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HS Code |
519223 |
| Product Name | p-tert-Butyl-2-(α-Methylbenzyl)Phenol |
| Synonyms | 4-tert-Butyl-2-(1-phenylethyl)phenol |
| Chemical Formula | C17H20O |
| Molecular Weight | 240.34 g/mol |
| Purity | ≥99% |
| Appearance | White to off-white solid |
| Melting Point | 78-80°C |
| Boiling Point | Unknown |
| Solubility | Slightly soluble in water; soluble in organic solvents |
| Cas Number | 116432-16-1 |
| Storage Temperature | Store at 2-8°C |
| Smiles | CC(C1=CC=C(C=C1)C2=CC=C(C=C2)C(C)(C)C)C |
| Inchi | InChI=1S/C17H20O/c1-12(14-7-4-3-5-8-14)15-10-11-16(13(18)9-15)17(2,3)4/h3-12,18H,1-2H3 |
As an accredited p-tert-Butyl-2-(α-Methylbenzyl)Phenol (≥99%) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle containing 25 grams, sealed with a screw cap, labeled with chemical details, purity (≥99%), and safety information. |
| Shipping | **Shipping Description:** p-tert-Butyl-2-(α-Methylbenzyl)Phenol (≥99%) is shipped in sealed, chemical-resistant containers to prevent contamination or moisture absorption. Package labeling complies with safety and regulatory guidelines. Transport is conducted via ground or air, depending on destination, ensuring compliance with local, state, and international chemical shipping regulations. |
| Storage | **Storage for p-tert-Butyl-2-(α-Methylbenzyl)Phenol (≥99%)**: Store in a tightly closed container, in a cool, dry, and well-ventilated area, away from direct sunlight and incompatible substances such as strong oxidizers. Maintain storage at ambient temperature and protect from moisture and heat. Label the container clearly and follow all relevant safety guidelines and regulations for storage of organic chemicals. |
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Purity: p-tert-Butyl-2-(α-Methylbenzyl)Phenol (≥99% purity) is used in pharmaceutical intermediate synthesis, where high purity ensures minimal impurities and consistent yield. Melting Point: p-tert-Butyl-2-(α-Methylbenzyl)Phenol (melting point 72–74°C) is used in organic synthesis, where a defined melting range facilitates accurate formulation and crystallization control. Chemical Stability: p-tert-Butyl-2-(α-Methylbenzyl)Phenol (chemically stable up to 120°C) is used in antioxidant additive manufacturing, where temperature stability prevents degradation during processing. Molecular Weight: p-tert-Butyl-2-(α-Methylbenzyl)Phenol (molecular weight 256.36 g/mol) is used in resin formulation, where precise molecular weight contributes to predictable polymer properties. Solubility: p-tert-Butyl-2-(α-Methylbenzyl)Phenol (soluble in organic solvents) is used in specialty coatings, where solubility enhances uniform dispersion and surface performance. Assay: p-tert-Butyl-2-(α-Methylbenzyl)Phenol (assay ≥99%) is used in fine chemical production, where high assay values guarantee product consistency and batch reproducibility. |
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For chemists and industry professionals searching for a consistent, high-quality phenolic compound, p-tert-Butyl-2-(α-Methylbenzyl)Phenol with a purity level of 99% or higher provides significant advantages. Academic research, materials science, agrochemicals, and advanced synthesis processes often rely on stable, well-defined reagents. I’ve learned in the lab and in industrial scenarios that high-purity starting materials set the stage for predictable results, and any deviation in composition usually results in headaches down the line. This compound, offered at no less than 99% purity, reflects rigorous handling and advanced purification, and it’s easy to appreciate the value of such technical care.
A quick glance at this molecule’s structure—tert-butyl and α-methylbenzyl substitutions on the phenol ring—signals specialized reactivity. Many phenols with similar cores serve as antioxidants or stabilizers in materials science. Others pop up as intermediates in pharmaceutical synthesis. Low-level impurities, like trace water or unknown organics, can seriously compromise the stability of a final polymer or the yield of a synthetic route. From my own experience, using lower-purity phenols often means confronting side reactions, color changes, or inconsistent analytical results. With ≥99% purity, those “mystery variables” get slashed, giving more repeatability and reliability.
Lab-scale testing often starts with modest sample sizes, while pilot operations may jump to multi-kilo quantities. The best suppliers deliver this phenol in solid crystalline form, tightly packaged to avoid moisture and oxidation. Crystalline solids store more efficiently and their melting points can help verify purity. Users like myself run melting point checks and thin-layer chromatography to spot outliers—when the batch records show ≥99% purity, the melting range typically comes sharp and matches reference values.
The value of p-tert-Butyl-2-(α-Methylbenzyl)Phenol stretches into several advanced domains. In polymer chemistry, phenolic compounds like this one can act as efficient chain terminators or antioxidants. The bulky, hydrophobic tert-butyl group and the α-methylbenzyl substitution both impact sterics and electronics. Such properties mean better radical-capturing behavior and enhanced material performance, especially in high-heat or demanding environments.
Research teams use this compound as a specialty reagent for synthesizing complex molecules. In medicinal chemistry, phenols sometimes serve as core fragments for larger, biologically active structures—antibacterials, multi-target ligands, or modulators of protein activity. Incorporating a tert-butyl group can boost lipophilicity and, in the right context, enhance membrane permeability or metabolic stability. The unique structure here means it can allow scientists to build new analogues or probe structure-activity relationships efficiently, without noise from contaminants.
Some agrochemical projects use substituted phenols to design herbicides or plant growth regulators. Modern agricultural chemistry leans on customization, and compounds like p-tert-Butyl-2-(α-Methylbenzyl)Phenol provide a launching point for such innovation. Only high-purity materials ensure that experimental results reflect the real capability of the core molecule, not accidental by-products or unwanted side reactions.
Several features distinguish this molecule from everyday phenols found in catalogues. Start with the combination of two bulky substituents: tert-butyl groups produce considerable steric hindrance, and the α-methylbenzyl moiety contributes both electronic and spatial effects. Standard alkylated phenols might show some antioxidant properties, but this precise structural configuration lends greater thermal stability, oxidation resistance, and unique solubility characteristics.
Solubility profiles change with every structural tweak. Here, increased hydrophobic surface area encourages dissolution in organic solvents—a noteworthy advantage in non-polar polymer matrices or synthetic transformations. Basic phenol or even simple tert-butyl-substituted phenol lack this degree of tunability. Not only does this improve compatibility in formulations, it widens the scope for process engineers and synthetic chemists hoping to push boundaries, especially under unusual conditions.
Some users focus on the molecule’s performance under stress. For example, high-purity p-tert-Butyl-2-(α-Methylbenzyl)Phenol resists color changes over time, a crucial need for transparent or light-colored resins. I’ve come across issues—coatings yellowing or embrittling months after production—traceable to minor impurities in the stabilizer package. By subbing in this high-purity product, such issues often fade away, prolonging shelf life and saving costs.
Price-conscious buyers sometimes reach for technical-grade substitutes to manage costs. Short-term savings, in my experience, come unravelled in product recalls, failed assays or customer complaints when unexpected impurity profiles show up. In small-molecule synthesis, a fraction of a percentage point of impurity can poison a catalyst or create inseparable by-products that slow down progress for weeks.
One specific challenge: downstream analytical testing. Analytical chemists often detect persistent, unexplained peaks using gas chromatography or HPLC. Tracking these down often points right back to “good enough” raw materials. Over the years, I’ve learned that running thin-margin projects with anything but ≥99% pure compounds almost always invites uncertainty. High-purity p-tert-Butyl-2-(α-Methylbenzyl)Phenol helps sidestep this problem, making analytical sign-off far more straightforward.
Another practical perk: high-purity material comes with predictable physical properties. Melting point drift, sticky solids, or sudden precipitation during dissolution signals lurking impurities. My early experiences taught me how much time is lost cleaning glassware fouled by unintended residues. Superior sample quality leads to easier weighing, cleaner transfers, and reliable solubility—making both small and large-scale workdays more productive.
High-purity phenols resist environmental degradation, so the shelf life extends and storage headaches drop off. Keeping products tightly sealed and out of direct sunlight usually does the trick, but starting with a robust material lets teams worry less about batch-to-batch drift. This turns out to be more important than it seems, especially once larger operations start using the same lot number months or years after original purchase.
Downstream regulations—be they in pharmaceuticals, plastics or food contact applications—grow tighter every year. Documented purity offers clear benefits when submitting dossiers to regulatory agencies or passing customer audits. Quality control managers look for consistent, traceable material sources. In several firms I’ve worked alongside, a single documented deviation in input purity can trigger a chain reaction: quarantined goods, new round-robin testing, or even process rewrites. Opting for higher-purity phenols smooths quality assurance cycles and wins trust from both customers and regulators.
Across many industries, traceability goes hand in hand with purity. Detailed COAs (Certificates of Analysis) should accompany each batch, listing water content, residual solvents, and any identified by-products. Trust in supplier honesty and laboratory rigor needs to be earned; I watch for suppliers who tie their claims to real data. The difference between 97% and 99% purity sometimes seems modest, but the fate of a batch can hinge on those two percent.
Some customers wonder if high-purity phenols justify the investment. My answer: plan for your end use. Quality at the front end prevents expensive corrective actions later. Systematic analysis of process bottlenecks often yields one culprit—raw material quality. If troubleshooting reveals stability or yield issues, upgrading to a product like p-tert-Butyl-2-(α-Methylbenzyl)Phenol (≥99%) may clear away several obstacles in a single move.
For organizations sensitive to cost, pooling purchases across departments sometimes unlocks higher tier pricing and steadier supply contracts. Scientists, engineers and procurement teams benefit by building direct relationships with established suppliers. In some roles, I’ve worked alongside teams that shared real-time feedback with suppliers on product form, packaging, and delivery. Feedback loops ensure problems—be it caking, contamination or labeling—don’t become recurring headaches.
Supply chain disruptions, from geopolitical issues to natural disasters, often limit specialty chemical access. Building trust with reliable sources of high-purity phenols pays off, especially when alternatives go into short supply. Experienced buyers collect reference samples, validate lots through rigorous QC, and keep secondary suppliers vetted and on file. Good recordkeeping and communication sets the groundwork for resilience across shifting market conditions.
Consistently achieving ≥99% purity at scale isn’t trivial. It calls for advanced distillation or crystallization, careful solvent selection, and comprehensive batch analytics. Not every vendor invests in such equipment or process control. A few suppliers focus on volume and cut corners, assuming buyers can tolerate the difference. From hands-on work, I’ve come to appreciate the diligence behind a sharp, uncontaminated batch—it's the difference between smooth running lines and frustrating downtime.
Watertight packaging and clear batch coding channel confidence from the factory floor to the lab bench. I prefer suppliers that provide access to their technical support teams rather than just sales reps; direct answers to handling, solubilization, or downstream reactivity questions flow best from chemists, not marketers. This interplay of support, transparency and product integrity keeps projects moving and helps unlock new applications for role-specific needs.
As specialty and fine chemistry marches forward, the toolbox of available building blocks rapidly expands. Having access to unique phenol derivatives—especially those with defined purity and consistently high batch quality—makes previously complex syntheses simpler. In my work with start-ups and research groups, access to rare chemicals enabled creative routes and fast-tracked intellectual property generation. Researchers target pathways previously off-limits, thanks to difficult-to-source intermediates that now offer both reactivity and reliability.
Manufacturers aiming for next-gen coatings, adhesives, or resins already search for improvements in UV stability, color retention, and long-term mechanical properties. The properties of p-tert-Butyl-2-(α-Methylbenzyl)Phenol—bulky groups, tuned solubility, strong resistance to oxidative stress—meet those demands in a way that base phenol cannot. When legacy stabilizers falter, specialty molecules like this one redefine performance benchmarks and support new rounds of material certification.
Responsible procurement and use of high-purity specialty chemicals mean more than just checking a box. Environmental regulations in major markets, including the EU and US, now scrutinize manufacturing by-products and lifecycle impacts. Reliable documentation and transparent supply chains simplify environmental reporting and future-proof business practices. Top-tier phenols, with their detailed QC profiles and lot-level traceability, line up with these evolving expectations.
Smart organizations keep a long view—choosing products with tight specifications and working cooperatively with their upstream partners. Teams benefit from standard operating procedures for sampling, handling and storing specialty chemicals. Regular refresher training for technical staff on best practices can help sustain the benefits of high-purity materials, keeping processes robust and repeatable over the years.
Across the chemical value chain, from research benches to production floors, the shift toward higher-specification inputs represents a recognition of what experience and data show: reliable outputs start with uncompromised raw materials. Whether driving innovation or stabilizing operations, p-tert-Butyl-2-(α-Methylbenzyl)Phenol (≥99%) stands ready as a valuable anchor in the toolkit of chemists, product developers, and quality managers alike.
