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All Right Reserved
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HS Code |
199653 |
| Product Name | 2-Adamantane |
| Purity | 99.5% |
| Chemical Formula | C10H16 |
| Molecular Weight | 136.23 g/mol |
| Cas Number | 700-58-3 |
| Appearance | White crystalline powder |
| Melting Point | 181-183°C |
| Boiling Point | 208°C |
| Density | 1.02 g/cm³ |
| Solubility In Water | Insoluble |
| Storage Temperature | Room temperature |
| Flash Point | 99°C |
| Refractive Index | 1.622 |
| Synonyms | Adamantan-2-yl, 2-Adamantanone |
As an accredited 2-Adamantane (99.5%) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 2-Adamantane (99.5%) is supplied in a 100g amber glass bottle with a secure, screw-cap lid and clear labeling. |
| Shipping | **Shipping Description for 2-Adamantane (99.5%)**: 2-Adamantane (99.5%) is shipped in secure, airtight containers to prevent contamination and moisture exposure. Each package is clearly labeled with product and hazard information. Shipping complies with local and international chemical transport regulations, ensuring safe handling. Temperature-controlled transportation may be used if required by safety data sheet guidelines. |
| Storage | 2-Adamantane (99.5%) should be stored in a tightly sealed container in a cool, dry, and well-ventilated area, away from sources of ignition and incompatible materials such as strong oxidizing agents. Protect from moisture and direct sunlight. Label the container clearly, and ensure access is restricted to trained personnel. Follow all relevant safety guidelines and local regulations. |
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Purity 99.5%: 2-Adamantane (99.5%) is used in pharmaceutical synthesis, where its high purity ensures consistent reaction yields and product safety. Melting Point 269°C: 2-Adamantane (99.5%) is used in high-temperature organic synthesis, where its elevated melting point facilitates thermal stability during processing. Molecular Formula C10H16: 2-Adamantane (99.5%) is used as a precursor in advanced material fabrication, where precise molecular composition enhances structural reliability. Stability Temperature up to 250°C: 2-Adamantane (99.5%) is used in polymer modification, where its thermal stability allows for reliable performance during extrusion processes. Particle Size <50 μm: 2-Adamantane (99.5%) is used in composite material production, where its fine particle size ensures homogeneous distribution and optimal mechanical properties. Hydrophobicity Index 6.02: 2-Adamantane (99.5%) is used in coating formulations, where its high hydrophobicity imparts water-repellent surface characteristics. Volatility Low: 2-Adamantane (99.5%) is used in electronics manufacturing, where low volatility minimizes material loss during vacuum deposition. Chemical Inertness: 2-Adamantane (99.5%) is used in analytical standard preparations, where chemical inertness prevents interference in chromatographic analysis. Solubility in Organic Solvents: 2-Adamantane (99.5%) is used in catalyst carrier preparation, where its solubility facilitates uniform catalyst dispersion. Bulk Density 0.98 g/cm³: 2-Adamantane (99.5%) is used in advanced resin formulation, where its controlled bulk density aids accurate dosing and consistent mixture. |
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Chemistry keeps changing the way we live and work, and not every compound gets its fair share of the spotlight. I learned this when I first started handling specialty chemicals in industry labs, and 2-Adamantane showed up on my checklist. This hydrocarbon carries a unique structure under the hood—think of a diamond lattice, but shaped into a tiny dome instead of a rigid block. With 99.5% purity, 2-Adamantane stands out for anyone looking to bring precision and reliability to their process, whether that’s crafting advanced drugs or developing new materials.
What sets 2-Adamantane apart isn’t just its name, but the cage-like shape. Scientists call this a tricyclic saturated hydrocarbon, but to most of us, it means a solid structure that doesn’t fall apart easily. Years ago, I worked with blends that were plagued by stability issues—fragile skeletons that broke under heat or chemical stress. 2-Adamantane, with its unique molecular frame, resists those breakdowns. Heat it, expose it to light, shake it with strong acids—most times, 2-Adamantane holds its own.
Its melting point sits high compared to many similar compounds, and I found that helped a lot with storage. My first warehouse job drilled into me the damage heat can do when summer rolls in. Some chemicals arrive as a gooey mess. But 2-Adamantane, with its crystal-clear solid state, stays dependable no matter the warehouse temperature swings. For professionals who need consistency, this is a big plus.
Purity isn’t just a number—especially when you have one stray molecule in a batch throwing off the whole reaction. I saw this firsthand while working on a batch synthesis of a new antiviral drug; contaminants produced byproducts that set off alarms in quality control. That’s why the 99.5% purity of this 2-Adamantane wins trust. Each bottle offers proven reliability, cutting down troubleshooting time and reducing risk for sensitive applications. It saves resources, and even helps a team sleep better at night knowing their baseline material won’t introduce headaches.
High-purity 2-Adamantane tends to be free from colored impurities or odorous residues that show up in lower grades. In my lab days, odorless, colorless materials told me we were off to a clean start. Downstream reactions pulled through with fewer purification steps. This gives you not just a product, but a smoother path to whatever innovation follows.
I’ve seen lists of specs with more lines than a phone book, but what matters most is what a model actually does on the bench. The 2-Adamantane in focus here is a powder or crystalline solid, packed to prevent moisture pickup. Each batch is checked to confirm consistent melting point and no visible contamination. As someone who’s spent hours poring over incoming QC data, I appreciate when the claims meet the eye-test—when you see a pure, snow-white powder pour easily and settle without clumping or discoloration.
The packaging fits professional settings. Bulk storage containers are designed to block air and humidity, which makes a real difference if you open them occasionally and want the rest of the supply to last. Each shipment comes with a Certificate of Analysis, backing the purity. For me, knowing that I could trace my results back to a clean batch number made investigations much smoother whenever something unexpected came up.
My experience with 2-Adamantane started in pharmaceutical research, but its reach goes far beyond that. This molecule’s sturdy skeleton lets chemists build complicated drug candidates from a stable foundation. Solvents, reagents, and even certain catalysts can all incorporate fragments of adamantane when durability is a priority. I saw colleagues use it to create antivirals, as the dense structure gives the right shape for drugs needing to interact tightly with their biological targets.
Material science teams have found a home for 2-Adamantane as well. Early in my career, I watched a group synthesize specialty polymers with improved thermal resistance, simply by introducing a bit of adamantane into the mix. The difference in heat stability became visible during quality testing; plastics that would otherwise sag under stress held their shape and integrity much longer. Most standard hydrocarbons don’t offer this edge.
Advanced electronics sometimes call for heat-resistant, insulating materials. My time supporting an electronics startup opened my eyes to just how many novel uses pop up once a building block like this gets noticed. They added 2-Adamantane derivatives to resins, creating housings that didn’t deform under fluctuating amperage and device heat. The reliability boost paid off fast in consumer safety tests. Seeing ideas jump from chemical theory to practical use changed the way I value specialty chemicals.
Before 2-Adamantane hit my radar, most hydrocarbon choices meant a tradeoff between affordability and performance. Compounds like cyclohexane or even decalin show up in many recipes, but their stability under challenging conditions leaves something to be desired. Cyclohexane liquids evaporate quickly, and solids can oxidize or break down under moderate heat.
2-Adamantane brings a different set of benefits. Its rigid structure, packed like a miniature geodesic dome, gives it a level of chemical resistance you won’t find with most alternatives. The absence of double bonds and the absence of weak points mean you can heat and process it with less worry about decomposition.
Cost once placed adamantane compounds out of reach for many users. Advanced synthesis routes have changed that. The price gap has closed over the past decade, putting high-purity 2-Adamantane in reach for both industrial and academic labs. While other hydrocarbons still work for low-stakes jobs, I’ve seen projects switch to adamantane derivatives once they’ve lost too many shipments or wasted too many hours troubleshooting issues tied to cheaper hydrocarbons.
Having worked with countless chemical shipments, I can say that shelf life and safety always matter more in the real world than on spec sheets. 2-Adamantane, being stable, doesn’t call for extreme storage conditions. Keep it dry, avoid contamination, and it proves reliable month after month.
Personal experience taught me that even sturdy compounds deserve some respect. Wear gloves, keep containers sealed, and never assume crystals are safe because they look clean. I still recall a colleague who dropped a beaker and learned the hard way that even the toughest powders scatter fast and can be hard to recover.
Disposal is simpler compared to many chemicals. 2-Adamantane doesn’t produce hazardous fumes under normal conditions, and most disposal teams will recognize it as a low-risk material, so long as it’s not contaminated with dangerous reagents.
Working across pharma, plastics, and applied research, I’ve seen the cost of compromised inputs. Downtime, failed experiments, and sometimes entire projects scrap out when a minor impurity goes unnoticed. Investing in a trusted material like 2-Adamantane at high purity means lowering the odds of expensive surprises. It brings peace of mind—a feeling that lets people focus on what they do best, whether that’s designing a new smartphone sensor or chasing breakthroughs in medicine.
I once watched as a research team traced the source of an unstable batch of experimental polymers. Days were lost to tracing contaminants in base materials. Eventually, they zeroed in on a low-purity hydrocarbon intermediate. Their next experiment ran with 2-Adamantane at 99.5%, and the difference stood out immediately. No unwanted breakdowns, fewer purification hassles, and a much smoother path to data that mattered.
Product origin and integrity have become non-negotiable. With supply chains growing more complex every year, I rely on vendors who can provide documentation and traceability for every lot. Consistent paperwork, properly documented batch numbers, and transparent supply chains make it easier to pass both internal audits and public scrutiny.
Using 2-Adamantane responsibly means building a culture of accountability. No short cuts, no working around safety data or regulatory compliance. The best labs keep careful logs and don’t skimp on staff training, even when dealing with a low-risk hydrocarbon. I’ve learned that a slipshod record often points to bigger problems down the road.
Transparency also matters for environmental stewardship. 2-Adamantane generates minimal waste, and the solid state means spills are easier to contain. Yet respecting the material at every handling stage protects both people and ecosystems. As someone who’s dealt with minor lab incidents, I appreciate systems that prioritize prevention over cleanup.
New discovery often happens on the shoulders of reliable starting materials. My best lab memories start with solid, trustworthy supplies—a factor that doesn’t always get enough credit in scientific papers. 2-Adamantane at high purity gives researchers the flexibility to explore new reactions, tinker with new applications, or test theoretical concepts in a safe, stable context.
I sat in on a design meeting where researchers debated which scaffold to use for a next-gen antiviral. The conversation circled back to adamantane’s geometry. Its rigidity enabled the type of predictability that complex molecular targets demanded. The team ended up pivoting a core project onto this foundation, saving months of development time and a bundle in wasted reagents.
Academic settings gain from these properties too. Students learning advanced organic chemistry can experiment without tripping over variable results from batch to batch. I’ve seen young chemists gain confidence from seeing textbook reactions work as expected; a reliable input material helps breed the type of repeatability science depends on.
Even a sturdy, pure chemical has room for improvement. The crystalline format can sometimes lead to static buildup or tricky weighing, especially scaled to industrial levels. In my own experience, this risk is small compared to the payoff in reliability, but it’s worth mentioning for teams not used to working with low-density powders.
Cost pressures persist, particularly for startups or teaching labs on tight budgets. While prices have dropped, 2-Adamantane still requires an investment. I’ve seen some groups cut corners by turning to older hydrocarbon stocks, only to deal with purity-related headaches later. I believe that as the synthesis and recovery become more streamlined, these costs will continue to fall, making high-quality materials accessible to a wider audience.
Supply consistency matters too. Disruptions—whether from logistical hiccups or market swings—can choke a project if not managed properly. I recommend partnering with trusted suppliers and always keeping a modest reserve. That lesson came from experience, after sweating through a week when a shipment got delayed and the planned timeline went out the window.
The push toward better specialty chemicals always revolves around making things purer, safer, and more dependable. 2-Adamantane at 99.5% purity answers these calls, but there’s room to keep pressing for user-friendly packaging and even greener production methods. From what I’ve seen, more manufacturers are shifting toward lower-impact synthesis routes, using milder reagents and cleaner solvents to produce adamantane derivatives. These moves cut waste and reduce the environmental burden—something I’ve come to value more over time.
Educational outreach plays a part. Many young scientists remain unaware of the benefits of adamantane-type structures versus older hydrocarbon options. Industry and academic partnerships can help share knowledge, making it easier for new users to see the potential that products like 2-Adamantane bring. I’ve mentored students through their first syntheses with adamantane compounds; watching their reactions when experiments perform better than expected proves the value of spreading practical insight.
On the supply chain side, digital inventory management tools can spotcoming shortages earlier and minimize last-minute panic buying. I’d be lying if I said I don’t miss the old paper logs, but there’s no substitute for software that can spot a dip in reserves ahead of schedule so the work doesn’t grind to a halt.
My career has taken me from small teaching labs to sprawling industrial setups. In every role, I’ve learned the same thing: the small choices—like where you source your base chemicals—shape the whole project. 2-Adamantane (99.5%) isn’t just another compound in a catalog; it’s a foundation stone for precision, safety, and creative exploration.
Its unique lattice gives researchers the freedom to test bold ideas without worrying the base will crumble under pressure. The high purity protects against mystery headaches and brings integrity to experiments, production runs, and innovations that might someday become the next big thing in health, tech, or industry.
As specialty chemistry marches forward, I see a place for ever-purer, more reliable building blocks. Products like 2-Adamantane show that technology and know-how can keep raising the bar—a lesson that every lab, no matter the size, can appreciate.
