|
HS Code |
740598 |
| Chemicalname | Adamantane |
| Chemicalformula | C10H16 |
| Molarmass | 136.24 g/mol |
| Appearance | White crystalline solid |
| Meltingpoint | 270 °C |
| Boilingpoint | 186-187 °C (at 15 mmHg) |
| Density | 1.08 g/cm³ |
| Solubilityinwater | Insoluble |
| Casnumber | 281-23-2 |
| Odor | Camphor-like |
| Structuretype | Cage hydrocarbon |
| Refractiveindex | 1.572 |
| Flashpoint | 145 °C |
| Vaporpressure | 1 mmHg at 150 °C |
As an accredited Adamantane factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
|
Purity 99%: Adamantane purity 99% is used in pharmaceutical synthesis, where it ensures consistent drug compound quality. Melting Point 270°C: Adamantane melting point 270°C is used in heat-resistant polymer production, where it improves thermal stability of the end product. Molecular Weight 136.24 g/mol: Adamantane molecular weight 136.24 g/mol is used in organic chemistry research, where it facilitates accurate stoichiometric calculations. Particle Size < 50μm: Adamantane particle size < 50μm is used in catalyst formulation, where it enables uniform dispersion in reaction mixtures. Stability Temperature up to 500°C: Adamantane stability temperature up to 500°C is used in high-temperature lubricant manufacturing, where it enhances lubricant performance under extreme conditions. Viscosity Modifier: Adamantane viscosity modifier grade is used in specialty oil blends, where it improves flow properties and reduces friction losses. High Volatility: Adamantane high volatility grade is used in analytical chemistry as a reference standard, where it provides reliable calibration results. Hydrophobicity Index: Adamantane hydrophobicity index 1.2 is used in membrane material design, where it increases water repellency and selectivity. Density 1.07 g/cm³: Adamantane density 1.07 g/cm³ is used in epoxy resin composites, where it contributes to mechanical strength and uniform matrix distribution. UV Stability: Adamantane UV stability grade is used in coating formulations, where it enhances resistance to photodegradation. |
| Packing | Adamantane, 100 grams, is packaged in a sealed amber glass bottle with a tamper-evident cap and detailed hazard labeling. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for Adamantane involves securely packing bulk quantities in drums or bags, maximizing space and ensuring safe transport. |
| Shipping | Adamantane is shipped in tightly sealed containers to prevent contamination and moisture exposure. It should be stored in a cool, dry, well-ventilated area, away from heat, ignition sources, and incompatible substances. All packages should comply with relevant transportation regulations, using appropriate labeling and documentation to ensure safe handling and delivery. |
| Storage | Adamantane should be stored in a tightly closed container in a cool, dry, well-ventilated area, away from sources of ignition or heat. It should be kept separate from strong oxidizing agents and acids. Storage containers should be labeled appropriately, and the area should be free from moisture to prevent degradation. Proper chemical storage protocols and personal protective equipment must be observed. |
| Shelf Life | Adamantane has a long shelf life; it is stable under normal storage conditions, typically exceeding several years when kept dry and sealed. |
Competitive Adamantane prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please contact us at +8615365186327 or mail to sales3@ascent-chem.com.
We will respond to you as soon as possible.
Tel: +8615365186327
Email: sales3@ascent-chem.com
Flexible payment, competitive price, premium service - Inquire now!
Adamantane stands apart for its extraordinary molecular geometry, distinguished by its rigid, diamond-like cage structure. For us as direct manufacturers, the unique lattice arrangement delivers consistent physical properties batch after batch. Our technical team manages every stage — from sourcing high-purity reagents, maintaining controlled reaction conditions, to downstream purification. This entire process preserves the molecular integrity, guarding against the typical impurities that tend to plague less meticulously produced chemical materials.
Several decades ago, chemists admired adamantane chiefly for its scientific curiosity. Today, our production lines have scaled the material into an industrial mainstay. Every week, in our reactors, we observe the clean transformation as precise stoichiometry and temperature control drive selectivity. Analytical chemists follow the material through every stage, ensuring compliance with the tightest specifications for melting point, volatility, and purity profile. The market now expects this reliability — and those who work up-close appreciate it.
Adamantane’s structure makes it far from a plain hydrocarbon. The tetrahedral carbon framework resists deformation, limiting the number of useful chemical modifications. In practice, this gives adamantane some unusual advantages rarely matched by conventional cyclic hydrocarbons. It behaves like a thermally robust scaffold, resisting breakdown above 200°C. We use a series of custom distillation steps to narrow the boiling range to precise, verifiable limits. This level of thermal stability rarely appears in hydrocarbons of comparable molecular mass.
As a manufacturer supplying research labs, pharmaceutical intermediates producers, and electronics companies, we keep quality control at the center of all operations. Every container displays not only CAS number and batch traceability but is supported by certificates generated from in-house gas chromatography and NMR analysis. Our chemists have refined the synthesis to minimize contaminants that could hinder downstream usage—whether that’s sulfonation in pharmaceutical APIs, or nanoparticle surface functionalization in electronics labs.
The adamantane made in our facility appears as pristine, snow-white crystals, free-flowing and easy to handle. Typical melting point sits between 264°C to 268°C, a vital check that confirms batch purity. Each lot undergoes screening for residual aromatic and aliphatic contaminants, which may otherwise influence trace analysis work for clients in analytical chemistry.
Particle size remains consistent, avoiding the static and clumping problems that occur when the material comes from insufficiently refined sources. Vapor pressure measurements at different temperatures get logged and checked to maintain predictability for clients scaling up vapor-phase reactions. Moisture content, often overlooked, can cripple reactivity for moisture-sensitive applications — we test each shipment for it using Karl Fischer titration, holding the threshold below internally set maximums for specialty chemical production.
Across the supply chain, adamantane from the original manufacturing source makes a difference laboratory users and process engineers can observe immediately. Many chemical traders sell similar-looking crystalline chemicals labeled as “adamantane.” But only direct manufacturers can guarantee process transparency and rapid response to technical questions. Batch recall is immediate, as our production logs track each kilogram to reactor and shift.
While some outside sources may deliver acceptable appearance on the surface, the deeper tests uncover differences in trace composition, especially persistent organics, moisture, and volatile hydrocarbons that escape cursory testing. Working as a direct producer means we have control over each stage and can optimize specifically for the demanding physical characteristics needed for regulated pharmaceutical synthesis or electronics-grade surface chemistry.
Another overlooked aspect grows from decades of operator experience on the production floor. Temperature ramp, reaction time, and catalyst composition changes year to year, as raw materials subtly shift with global supply conditions. Our plant chemists routinely adjust and document these changes. Small improvements — like switching to higher-purity initial hydrocarbons or tweaking column heights for finer distillations — ripple out through every subsequent kilogram. Traders and repackers working from bulk tanks in remote locations rarely have access to this level of feedback or the material’s full data history.
Adamantane’s journey through industry began in research laboratories, but today spans much wider applications. In pharmaceuticals, chemists draw on adamantane as a backbone in antiviral drugs, with rimantadine and amantadine built directly on the molecule’s core. Direct manufacturing allows us to supply pharmaceutical companies with batches certified not only for hazard compliance, but also for the nuanced reactivity needed for stepwise functionalization.
Beyond small-molecule drugs, research projects at universities and advanced materials labs handle adamantane for constructing new surface coatings, or for template-driven polymer synthesis. The rigid cage structure supports cross-linking that softer hydrocarbons can’t match. Our experience working directly with researchers has shaped our shipping packs and documentation for effortless use — custom weights, nitrogen-purged packaging, and rapid response to requests for additional analysis.
Adamantane’s value in electronics stems from its role as a building block for dielectric films and as a stabilizer in liquid crystals. Direct relation with electronics manufacturers teaches us their tolerance for contaminants is even tighter than most pharmaceutical intermediates. Hydration, trace metal content, and surface purity all affect device yield — we respond directly with extra panel analysis for these metrics, anchored by a manufacturing protocol tuned for semiconductor and display industry standards.
Other applications keep emerging. Hydrophobic coatings benefit from adamantane’s resistance to degradation. Synthetic lubricants take advantage of its thermal reliability. From the manufacturer side, we see the patterns in demand as industries adapt and evolve their products, and this pushes us to maintain both stock and adaptability.
Comparing adamantane with other common hydrocarbon compounds highlights several differences. Cyclohexane, decalin, and cubane often turn up in similar research, but their use cases diverge sharply. Cyclohexane and decalin, for instance, have lower melting points, much higher volatility, and softer molecular shapes. Those properties rule them out in cases demanding long-term heat resistance or when precise molecular scaffolding matters in organic synthesis or device fabrication.
Cubane, with its even more strained structure, looks tempting for custom syntheses, yet brings a risk of instability and higher cost. Adamantane sits in a sweet spot: rigid, stable, nonaromatic, and available at industrial scale. Our facility routinely receives questions from chemical engineers comparing the performance of adamantane vs. its analogues in specialty polymer production, and the feedback is persistent — only adamantane consistently delivers thermal endurance, resistance to chemical attack, and reliable handling under ambient conditions.
Sourcing adamantane straight from the manufacturer avoids another common pitfall: trace contamination with aromatic hydrocarbons, subtle yet problematic in NMR, IR, or GC-MS work. Traders and secondary packagers typically lack the extended purification sequence that can drive unwanted components down to sub-ppm levels. In specialty applications — such as building photostable compounds, or in next-generation lithium battery research — purity confirmed by multinuclear NMR and high-res mass spectrometry makes all the difference. We continually update our procedures as downstream demands evolve.
In chemical manufacturing, theory only brings results when paired with execution. Adamantane’s solid-state stability can lull new suppliers into shortcutting on drying or packaging, especially if their teams lack years of floor experience. Ruptured delivery containers or off-odor on opening betray poor curation in transit or aging inventory. We count it as our responsibility to deliver material still at peak attributes, no matter when a customer calls up a shipment from warehousing.
The decades spent synthesizing, refining, and packaging adamantane have led to what we now consider the “real” minimum specifications — not just the purity figures on paper, but the hands-on details that working chemists notice. Each upscaling project — whether it’s a jump from a few kilograms to tons or customized for a pilot process — brings new challenges. Pressure regulation, solvent selection, and reactor material compatibility become conversations between our process engineers, plant operators, and the customer’s own technical staff.
Direct manufacturing keeps the feedback loop short. We monitor storage conditions, thermal cycling during transport, and (for high-sensitivity users) provide per-shipment post-delivery analysis on request. Years of logistical experience tell us which pack sizes reduce clumping, which containers best resist static, and which courier options are safest for the application at hand, whether urgent pharma projects, time-sensitive electronics work, or method development in new sectors.
Adamantane production isn’t static. Our knowledge base grows with every batch, audit, complaint, or suggestion from downstream chemists. Regular reviews of raw material integrity, investment in more selective catalysts, and upgrades to analytics keep our process both innovative and consistent in outcome. Our R&D chemists experiment year-round to improve conversion yield, eliminate problematic byproducts, and trim energy use without jeopardizing product stability.
No day is typical in manufacturing. Sudden fluctuations in feedstock quality, global logistics interruptions, or shifting regulatory perspectives all demand that we adapt fast. Our well-established standard operating procedures act as both backbone and a launching pad for swift adjustment. Each plant operator is trained not just on what to do, but on why: understanding not just how to meet the adamantane grade, but how to spot anomalies that only real hands-on familiarity reveals.
Traceability forms an essential feature for industrial buyers — from the first blend of catalyst through to final pallet loading. On-site QA/QC labs support round-the-clock checks, not as bureaucracy, but as the straightforward backbone of material assurance. Problems rarely get lost in communication: technical experts remain available by phone and email, and site visits from customer process engineers are routine for large or customized shipments.
Serving global customers puts practical demands on packaging, logistics, documentation, and after-sales support. Every region brings distinct regulatory needs — from Eurasian Economic Union certifications to REACH or region-specific hazard statements. Our compliance team updates paperwork proactively and communicates any changes up the chain promptly. No batch leaves our warehouse without full regulatory documentation and application-specific certificates of analysis.
Adamantane leaves our plant for many different destinations: research centers in Europe, pharmaceutical manufacturing lines in East Asia, electronics development labs in North America. Field experience shows that what matters most is consistency — purity, particle size, dryness, packaging, labeling, and follow-through if issues arise. Our relationship with clients is built not on selling a list of features, but on proving over time that we can meet the real-world demands of their processes, even as market uses evolve.
Direct feedback from users on the ground often leads to improvements in both product and process. Whether it’s engineers working to improve chip yields, academic researchers exploring new materials, or industrial chemists scaling up new routes for established drugs, their insights filter back to our production team. Adjustments to ramp rates, better solvent recovery, or smarter nitrogen-purged packs — such improvements often come out of these working relationships, and drive the incremental advancements that set the standard for the next batch.
Consistently delivering high-quality adamantane comes from a blend of theory, practice, oversight, and open channels with users worldwide. Every improvement made on the plant floor — a new drying cycle, an upgraded filtering rig, a smarter data tracking system — influences the final material that arrives in a customer’s lab. Our plant personnel take pride in solving operational puzzles, hunting down sources of contamination, and seeing the results reflected in tighter analytics.
The company’s focus on direct manufacturing means problems rarely get lost or deferred. If a user flags an off-spec shipment, our technical team has the authority and the records to investigate immediately. We can pull historical data, reproduce the synthesis, and trace any deviation back to its origin. This responsiveness is only possible in a manufacturing culture geared for continuous process control rather than the looser standards that sometimes arise in re-bottled, relabelled, or bulk-shutdown material.
Quality doesn’t stop at the door. Regularly, our operators swap stories and strategies with their counterparts at customer sites, sharing knowledge about reactor lining materials, agitation rates, or optimal handling. Global travel for audits and customer support keeps the manufacturing philosophy rooted in hands-on, visible performance rather than theoretical assurance. The market’s trust comes from this open exchange, backed up by years of documentation, not just by passing a regulatory threshold.
Current industrial and academic interest in adamantane hints at greater importance in future materials research, pharmaceutical innovation, and electronic component design. As new methods for functionalizing adamantane surfaces emerge, direct supply becomes critical. Manufacturers have the readiness to adapt, optimize, and meet upcoming needs when knowledge stays anchored in practical experience, not abstract promise.
Green chemistry presents another challenge. Reducing solvent footprint, improving yield ratios, and optimizing thermal cycles remain goals we work toward every year. Steady investment in new reactors, more precise distillation units, and waste heat recovery has yielded significant returns for us as a chemical manufacturer, and those savings pass to end users through more consistent, reliable, and competitively priced supply.
Adamantane’s distinctive molecular architecture means new applications keep surfacing, making direct lines between user and producer especially important for time-sensitive R&D work. We help researchers and engineers move from small-scale bench chemistry to full industrial production without the headaches of variable feedstock, uncertain purity, or shifting documentation. Responsibility extends well beyond synthesis — it covers logistics, compliance, real-life adaptability, and technical support at every stage.
For us, producing adamantane never feels like a commodity business. In a marketplace full of relabelled material, true value traces back to a manufacturer who knows the molecule’s behavior not just through theory, but from years of trial, error, and continuous improvement. Our investment in people, systems, and deep technical support guarantees every delivered kilogram supports the most demanding applications, whether they come from pharmaceuticals, electronics, advanced materials, or new sectors yet to emerge.
From plant floor to packaged product, our knowledge as a chemical manufacturer builds not just a better chemical, but stronger downstream science and industry as a whole.
