields or drive unwanted side reactions.
Throughout years of supplying this specialty, manufacturers like us have learned that even small inconsistencies in product quality can ripple through an entire supply chain. If an R&D team qualifies a batch with certain reactivity or melting characteristics, a subtle change can slow down their project or introduce unpredictable results. In pharmaceutical production, even minor off-spec levels of related substances can trigger costly investigations by regulatory teams. By keeping batch records, retaining sample libraries, and monitoring supplier performance for each raw material, we cut back on these risks for our customers.
Our team does not simply blend imported or technical-grade raw materials. We monitor upstream suppliers, audit their materials for residual or process contaminants, and only select partners who use closed-loop handling for critical reagents. Final product gets packaged in inert-atmosphere bags or drums, preventing introduction of humidity during shipping—this practice alone accounts for the consistently high yields our clients achieve in their own plants.
Working with different customers—ranging from university labs to multi-site pharmaceutical plants—has highlighted real-world product handling challenges. Static electricity in dry climates, uncontrolled ambient moisture during weighing or blending, and accidental contamination during transfer are issues our logistics and quality teams address. For sensitive projects, we offer pre-measured sachets under nitrogen-purged packaging, which saves time on cross-checks and minimizes possible handling mistakes. Our customer support team often helps with questions about process integration or troubleshooting batch profile variations, using knowledge drawn directly from our synthesis and testing labs.
In our observation, project delays or failures stem just as often from logistical missteps as from core process chemistry issues. By staying in close contact with customers, responding quickly to technical queries, and sharing updates about process changes or lot characteristics, we keep projects on track. Our role does not end after shipping—the feedback loop remains open for field performance or analytical questions that come up after delivery.
Sustainable practice forms a cornerstone of our operation. 1,3-Dihydroxyadamantane production involves oxidants and solvents that, if handled carelessly, would add to environmental load or safety risk. We designed our reactors with full vapor recovery to minimize fugitive emissions. Spent streams are recovered and recycled for both safety and cost reasons. We source solvents with a high recovery value and regularly audit waste removal processes with certified local partners.
On the safety front, training and risk-assessment go hand-in-hand. Our teams conduct annual safety audits, update operational procedures, and rehearse emergency drills, reducing the chance of incidents or downtime. For customers, this strict in-factory safety profile means the material they receive carries minimal risk of unknown by-products or unexpected hazards. Manufacturing under continuous improvement principles makes the supply of 1,3-Dihydroxyadamantane safer, cleaner, and more reliable.
One benefit of manufacturing directly is our ability to meet unique requests, some driven by research labs and others by mature production sites. Some partners ask for micronized product for rapid dissolution, some need specific moisture levels for water-sensitive catalysts, and others require larger crystals for bulk powder handling. Since every custom specification affects reaction behavior, we invest in small-batch trials before restocking or introducing process changes.
Close interaction with formulation chemists and production engineers allows us to anticipate downstream challenges—such as clogging of feed systems, settling in hoppers, or degradation in warm storage rooms. Our team logs every non-standard request and keeps a record of final delivery outcomes. These post-project reviews refine our ability to serve the next set of customers more efficiently.
Feedback from partners using our 1,3-Dihydroxyadamantane regularly yields insights we build back into the manufacturing loop. In pharmaceutical intermediates, teams have reported improved yield and batch reproducibility versus locally sourced material. A surface coatings factory sought our advice after seeing poor dispersion during resin modification; by reducing average particle size, they recovered batch throughput and minimized filter blockages. For those creating high-R&D formulations, controlling trace metal content proved critical, so we added an ion-exchange purification step upon request.
These collaborations show how manufacturer-customer engagement sharpens both product profile and downstream performance. Direct dialogue often uncovers subtle points that do not appear in data sheets—like color drift during storage, interaction with specific catalyst packages, or foaming during mixing. The improvements we make in response to this real-world data lower plant downtime and boost yield reliability for all customers.
Ensuring on-time, in-spec deliveries has been a continual focus. Weather events, border delays, and regulatory checks impact timing more than many realize. Our logistics and inventory control teams run simulations on customs cycle time, test various packing formats for international travel, and keep open options for air or sea freight. Customers have asked about cold chain logistics for moisture-sensitive batches; by building double-barrier packaging with desiccant and real humidity trackers, we help preserve product through longer routes or unpredictable customs holds.
Transparent communication keeps projects on schedule. Before shipment, we alert partners about estimated arrival windows, documentation, and regulatory clearance times. This proactive approach has allowed several customers to plan runs with confidence, avoiding expensive shutdowns or bottlenecks tied to ingredient shortfalls.
The chemistry landscape keeps changing, with new processes, greener regulations, and tougher purity demands. As a manufacturer, we treat every customer request as feedback for future upgrades—whether through tighter process telemetry or improved in-process controls. New investments in reactor monitoring and analytical equipment let us catch process drift before it affects yields or processability.
The drive to keep up with changing requirements also means sharing best practices with stakeholders. We organize periodic technical workshops, invite feedback from formulation experts, and explore pilot scale-up challenges together. The ideal result: fewer process upsets, more cost-effective manufacturing, and continued readiness to support novel applications for 1,3-Dihydroxyadamantane as industries grow and change.
Producing 1,3-Dihydroxyadamantane consistently and safely involves more than just following a recipe. Decades of cumulative knowhow, an eye for the details that shape end-user success, and a commitment to transparency define how we approach every order. Direct feedback, strict quality control, and nimble problem solving set manufactured product apart from re-packed, blended, or indirectly sourced alternatives.
At every phase—from raw material acceptance to delivery, storage, and application support—customers benefit from a supply chain anchored by people who know the chemistry and use cases inside out. Our mission is to deliver not just a product, but a technical partnership that makes better results possible every run.
