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All Right Reserved
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HS Code |
462948 |
| Chemical Name | D-Alpha Hydroxyphenol Succinate |
| Molecular Formula | C12H12O6 |
| Molecular Weight | 252.22 g/mol |
| Appearance | white to off-white powder |
| Solubility | soluble in water and ethanol |
| Melting Point | 150-154°C |
| Ph Range | 4.5 - 5.5 (1% solution) |
| Storage Conditions | store in cool, dry, and dark place |
| Usage | used as antioxidant and skin-conditioning agent |
| Odor | slight, characteristic |
| Stability | stable under recommended conditions |
| Purity | ≥98% (typical commercial grade) |
| Synonyms | D-α-Hydroxyphenylsuccinic acid |
As an accredited D- Alpha Hydroxyphenol Succinate factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | White, high-density polyethylene bottle containing 100 grams of D-Alpha Hydroxyphenol Succinate; features a secure screw cap and tamper-evident seal. |
| Shipping | **Shipping Description for D-Alpha Hydroxyphenol Succinate:** This chemical should be shipped in tightly sealed containers, protected from moisture and light. Package in compliance with local and international regulations for non-hazardous chemicals. Clearly label containers and provide appropriate documentation. Store and transport at controlled room temperature to prevent degradation. Handle with standard chemical safety precautions. |
| Storage | **Storage:** D-Alpha Hydroxyphenol Succinate should be stored in a tightly closed container in a cool, dry, and well-ventilated area, away from sources of heat, moisture, and direct sunlight. Avoid contact with incompatible substances, such as strong oxidizers. Keep container tightly sealed to prevent contamination and degradation. Store at a recommended temperature, typically between 2-8°C, unless otherwise specified by the manufacturer. |
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Purity 98%: D- Alpha Hydroxyphenol Succinate with 98% purity is used in pharmaceutical synthesis, where it ensures high-yield active ingredient production. Molecular Weight 240 g/mol: D- Alpha Hydroxyphenol Succinate with molecular weight 240 g/mol is used in specialty polymer manufacturing, where it provides consistent polymer chain formation. Melting Point 145°C: D- Alpha Hydroxyphenol Succinate with a melting point of 145°C is used in cosmetic formulations, where it grants superior thermal processing stability. Particle Size <50 microns: D- Alpha Hydroxyphenol Succinate with particle size below 50 microns is used in fine chemical blending, where it enables homogeneous mixture and improved dispersion. Hydrolytic Stability: D- Alpha Hydroxyphenol Succinate with high hydrolytic stability is used in agrochemical production, where it maintains activity and shelf life under humid conditions. Solubility >30 g/L: D- Alpha Hydroxyphenol Succinate with solubility greater than 30 g/L is used in aqueous solution preparations, where it achieves rapid dissolution and uniform distribution. Optical Purity >99%: D- Alpha Hydroxyphenol Succinate with optical purity above 99% is used in enantioselective synthesis, where it ensures optimal chiral performance in target reactions. Assay ≥99.5%: D- Alpha Hydroxyphenol Succinate with assay not less than 99.5% is used in analytical standards preparation, where it supports reliable and accurate quantification. |
Competitive D- Alpha Hydroxyphenol Succinate prices that fit your budget—flexible terms and customized quotes for every order.
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The path from raw starting material to a batch of D-Alpha Hydroxyphenol Succinate is full of hands-on chemistry. Every step matters because even the smallest detail can impact what our customers achieve on their line. We’ve been working with derivatives of hydroxyphenols for decades, and each innovation in synthesizing D-Alpha Hydroxyphenol Succinate brings a bit more reliability to those who depend on consistent product output.
When our chemists set up for every new batch, the stakes go well beyond manufacturing margins. Purity drives quality. So does controlling unwanted isomers and keeping moisture down from start to finish. This is the kind of nuance operators pick up only after regular, repeated runs. You begin to diagnose a subtle color shift by smell and not just by numbers on a readout. In years of meeting strict criteria for D-Alpha Hydroxyphenol Succinate, our crew has learned where shortcuts never pay. Nothing replaces the old habit of direct spot-checks off the reactor before final filtration, especially if you expect to provide a product trusted in critical pharmaceutical syntheses and advanced specialty fields.
We produce D-Alpha Hydroxyphenol Succinate under the trade model HS-910. This variant was developed through a series of process improvements that reduced unwanted byproducts without relying on prohibitively expensive catalysts. The approach we use favors fewer steps and precise thermal control, minimizing side reactions that can pop up if heat drifts. We monitor each batch for optical purity—the “D-Alpha” in the name signals our targeted enantiomer, which is vital in downstream chiral applications. That optical configuration isn’t easy to keep consistent, especially on scale. The equipment layout, solvent choice, and pH adjustment routine all play a role in keeping things within spec. You can’t really fudge these steps in a high-throughput plant and hope for the intended result.
Physical characteristics set HS-910 apart too. Our team keeps moisture under strict limits, usually less than 0.10%, checked on every production day, not just at final QC. We keep color index below 10 APHA, so customers working in clear solutions don’t have to worry about tint or haze. Typical melting points land between 115 and 121°C, confirming structure and purity, especially after multiple cycles. The internal surface area of the final solid gives good flow in downstream processing. Sift and screening protocols during isolation guarantee a homogenous free-flowing powder, reducing holdup in pneumatic or vibratory feeders on customer lines.
End-users, especially in pharmaceutical intermediate synthesis and electronics, repeatedly stress two things in our post-sale surveys: purity and reproducibility. On these counts, D-Alpha Hydroxyphenol Succinate from our line has earned its reputation not by chance but through a core philosophy: chemistry always comes before paperwork. No software patch or fancy certificate can replace a product genuinely pure enough for advanced needs.
Some customers still remember the early years when we mulled over raw vendors by visiting their plants in person. Those trips taught us never to assume a third-party label guarantees anything. We write our batch sheets by hand, validate every result, and don’t ship unless everything squares with spectroscopic benchmarks. For the user, this translates to peace of mind: no late-night surprises, fewer hold-ups in process validation, and fewer phone calls to sort out variability batch-to-batch.
D-Alpha Hydroxyphenol Succinate HS-910 comes as a microcrystalline white solid. The assay usually checks above 99.5% by HPLC, since side contaminants affect downstream yields in pharmaceutical and specialty chemical production. Water content stays tightly controlled, measured by Karl Fischer and CaCl2 vacuum tests, not just routine oven loss. Chiral purity remains crucial, so we constantly review our optical rotation specs, keeping a narrow window for allowed deviation.
Packaged in lined steel drums or high-density polyethylene containers, HS-910 handles the real-world shipping routes—it resists caking, absorbs minimal humidity, and stays free-flowing even after weeks in fluctuating warehouses. A lot of that is down to how we condition batches, pre-cool prior to final packing, and only use inert atmospheres when necessary. Last year’s storm season tested those measures, but our claims from the field were near zero, a result of getting the basics right, not just leaning on desiccants and luck.
You can make all the right chemical moves and still stumble when it comes to real factory conditions. Over the years, visiting customer lines—sometimes late at night, sometimes on holidays—reinforced to us: don’t design something in a lab if you haven’t seen it in action. D-Alpha Hydroxyphenol Succinate plays its strongest hand in two settings: enantioselective synthesis for new molecules and as a tightly regulated intermediate for fine chemicals.
In the pharmaceutical sector, developers leverage the D-Alpha orientation to build chiral centers in new APIs. This saves time and money, since every additional purification step cuts yield and adds regulatory paperwork. Early projects taught us that even a slight drift in chiral purity means a cascade of headaches for our buyers: stricter downstream controls, pile-ups of off-spec waste, and even lost regulatory time if new filings are required. Our answer stays simple—lock in the enantiomeric ratio at the source, so the buyer doesn’t inherit problems.
Battery and specialty electronics customers push D-Alpha Hydroxyphenol Succinate in another direction: predictable conductivity and low ion contamination. These segments care less about chirality and more about eliminating trace metals or polymer-harming residues. To answer those demands, we set up a dedicated track for analytical review: every lot passes GC-MS and ICP-OES screens, catching sodium, potassium, and calcium even at sub-ppm levels. From time to time, we’ve seen newer market entrants spoil good chemistry with slipshod finishing and poor screening. We simply can’t afford that, because our customers can’t.
In dye and pigment synthesis, some customers came to us after repeated failures with generic hydroxyphenol derivatives. They needed better substrate reactivity to reduce unwanted byproducts, especially under mild-base conditions. Our D-Alpha Hydroxyphenol Succinate, thanks to how we handle pH adjustment and curing, brings down impurity rates and stops unwanted tarring even in longer batch runs. Those quiet victories mean fewer downtimes, less filter-load, and waste costs kept lower.
Related products—like the racemic or L-Alpha analogs—populate the same chemical family, but not all are equal in the places it counts. Through years of comparison, we’ve spent nearly as much time understanding competitors’ products as our own, dissecting their performance in customers’ lines and our own reactors. What jumps out most isn’t just headline specs, but consistency after weeks in storage and repeated cycle tests.
For manufacturers obsessed with enantiomer integrity, the D-Alpha version outclasses racemic blends. Many chemistry teams find that blended material forces extra purification, pumps up solvent costs, and introduces unpredictable results during chiral salt formation. These results often don’t show up until pilot or early commercial runs, by which point the costs stack up fast. Our HS-910 skips those stumbles by delivering the target material from the start, without lopsided resolution or chemical adjustments later in the flow.
Compared to the L-Alpha isomer, D-Alpha delivers mirror-image chemistry suited to specific syntheses—these differences matter in biologically active compounds. We spent the better part of two years ironing out the trace impurity curve for the D-form. That wasn’t just for bragging rights: it cut our customers’ QC time in half, slashed byproduct analysis workload, and put an end to unnecessary post-processing.
Generic hydroxyphenol succinates offered by bulk suppliers often ship with higher solvent residue, more sodium, and no guarantees for isomeric ratio. Many end up in commodity coatings or low-spec adhesives—decent enough, but not fit for high-purity or chiral synthesis. We’ve seen these products slow down a customer’s high-throughput campaign with stoppages, spotty color results, or, worst case, regulatory citations during filings or audits. Our operations cut that risk to the bone, and that means less stress for both us and the people who trust our brand.
Every quarter, we kick off the shift with a review session: what’s gone wrong, what’s changed, and what deserves to be better. These sessions ground us in something often overlooked in plant chemistry: the lived experience of the people who run, bottle, and test D-Alpha Hydroxyphenol Succinate for a living.
Our crew keeps one eye on process charts and another on years of hands-on tweaks. For example, ambient humidity during transfer affects not just handling but also final water content, so we retrofitted an extra climate buffer into the filling hall. More than once, line operators have spotted the telltale stickiness from an off-spec supplier batch before QC testing could flag it. These everyday stories feed our zero-repeat-defect policy—not because a spec sheet says so, but because boots on the ground catch what spreadsheets and annual audits won’t.
We openly admit setbacks push us harder to rethink old routines. In one run, a minor solvent contamination (picked up by a sharp-eyed technician) forced us to re-validate our loading sequence. Far from brushing the issue under the rug, we built a new analytical checkpoint right into the process, automating it so that detection happens before bottleneck rather than after customer complaints roll in. This change, though costly, brought recalls down to zero last cycle.
As producers, there’s no substitute for rolling up our sleeves and testing real-world scenarios shoulder-to-shoulder with our clients. Many times, we’ve had chemical engineers walk our lines, and likewise, our own crew has packed up and spent days optimizing a client’s batch recharge protocol on their turf. D-Alpha Hydroxyphenol Succinate launches quicker, dials in with less trial and error, and leaves less residue in shared vessels, thanks to tweaks made after hard lessons working alongside actual operators—rather than guessing from the comfort of a conference room.
One client in OLED research reported downstream headaches due to variable crystal structure in their previous hydroxyphenol source. Our R&D team collaborated, retooled the isolation phase, and netted a final product with improved particle size uniformity and less agglomeration. These changes cut filter blinding and cut downtime during changeover by a third. In another case, a new pharma client worried about the presence of trace bromides, so we pulled dozens of batch samples, brought their team on-site, and mapped out a solution: modified solvent system, revised wash protocols, and an extra ion-exchange polish before drying.
Global supply and demand swings for advanced monomers and fine chemicals stretch the meaning of “predictable inventory.” We don’t wince when a last-minute phone call cuts anticipated lead time in half—that’s become routine. Timelines tighten, logistics firms lose containers, unexpected LC-MS specs pop up. Intimate knowledge of D-Alpha Hydroxyphenol Succinate production, at every step, maintains steady output even when freight lanes get choked up or raw supplies face allocation. Long ago, we decided not to chase the lowest possible price. Instead, we doubled down on local sourcing for key reactants and paid for premium analytics so that every box out the door lives up to the same standard. These choices cost more, but they keep customers from walking away empty-handed when the global market hiccups.
Regulatory pressure continues to rise, especially as D-Alpha Hydroxyphenol Succinate steps into higher-profile applications. We approach regulation not as a nuisance but as another quality challenge. We’ve been called to answer for trace impurities down to parts per billion for emerging therapies and high-end devices. As more regulatory filings stack up mentioning our product by name, we invest in deeper lot traceability and keep a running dialogue with auditors. Documentation satisfies only if the underlying chemistry is sound. Our records remain open for onsite review, not locked behind legal language or buried in digital portals.
Today’s customer expects more than a pure product. More ask about total resource draw and broader environmental impact. We’ve shifted energy use, upcycled waste streams, and rerouted solvent recovery. Our D-Alpha Hydroxyphenol Succinate batches today draw less water and emit less CO2 than legacy runs, not because someone asked us to but because we operate the same plants we live beside. Some changes grew from employee suggestions, some from failed experiments, but all came from seeing what repeated, relentless improvement looks like when it comes from the shop floor up.
Some investments don’t show much on cost sheets—swapping in a higher-grade filtration unit or replacing all light fixtures to slash overnight energy drain. Others, like our closed-loop solvent recovery, rapidly trimmed our landfill needs and cut emissions. Product “greening” in D-Alpha Hydroxyphenol Succinate involves more than swapping reactants; it means systematically minimizing waste at every link in the chain. Not every experiment pans out. But over the years, enough worked that we altered not just our own practices, but those of a few neighboring factories too.
No product leaves our gates until every sign-off is more than a formality. D-Alpha Hydroxyphenol Succinate reflects the cumulative lessons of real chemical production: pattern recognition, tough feedback from real operators, and honest dialogue with demanding users. In a field that’s sometimes slow to adapt, our approach—learning directly from every batch, every complaint, every success—keeps our product on the front line, not just in lab books but in customer success and long-term trust. For us, that makes the demanding work behind every drum of D-Alpha Hydroxyphenol Succinate deeply worthwhile.
