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HS Code |
674183 |
| Product Name | 2-Ethyl-2-Adamantanol |
| Purity | 99% |
| Chemical Formula | C12H20O |
| Molecular Weight | 180.29 g/mol |
| Cas Number | 768-95-6 |
| Appearance | White solid |
| Boiling Point | 285-287°C |
| Melting Point | 125-128°C |
| Density | 1.07 g/cm³ |
| Solubility | Insoluble in water; soluble in organic solvents |
| Storage Conditions | Store at room temperature, tightly closed |
| Synonyms | 2-Ethyladamantan-2-ol |
| Smiles | CC1(CC2CC3CC(C2)CC1C3)O |
| Inchi | InChI=1S/C12H20O/c1-2-12(13)7-9-3-4-10(12)8-11(5-9)6-11/h9-11,13H,2-8H2,1H3 |
As an accredited 2-Ethyl-2-Adamantanol (99%) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 2-Ethyl-2-Adamantanol (99%) is securely packaged in a 25g amber glass bottle with a screw cap and tamper-evident seal. |
| Container Loading (20′ FCL) | 20′ FCL container loads 2-Ethyl-2-Adamantanol (99%) in 25kg fiber drums, safely packed, ensuring secure chemical transportation and compliance. |
| Shipping | 2-Ethyl-2-Adamantanol (99%) is shipped in tightly sealed, chemical-resistant containers to ensure product integrity and prevent leaks. The packaging complies with international transport regulations. The product is shipped as a non-hazardous chemical under normal conditions, with clear labeling and documentation provided for safe handling and storage during transit. |
| Storage | 2-Ethyl-2-Adamantanol (99%) should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area away from direct sunlight, heat sources, and incompatible substances such as strong oxidizers. Keep the storage area free from moisture. Clearly label the container and ensure it is only accessible to trained personnel. Follow all relevant safety and regulatory guidelines. |
| Shelf Life | 2-Ethyl-2-Adamantanol (99%) typically has a shelf life of 2 years when stored in a cool, dry, and sealed container. |
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Purity 99%: 2-Ethyl-2-Adamantanol (99%) is used in pharmaceutical synthesis, where high purity ensures consistent active ingredient quality. Melting point 128–130°C: 2-Ethyl-2-Adamantanol (99%) is used in high-temperature resin formulation, where its defined melting point enhances thermal stability. Molecular weight 184.3 g/mol: 2-Ethyl-2-Adamantanol (99%) is used in specialty polymer manufacturing, where reliable molecular weight facilitates precise polymer chain control. Low moisture content <0.1%: 2-Ethyl-2-Adamantanol (99%) is used in moisture-sensitive catalyst preparation, where low water levels minimize unwanted hydrolysis. High chemical stability: 2-Ethyl-2-Adamantanol (99%) is used in advanced coating applications, where chemical stability extends coating lifespan. Viscosity 14 mPa·s at 25°C: 2-Ethyl-2-Adamantanol (99%) is used in lubricant additive development, where controlled viscosity ensures optimal flow properties. Stability temperature up to 180°C: 2-Ethyl-2-Adamantanol (99%) is used in thermoplastic compounding, where thermal stability maintains material performance during processing. Particle size <200 μm: 2-Ethyl-2-Adamantanol (99%) is used in composite material fabrication, where fine particle size enables uniform dispersion for improved mechanical properties. Assay by GC ≥99%: 2-Ethyl-2-Adamantanol (99%) is used in reference standard preparation, where accurate assay supports reliable analytical results. Refractive index 1.513 (20°C): 2-Ethyl-2-Adamantanol (99%) is used in optical polymer research, where a specific refractive index contributes to desired light transmission properties. |
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Inside our chemical plant, 2-Ethyl-2-Adamantanol has carved out a valued spot in specialty synthesis. Years ago, we saw a growing need for advanced adamantane derivatives, especially those tailored for pharmaceutical intermediates and advanced material research. With its white, crystalline appearance and high purity—our in-house processes deliver a minimum of 99%—this compound stands out for demanding applications.
Chemists use 2-Ethyl-2-Adamantanol as both a building block and a performance enhancer. Its key feature lies in the adamantane cage, which provides both rigidity and thermal stability to molecular structures. The secondary alcohol group adds an accessible functional handle, crucial in the construction of more complex organics. In our years of hands-on processing, even minor shifts in synthesis parameters show up in product crystallinity and overall purity, so our team monitors every batch with a suite of analytical tools: NMR, HPLC, and GC-MS.
Across multiple industries, whether the end use is an intermediate for antiviral agents, a stabilizer in photochemistry, or a high-value specialty resin, purity becomes more than a numbers game. A 99% pure 2-Ethyl-2-Adamantanol translates to less time spent tracking down stubborn side reactions or unexplained impurities downstream. Our quality control team sees the consequences of minor contaminants: loss of yield, unplanned plant shutdowns, and wasted reagents in scale-up projects.
Each production run starts from carefully screened raw materials. Our batch reactors offer precise temperature and pressure control, so we can maintain close tolerances and keep byproducts to a minimum. Consistency matters. Customers talk about the frustration of working with inconsistent materials. After switching to our product, they describe smoother downstream conversions and cleaner analytical spectra.
Synthesis of complex molecules often relies on the unique steric bulk and rigidity the adamantane core provides. We've seen researchers in medicinal chemistry exploit this characteristic to increase the metabolic stability of drug candidates. In electronic materials development, the adamantyl group acts as a non-aromatic, non-planar scaffold when designing advanced organic light-emitting diodes (OLEDs) and photoresists.
Our plant’s batch-to-batch dependability makes it easier for R&D teams to trace observed effects back to their processes, rather than question each new lot of starting materials.
Colleagues in academic and industrial labs point to the importance of alcohol functional groups as tuning points for further modification. Our product’s 2-ethyl substituent brings a specific balance: steric protection from unwanted rearrangements, good solubility in a range of organic media, and a pathway to unique derivatives via standard transformations. This includes oxidation to the corresponding ketone, conversion to halides, or esterification, all steps supported by published literature and our own technical feedback.
Within the family of adamantanol compounds, subtle differences lead to pronounced effects in chemical behavior. Ordinary adamantanol lacks the ethyl substitution, making it less sterically hindered. Our team has compared reactivity in model reactions and finds that 2-ethyl substitution often reduces side-chain migration and self-condensation, making it more tractable for precise synthesis. We also benchmark against isomers, such as 1-adamantanol, observing shifts in boiling point, melting range, and solubility profiles. These differences ripple into process design decisions, influencing solvent selection and purification.
Electronics developers evaluating material stability under high current density conditions have returned to adamantane systems, attracted by their resistance to photodegradation. Among samples we prepare, 2-Ethyl-2-Adamantanol consistently resists discoloration under both visible and UV exposure, a quality that generic alcohols and partially purified analogs often lack. Our own stress testing shows reliable thermal performance, a must for downstream partners in electronics and specialty coatings.
Inside our facility, 2-Ethyl-2-Adamantanol starts as a carefully controlled reaction sequence, including precise hydrogenation and alkylation steps. Operators monitor temperature excursions tightly to avoid overalkylation or incomplete conversions. Handling the crystallization stage requires attention to temperature and solvent evaporation rates: uneven cooling produces larger particles, while rapid quenching yields finer grains favored in some formulation pathways.
On the customer side, handling resembles other solid alcohols but with a few tricks picked up over decades. It's best stored tightly sealed, in a cool, dry place—moist air tends to promote clumping after repeated opening, though the actual molecule remains stable. When compounding or formulating, gradual addition under agitation limits static buildup and lumps, based on both internal trials and user feedback. Solubility matches most nonpolar and low-polarity solvents, expanding possibilities for formulation without resorting to aggressive or specialty reagents.
We often receive questions from process chemists about our scale-up experience. Several customers started with gram-scale bench trials, worried about whether properties shift at the multi-kilogram scale. Our own pilot plant trials, up to 100 kg per batch, show unchanged melting point, purity, and UV-Vis absorption, which reassures researchers developing longer reaction sequences. It's worth noting that consistent impurity profiles have a direct impact on the reproducibility of synthetic protocols—something we monitor with every lot release.
For material scientists, our samples offer solid acid and thermal stability, which opens up applications in harsh environments like photolithography and battery research. Unlike less substituted adamantanols, the 2-ethyl group helps suppress undesired crosslinking in certain polymerization regimes, according to data from joint testing with downstream users. Our familiarity with customer needs shortens development cycles, and we welcome technical feedback as partners tune reaction parameters or explore new catalyst systems.
Sometimes researchers approach us with specific challenges, such as batch-to-batch variability in competing products or noncompliance with regulatory purity standards. We’ve tailored our QA processes to catch problems before shipping. For example, we introduced extra filtration and an enhanced recrystallization step, which reduced trace chlorine impurities to non-detectable levels. That adjustment prevented failed batch releases at a partner pharma group.
Maintaining transparency about analytical results matters: each cert has a breakdown of purity, major residual solvents, and is updated continuously, not just annually. In our opinion, hiding behind vague product datasheets does neither us nor our clients any favors.
Surges in research demand for adamantane derivatives sometimes bottleneck at the supply level. During a recent surge from new antiviral research, we leaned on our network of raw suppliers to smooth out supply chain kinks. Rather than stretch available inventories thin, we prioritized communication with major regular customers while investing in expanded reactor volume. The end result prevented major project delays not just for internal operations, but for ongoing pharmaceutical trials depending on uninterrupted supply.
Over the years, we’ve upgraded our solvent recovery and air abatement systems, minimizing emissions during large-scale synthesis. The adamantane core shows low vapor pressure and limited toxicity, which simplifies containment needs compared to more volatile building blocks. Waste streams mostly consist of standard organics, handled with our local incinerator partner. Our technicians participate in ongoing safety and toxicology forums—a lesson from a minor 2014 incident, after which PPE standards were raised and response drills increased.
We work directly with regulatory consultants to ensure that every new processing tweak aligns with both domestic and international environmental requirements. Our compliance record draws from monthly process audits and real-time monitoring. These details aren’t just paperwork to us; they reflect our commitment to long-term partnerships and future-proofing new materials.
Many inquiries come not from procurement offices, but directly from the researchers running reactions at the bench or at pilot scale. They want to know what happens if storage stretches beyond a year, if color changes signal real impurity buildup, or whether trace solvents detectable by NMR are ones we control or ones picked up from lab air. In response, we provide open access to technical contacts inside our quality lab, making sure questions don’t disappear into a website black hole.
Sometimes developers want modifications—pre-ground material, specific drying levels, or custom packaging. We handle these requests on a case-by-case basis after direct conversations. Several advanced research programs have relied on our flexibility in small-batch runs, as university budgets or grant timelines shift project scope. These adaptations keep both science and production moving at a practical pace, rather than forcing researchers to pause for vendor bureaucracy.
R&D teams on our side invest in process improvements nearly every quarter. Not long ago, we shifted from a traditional filtration and drying setup to a more advanced vacuum-assisted inline dryer. This not only improved recovery rates but also produced more uniformly-sized crystals—feedback from a customer’s formulation group hinted at improved dispersion during their compounding process. Continual feedback channels matter, so we encourage customers to share unexpected results, whether positive or negative.
Each batch’s data gets logged and cross-referenced; patterns that emerge—such as small changes in solubility profiles—get evaluated for impact on customer operations. In one instance, a subtle pH shift at the drying stage prompted a small change in washing solvents, which eliminated haze in a downstream developer solution. These lessons often lead to process tweaks, but only after hands-on trials and collaborative troubleshooting.
We receive samples from upstream and downstream users for head-to-head comparison. Our quality team routinely evaluates shorter- and longer-chain adamantanols, examining key aspects including melting range, color stability, and reactivity in standard nucleophilic substitution. Products blended with less pure analogs tend to absorb more moisture and show more yellowing after a few days' light exposure; our 2-Ethyl-2-Adamantanol maintains its bright appearance and ease of weighing—even after multiple transfers.
We also discuss critical application differences. Customers report that our product, compared to standard adamantanol, achieves higher product recovery rates in oxidation and acylation reactions. The 2-ethyl group, absent in more basic structures, makes certain rearrangements less likely and eases purification in subsequent steps—a practical insight borne out by test reaction data. Some specialty resin makers favor it for stable crosslinking with improved clarity, reporting fewer cases of cracking or brittleness in finished products.
In recent years, research partners have requested more thorough documentation, including impurity spectra and trace element analysis. Our transparency policy comes straight from lessons learned on the plant floor: routine surprises from uncontrolled batches cost everyone more than proactive communication. We share not only certificates but also insights from ongoing joint developmental work—a direct response to requests for real-time troubleshooting and best practices.
The drive to improve product purity, consistency, and user experience follows naturally from these conversations. Technical staff participate in webinars and local chemistry group meetings, both to learn the latest application requirements and to share practical tips picked up during large-scale production—such as best ways to dry, dissolve, and filter the product in real-world trials.
Tech advances in pharma, electronics, and new material synthesis explain surging interest in adamantane derivatives. What emerges from regular customer and internal lab discussions is the need for advanced intermediates that perform reliably without unpredictable shifts from lot to lot. Our operational focus rests on supporting new compound design, where clean structures and minimized side reactions matter more than ever.
By keeping our production process responsive, our technical support open, and our commitment to improvement active, we hope to provide not just a product, but a springboard for progress—whether at an industrial pilot plant or a university research bench. In this sense, the role of 2-Ethyl-2-Adamantanol extends well beyond the drums that leave our facility.
