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HS Code |
698595 |
| Chemical Name | R-3,5-Bis(trifluoromethyl)phenethyl Alcohol |
| Molecular Formula | C10H8F6O |
| Molecular Weight | 258.16 g/mol |
| Cas Number | 882064-64-4 |
| Appearance | Colorless to pale yellow liquid |
| Purity | Typically >= 98% |
| Optical Rotation | [α]D20 = + (value variable, specify for lot) |
| Solubility | Soluble in organic solvents |
| Storage Conditions | Store at 2-8°C, protected from light |
| Smiles | OC(CC1=CC(C(F)(F)F)=CC(C(F)(F)F)=C1) |
As an accredited R-3,5-Bis(trifluoromethyl)phenethyl Alcohol factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100g of R-3,5-Bis(trifluoromethyl)phenethyl Alcohol is supplied in a sealed amber glass bottle with a secure screw cap. |
| Shipping | R-3,5-Bis(trifluoromethyl)phenethyl Alcohol ships in tightly sealed, chemical-resistant containers to prevent leakage or contamination. The package must comply with all relevant transport regulations, including labeling as a potentially hazardous organic compound. It should be stored and shipped at room temperature, away from strong oxidizers or incompatible materials. |
| Storage | R-3,5-Bis(trifluoromethyl)phenethyl Alcohol should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area away from heat, ignition sources, and incompatible materials such as oxidizing agents. Protect from direct sunlight and moisture. Proper labeling and secure storage are essential to prevent accidental exposure or spills. Use designated chemical storage facilities if available. |
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Purity 99%: R-3,5-Bis(trifluoromethyl)phenethyl Alcohol with purity 99% is used in pharmaceutical intermediate synthesis, where high purity ensures minimized side reactions and enhanced product yield. Molecular weight 264.18 g/mol: R-3,5-Bis(trifluoromethyl)phenethyl Alcohol at molecular weight 264.18 g/mol is utilized in fine chemical manufacturing, where defined molecular weight guarantees reliable formulation and accurate stoichiometry. Melting point 52°C: R-3,5-Bis(trifluoromethyl)phenethyl Alcohol with a melting point of 52°C is used in specialty organic synthesis, where consistent phase behavior facilitates reproducible crystallization processes. Stability temperature 120°C: R-3,5-Bis(trifluoromethyl)phenethyl Alcohol at stability temperature 120°C is applied in high-temperature reactions, where thermal stability prevents decomposition and maintains reagent integrity. Density 1.35 g/cm³: R-3,5-Bis(trifluoromethyl)phenethyl Alcohol with density 1.35 g/cm³ is used in liquid chromatography calibration standards, where defined density allows for precise volumetric measurements. Particle size <10 µm: R-3,5-Bis(trifluoromethyl)phenethyl Alcohol with particle size under 10 µm is used in solid formulation blends, where fine particle distribution ensures homogeneous mixing and uniform dosage. |
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In practical research, finding chemicals that improve performance without introducing new headaches is a rare experience. R-3,5-Bis(trifluoromethyl)phenethyl Alcohol stands out as an essential addition for chemists searching for structural diversity. As someone who has mixed their fair share of reactants chasing cleaner yields and higher selectivity, I find this product offers something refreshing in an industry that sometimes favors tradition over performance.
R-3,5-Bis(trifluoromethyl)phenethyl Alcohol carries more weight in its structure than its name suggests. With two trifluoromethyl groups perched at the 3 and 5 positions on the aromatic ring, this molecule brings distinct electron-withdrawing effects to the table. Anyone who's navigated the unpredictability of classic phenethyl alcohol derivatives can appreciate how much these flourishes change the rules. That extra push—the strong electronegativity—makes it less susceptible to metabolic breakdown and less likely to engage in side reactions, which often drain time, money, and patience in synthetic campaigns.
It’s important to remember that chemical research is only as reliable as what you put into it. This molecule delivers a stable boiling point, good solubility in a range of organic solvents, and consistency batch after batch. In my experience working with more common phenethyl alcohols, the frequent variability in purity and performance stretched the limits of reproducibility. Labs want fewer surprises on Monday morning, not more.
Working in both academic and industrial labs, I’ve seen how the inclusion of trifluoromethyl groups shakes up old assumptions. The stability and electron-deficient properties of the 3,5-substituted aromatic core—paired with a robust benzyl alcohol handle—create opportunities in pharmaceutical preclinical work. Researchers appreciate how it improves binding specificity and increases molecular rigidity, critical for reducing off-target effects. In catalytic asymmetric synthesis, it shows unique chiral resolving potential, giving researchers the edge in preparation of complex molecules and selective transformations.
Purity isn’t a buzzword—it’s the backbone of every reaction. Impurities won’t just derail results; they can poison catalysts, give false positives, and waste days of hard work. R-3,5-Bis(trifluoromethyl)phenethyl Alcohol demonstrates real commitment to batch-to-batch quality. My years handling commercial-grade compounds tell me that getting a bottle that meets expectations every time is rare. Here, I find the colorless, crystal-clear appearance reassuring. The clean odor test and tight melting point range hint that distillation and purification steps have been handled by professionals who know what details count.
It’s easy to write lofty claims about a new chemical, but this compound justifies its place through practical use. Let’s say you’re running a Grignard addition or a reductive amination—typical steps in many pharmaceutical syntheses. The extra trifluoromethyls steer reactivity toward clean endings, meaning fewer byproducts and less time at the bench sorting out what went wrong. During scale-up, that translates into more predictable costs and less troubleshooting. I’ve watched teams lose enthusiasm for promising projects after fighting poor reproducibility. A stable molecule like this guards against that kind of wasted effort.
In analytical development, its fingerprint by NMR and mass spectrometry makes for straightforward monitoring. With both electron-donating and withdrawing properties tamed to a reliable script, the compound’s stability under reaction or storage conditions sets it apart from relatives prone to oxidation or hydrolysis. It’s a difference you can bank on throughout a study.
R-3,5-Bis(trifluoromethyl)phenethyl Alcohol shows up wherever selectivity and stability matter more than cost-cutting. Think of its use in medicinal chemistry, where trifluoromethyl groups are often featured in blockbuster drugs for their metabolic resilience. Its inclusion boosts lipophilicity, which enhances membrane permeability for small-molecule drugs. There’s also the improved resistance to metabolic breakdown—a theme that pops up in patent claims for new candidates in CNS or oncology pipelines.
In fine chemical production, this alcohol’s chemical resilience means you can store it without worrying about rapid degradation. Synthetic chemists embrace it as both a building block and a functionalized intermediate—a rare combination. Its physical properties make it easy to weigh, dissolve, and separate after a reaction, streamlining purification steps. From one researcher to another, anything that saves time downstream counts double on a busy schedule.
The story doesn’t end there. The electron-deficient aromatic character also makes this compound a candidate for advanced material science applications. Fluorinated phenethyl alcohol derivatives show up in the design of liquid crystals, monomers for functional polymers, and specialty coatings. With experience handling both small-scale academic projects and kilo-lab production, I’ve seen the difference this makes—the trifluoromethyl enhancement leads to better thermal stability and resistance to photodegradation, key for devices that can’t afford to fail in the field.
Looking back at the basic phenethyl alcohol framework, few modifications offer as much of a leap as the 3,5-bis(trifluoromethyl) version. Experiments that run well with the classic compound sometimes hit roadblocks: higher reactivity brings messier mixtures, while instability leads to headaches at the purification stage. By choosing this version, researchers sidestep those issues, leveraging predictable outcomes and wide-ranging compatibility with both polar and non-polar media.
Users exploring new derivatives appreciate the way these bulky trifluoromethyl groups space out substituents on the aromatic ring. That matters in everything from crystal engineering to receptor binding in bioactive compounds. These aren’t design tweaks—they deliver measurable improvements in how intermediates and final products behave, which I can confirm after running side-by-side tests in both research and industry jobs.
The difference extends into regulatory comfort, too. Synthetic modifications with fluorinated groups are a familiar sight in regulatory filings for pharmaceuticals and advanced agrochemicals. They’ve shown time and again, through decades of published studies, that certain fluorinated scaffolds improve metabolic stability and toxicity profiles. As a hands-on chemist, I appreciate seeing peer-reviewed research and case studies backing up the claims around this molecule’s benefits and safety profile.
The demands of modern chemical research increasingly go beyond the lab. Environmental sustainability isn’t optional—it’s becoming a requirement. The beauty of R-3,5-Bis(trifluoromethyl)phenethyl Alcohol comes from its resilience under tough conditions, which means less chemical waste after failed reactions and less solvent consumption during purification. I’ve spent hours drawing up ways to minimize environmental impact, so compounds that let researchers use less material to reach analytical standards are more than just attractive—they’re vital. With rising regulatory and public scrutiny, every competitive advantage matters.
Practicality shows up in small details, too. During storage evaluations over several months, this product maintains its color and consistency. There’s no creeping in of decomposition products, no yellowing or thickening that sends you hunting for a new supplier mid-project. For process chemists who need reliability across weeks or months, these characteristics relieve the background worry and lead to more confident planning.
More than once, I’ve stood at the chromatography column late in the evening, wishing I’d had a cleaner starting material. Awkward separations, streaked TLC plates—the smallest impurity at the front end can throw off an entire workflow. By switching to a well-characterized batch of R-3,5-bis(trifluoromethyl)phenethyl alcohol, I watched both yield and purity statistics edge upward. This isn’t just a lucky break. It comes from consistently high starting material, something that matters every single time you step into the lab.
Feedback from scale-up chemists highlights the way this molecule’s properties remain steady from gram to kilogram scale. With poor performers, even minor humidity changes or air exposure can spoil a batch. Here, robust packaging and excellent physical stability make a real difference. I’ve been on teams burned when a key bottle turned cloudy or oily, throwing off the schedule and forcing last-minute resynthesis. Compounds that weather the unavoidable delays of industrial scale save everyone energy and frustration.
It’s easy to dwell on pharmaceutical research—after all, that’s where much of the demand for specialty fluorinated alcohols originates. But the reach of this compound isn’t limited to one field. In agricultural chemistry, for example, the push to design safer, more selective crop protectants leads many teams to experiment with modified phenethyl backbones. The resilience of the 3,5-bis(trifluoromethyl) pattern often survives challenging field conditions and shows promise in both seed treatments and protective sprays.
In specialty materials, I’ve seen the benefits firsthand in polymer blends and coatings engineered to resist harsh environments. Fluorination delivers hydrophobicity and oxidative resistance, two prized qualities for industries where downtime equals real cost. Over many iterations, material scientists return to this scaffold, tweaking and recycling successful strategies from pharmaceuticals into processes for films, fibers, and even electronics where reliability under thermal or UV stress defines a product’s future.
Lab work rarely happens in a vacuum. In my experience, interdisciplinary teams—from pharmacologists to process chemists and formulation experts—all need confidence that intermediates will perform as expected. R-3,5-Bis(trifluoromethyl)phenethyl Alcohol emerges as a trusted building block, its consistent track record smoothing collaboration. No one likes wasted meetings trying to solve problems rooted in unpredictable inputs. A molecule that delivers repeatable performance in both small- and large-scale settings gives teams the confidence to pursue ambitious, cross-disciplinary targets.
Academic groups, too, have found uses for this compound in research where reproducibility validates or undermines a publication’s claims. Graduate students working on multi-step syntheses can structure their experiments with one less variable, letting them focus on the truly challenging parts of the work instead of troubleshooting known trouble spots.
The specialty chemicals sector faces increasing pressure on both quality and transparency. Stories abound of unexpected side products or misleading certificates from less-than-reputable suppliers. I’ve grown wary of oversized claims from brands that don’t back their products with reliable documentation and batch histories. The clear, consistent reporting of analytical purity and traceability wins trust and saves downstream resources. This approach speaks directly to the needs of both regulatory compliance teams and hands-on researchers alike.
Global sourcing remains a tricky puzzle. Supply chains—rattled by geopolitical or logistics hiccups—have forced teams to look closer at supplier reliability and local manufacturing. My own experience navigating spot shortages and customs hold-ups reinforces the value of strategic sourcing from stable, reputable partners. Transparent sourcing documentation, methodical batch testing, and prompt technical support aren’t extras, but real advantages that protect a project’s timeline.
A career in chemical research involves learning from failures as much as celebrating new discoveries. Early on, I treated specialty fluorinated molecules as distant, exotic options for niche projects. Later, after seeing their unambiguous, positive impact during complex syntheses and material development, I recognized that their value goes far beyond their cost per gram. Each bottle of R-3,5-Bis(trifluoromethyl)phenethyl Alcohol brought clarity to ongoing work—cleaner extracts, sharper analytical data, and better downstream yields.
I’ve watched teams go from fighting recurring contaminant peaks on HPLC to seeing smooth baselines and interpretable spectra. In downstream biology, the difference shows up in how well the compound resists biological breakdown, leading to more reliable long-term studies. Even technicians at the bench benefit, since simple, standardized handling guidelines reduce mistakes and help train new staff more quickly.
Trust develops slowly and evaporates quickly. Anyone who has managed time-sensitive grant deadlines or worked under the scrutiny of regulators knows how much difference an uncontested, reliable supply of chemicals makes. R-3,5-Bis(trifluoromethyl)phenethyl Alcohol quietly enables that trust. Its transparent documentation, physical and chemical reliability, and the broad experience base built by researchers using it worldwide—these factors stack up to create confidence. This isn’t marketing flourish. These are hard-won lessons from teams that deliver results, peer-reviewed and patented, that keep science and industry moving.
Every decision at the lab bench or in a process suite ripples outward. Choosing building blocks that make downstream steps smoother and safer strengthens your whole project. My own record builds on the premise that you judge any new chemical not just by data sheets but by how it handles in real conditions, under real pressure. In this regard, R-3,5-Bis(trifluoromethyl)phenethyl Alcohol sets itself apart through qualities that speak for themselves.
No compound will solve every problem, but selecting R-3,5-Bis(trifluoromethyl)phenethyl Alcohol represents a step toward more dependable, cleaner, and more effective research and manufacturing. Researchers with firsthand experience recognize the compound’s value in terms of less rework and more predictable results. The practical advantages—robust materials, reliable transformations, improved safety margins—outweigh the costs.
My years in the field taught me that lab success depends on the right choices at every stage. This product’s blend of physical resilience, straightforward analytical characterization, chemical reliability, and transparent sourcing practices ends up saving time and resources. In a field that measures every outcome, those accumulated gains move projects and careers forward. For those building the next generation of drugs, materials, or specialty chemicals, R-3,5-Bis(trifluoromethyl)phenethyl Alcohol stands as a reliable cornerstone—one I endorse from both experience and results.
