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HS Code |
586897 |
| Iupac Name | 4-Hydroxybenzaldehyde |
| Molecular Formula | C7H6O2 |
| Molar Mass | 122.12 g/mol |
| Cas Number | 123-08-0 |
| Appearance | White to pale yellow crystalline powder |
| Melting Point | 112–115 °C |
| Boiling Point | 315 °C |
| Solubility In Water | Slightly soluble |
| Density | 1.226 g/cm³ |
| Smiles | C1=CC(=CC=C1C=O)O |
| Pka | 7.61 |
| Refractive Index | 1.626 |
As an accredited P-Hydroxybenzaldehyde factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 250g P-Hydroxybenzaldehyde comes in a sealed, amber glass bottle with a secure screw cap, labeled with safety and product information. |
| Shipping | P-Hydroxybenzaldehyde is shipped in tightly sealed containers, typically made of glass or high-density polyethylene, to prevent contamination and moisture absorption. It should be transported in accordance with local and international chemical handling regulations, kept away from incompatible substances, and stored in a cool, dry, well-ventilated area during transit. |
| Storage | P-Hydroxybenzaldehyde should be stored in a cool, dry, and well-ventilated area, away from sources of ignition and incompatible substances such as strong oxidizing agents. Keep the container tightly closed to prevent moisture absorption and contamination. Store in a tightly sealed container, clearly labeled, and protect from light. Follow all relevant safety guidelines and local regulations for chemical storage. |
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Purity 99%: P-Hydroxybenzaldehyde with purity 99% is used in pharmaceutical intermediate synthesis, where it ensures high yield and low impurity content in end products. Melting Point 116°C: P-Hydroxybenzaldehyde with a melting point of 116°C is used in fine chemical manufacturing, where it provides uniformity and reproducibility in solid-state reactions. Particle Size <50 μm: P-Hydroxybenzaldehyde with particle size less than 50 μm is used in dye formulation processes, where it enhances solubility and dissolution rate. Stability Temperature 80°C: P-Hydroxybenzaldehyde with stability temperature of 80°C is used in food flavor preparations, where it maintains chemical integrity during heating. Moisture Content <0.2%: P-Hydroxybenzaldehyde with moisture content below 0.2% is used in agrochemical synthesis, where it prevents hydrolytic degradation during storage. Bulk Density 0.7 g/cm³: P-Hydroxybenzaldehyde with bulk density of 0.7 g/cm³ is used in resin production, where it allows precise dosing and consistent batch processing. |
Competitive P-Hydroxybenzaldehyde 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.
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Tel: +8615365186327
Email: sales3@ascent-chem.com
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Meaningful chemical production always begins with a solid foundation of raw materials. Every day, we handle compounds that fuel innovation and industry, often invisible outside the lab or factory. P-Hydroxybenzaldehyde fits this role perfectly. As specialists who have spent years working at scale, we understand how vital its quality and consistency are to processes that reach from fine chemicals to large-scale manufacturing. This isn’t just a catalog listing—our experience with its purification, packing, and transition into customer hands informs every kilogram produced in our facilities.
Our P-Hydroxybenzaldehyde carries the model name PHB-99, a label rooted in our target for a minimum purity of 99%. Reaching this isn’t a matter of luck. From the moment raw phenol intermediates enter our reactors, people in our plants monitor reaction parameters, handle distillation, and analyze samples. Chemists draw on hundreds of pilot runs and production data to pin down the best route for a consistent, off-white to pale yellow crystalline solid. Moisture, ash, and residual solvents each get attention by a trained eye and sensitive instrumentation. We avoid the additives and extenders that creep into low-grade supplies, sticking to the purity that downstream syntheses demand. The melting point regularly tests at 114 to 116°C, which acts as the litmus for any off-spec batch. Laboratories and shops have no time to waste reworking material. That’s why we flow our experience into making sure each drum reliably delivers the product as expected.
A decade ago, many plants—our own included—wrestled with contamination issues and color variables that made QA hazardous. Close work with analytical teams steered us toward tighter raw input controls, water purification, and better column designs. Each step hardened the product’s profile and reduced batch-to-batch drift. End users in our supply chain, whether they run small glassware or kilo-scale reactors, depend on that accuracy. It’s satisfying to know they don’t lose time chasing impurities because our process, pH monitoring, and filtration manage that trouble up front.
People use P-Hydroxybenzaldehyde for a reason. On manufacturing floors and in R&D centers, this molecule builds bridges to several value-added chemicals. We’ve watched as pharmaceutical firms transform it into intermediates, chasing particular aromatic compounds. It serves as the backbone for synthesizing vanillin, a popular and familiar aroma. In resin production, it acts as a crucial building block for specialty plastics. Dye makers use it to create vivid, stable colorants. Our largest batches leave the plant destined for these sectors. Solid relationships develop over years with buyers who identify their end formulas by the clarity and purity of our material. It isn’t one-size-fits-all. Every visit to a dye house or pharma lab brings new queries about how our production tweaks could serve a more demanding synthesis or reduce waste. Our commitment tracks with theirs, aligning raw material quality to enhance overall outcomes downstream.
On the agricultural front, organic chemistry continues to drive the search for greener pesticides and growth regulators. Our P-Hydroxybenzaldehyde provides a scaffold for these molecules. Spray drift, degradation rates, and application timing in field trials hinge on consistent input purity. With transparency about our process, we offer assurance that every drum supports these objectives. In the fragrance sector, subtle shifts in impurity profiles can noticeably affect organoleptic tests. Over the past eight years, close discussions with perfumers and formulators have underscored just how crucial clean starting material is when targeting a signature note or a specialized additive. Years of feedback and joint troubleshooting have refined our approach, reducing risk for end users and enhancing the ability to meet delicate performance specifications. Every application hands us a new lesson, and every lesson reshapes the way we manufacture and test our product.
Looking at the broader market, not all P-Hydroxybenzaldehyde performs equally. Experience tells us that minute changes in feedstock or plant operating conditions can affect yield, impurity profile, color, and downstream reactivity. We face a constant challenge to balance efficiency, purity, and cost while responding to seasonal and global raw material shifts. Interacting with customers who have trialed off-brand or so-called “commodity” material, the stories are similar—unexpected residue buildup, off-spec melting points, or complaints from their own QA departments. Standard practice in some regions includes higher levels of byproducts, especially p-hydroxybenzoic acid or phenolic contaminants, sneaking past basic inspection. These byproducts might go undetected until they gum up a sensitive catalyst or tint a colorant batch.
Our approach uses in-process controls and batch records so that every shipment tracks back to specific reactor parameters and raw input sources. Spectral data for every lot gets archived and referenced by our QA staff. This practice helped identify trends and correct a filtration stage that, years ago, was raising trace contaminant levels, even though end-point analysis had looked fine. We built a troubleshooting culture, so line operators know what signals require escalation. Over time, these habits differentiate the product—customers tell us their reactions run cleaner, and purification steps downstream become more straightforward.
Another major difference reflects our packaging and logistics. Moisture ingress or exposure to heat can make this product clump, degrade, or alter appearance. Storage in sealed, moisture-resistant containers, loaded and checked by people who understand the chemistry, prevents unnecessary risk. Years of talking with our partners revealed that careful labeling, contamination checks, and clear shipping documentation can save hours at the receiving dock and avoid production line disruptions. Scrutinizing feedback made a clear path to develop these improvements. They might look simple, but they reflect extensive ground-level work between people who use this product every day and those who make it.
Long-term viability for any chemical operation requires a laser focus on handling waste, maximizing atom efficiency, and reducing emissions. Plant operators, researchers, and technicians all play a part in this process. During the early 2010s, increasingly strict local regulations required us to rethink our waste management and solvent recovery. Upgrades to our distillation columns increased recovery rates and cut solvent discharge by 40%. Close integration with our wastewater treatment partners, paired with real-time analytics, guards local water quality and ensures confidence from our community as well as our customers.
Our people share stories of tough audits and spot checks designed to keep everyone honest. The result is an operation that prioritizes recycling and strict separation of waste streams. The goal is to ensure each kilogram of P-Hydroxybenzaldehyde withstands scrutiny from both regulators and responsible manufacturers. Safety protocols in our plant extend from the factory gate to the shipping dock. On-the-ground knowledge, built over years of steady production, guides each update to training and incident prevention strategies. A factory team that communicates confidently about spills, personal protective equipment, and emergency plans ends up making a better, more reliable product.
Over the years, shifts in end-user requirements have kept our feet to the fire. A dye manufacturer pushes for even higher chromatic purity, a pharma startup asks for specialized trace impurity analysis, or a food additive company requests documentation for every lot. These requests don’t disappear into a black hole—our laboratory and engineering staff engage directly with our partners, start conversations, and bring what they learn back to the factory floor. Upgrades to batch analytics, operator dashboards, and automated record-keeping come from real-world feedback. We welcome pilot trials or sample requests because they push us to validate every process change in the market’s reality rather than theory.
When production plants run into crunchy supply chains, everyone gets a lesson in what flexibility and responsible stocking mean. During times of raw material shortages, some competitors water down standards just to keep outputs flowing. We have always found it’s wiser to communicate delays than to risk shipping substandard goods. Many buyers have stuck with us after seeing this transparency in action. That trust cuts both ways, feeding into our willingness to invest in better lab equipment, safer packaging options, or greener processing routes.
For those who depend on P-Hydroxybenzaldehyde as a key ingredient, the difference between success and failure in the lab or on the manufacturing line isn’t explained by paperwork or glossy presentations. It’s built on hundreds of routine actions, good science, and ongoing relationships nurtured by honest feedback. Every step, from reaction setup to packing, supervision, and delivery, links the experience and discipline of our team to the reliability of the product in the world beyond our factory doors. Years spent answering technical questions, tweaking process steps, and troubleshooting real-world challenges set our P-Hydroxybenzaldehyde apart from generic alternatives.
We have seen this compound steer the development of better pharmaceuticals, sharper dyes, more resilient polymers, and subtle flavors. Listening to those on the front lines—process chemists, production leads, and R&D pioneers—lights the way for every product improvement. Whether users encounter our product as a raw material or a finished ingredient in their daily work, they engage with a continuity of quality that draws on a generation of chemical manufacturing knowledge. Reliable chemistry doesn’t live in the abstract—it exists in consistent batches, candid conversations, and the day-to-day dedication of people who care about what leaves their plant as much as those who rely on what arrives at theirs.
Manufacturing has taught us that a textbook ideal rarely survives contact with real-world supply chains, seasonal shifts, and regulatory pressure. A rainy season in our feedstock region raises water content in early intermediates—so we adjust that year’s drying regime and instrument calibration. Trading houses shift allocation priorities, and we revisit contracts with trusted vendors to avoid last-minute substitutions that could disrupt product profiles. There’s no substitute for boots on the ground, walking the plant, checking storage, and consulting with warehouse staff as well as laboratory analysts. It’s this blend of expertise and experience that lets us recognize, adapt, and prevent headaches before they escalate.
Customers expect more than a transaction—they want practical solutions when they hit a unexpected roadblock. We view technical troubleshooting as a shared problem, inviting transparent dialogue about synthesis steps, anomalous results, or changes in downstream reactivity. Offering written advice or inviting client chemists to tour our plant isn’t just good business, it’s how we collectively raise the bar for P-Hydroxybenzaldehyde applications. Team members remember early days, scrambling to solve a pharma client’s yield drop traced to minute impurity drift—now, routine process reviews and sample checks catch issues before they slip past the QA net.
What sets us apart isn’t just a technical data sheet or a regulatory certificate. Real differentiation lives in the detailed attention, continuous improvement, and the open feedback loops between our process team, sales staff, and the scientists and engineers who bring P-Hydroxybenzaldehyde into new applications year after year. Each new request, complaint, or success story lands on a desk where it meets collective experience. The feedback steering our work doesn’t end with a shipped invoice—it loops back to production, storage, logistics, and plant maintenance, refining the product’s profile over time.
With decades of specialization, we respect how crucial raw material integrity becomes across sectors. The subtleties of aroma or pharmaceutical intermediates force a closeness with our buyers and a drive for transparent, reliable production. Our safety and sustainability standards keep pace with both global expectations and local environmental realities. Long-term customer relationships bloom because we openly share our process, testing data, and improvements in technical handling. The stability, clarity, and consistency of our P-Hydroxybenzaldehyde owe everything to this open channel—one that leads from complex chemistry to customer confidence and tangible results. Each batch shipped tells not just the story of chemical synthesis, but the ongoing trust, diligence, and care that define us as a manufacturer in this field.
