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Phloroglucinol Dihydrate

    • Product Name Phloroglucinol Dihydrate
    • Alias 1,3,5-Trihydroxybenzene
    • Einecs 614-030-9
    • Mininmum Order 1 g
    • Factory Site Tengfei Creation Center,55 Jiangjun Avenue, Jiangning District,Nanjing
    • Price Inquiry admin@sinochem-nanjing.com
    • Manufacturer Sinochem Nanjing Corporation
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    Specifications

    HS Code

    671950

    Product Name Phloroglucinol Dihydrate
    Chemical Formula C6H6O3·2H2O
    Molecular Weight 198.17 g/mol
    Appearance White to off-white crystalline powder
    Solubility Soluble in water, ethanol, and ether
    Melting Point 106-110 °C (dec.)
    Cas Number 6099-90-7
    Purity Typically ≥99%
    Storage Conditions Store in a cool, dry place, protected from light
    Synonyms 1,3,5-Trihydroxybenzene dihydrate
    Application Used in pharmaceuticals, laboratory reagents, and as an analytical reagent
    Hazard Statements May cause irritation to skin and eyes

    As an accredited Phloroglucinol Dihydrate factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.

    Packing & Storage
    Packing Phloroglucinol Dihydrate is supplied in a tightly sealed amber glass bottle, 100g, with a clear hazard label and product information.
    Shipping Phloroglucinol Dihydrate is shipped in tightly sealed containers to protect it from moisture and light. Packaging complies with relevant chemical transport regulations, ensuring safe handling. During transit, the chemical is kept in cool, dry conditions and clearly labeled for appropriate identification and hazard awareness. Shipping documentation accompanies every shipment.
    Storage Phloroglucinol Dihydrate should be stored in a tightly closed container, in a cool, dry, and well-ventilated area, away from sources of heat, moisture, and incompatible materials. Protect from light and humidity to prevent degradation. Avoid storage near oxidizing agents. Follow all relevant safety guidelines and local regulations when handling and storing this chemical.
    Application of Phloroglucinol Dihydrate

    Purity 99%: Phloroglucinol Dihydrate with 99% purity is used in pharmaceutical synthesis, where it ensures high-yield and high-purity end products.

    Low Molecular Weight: Phloroglucinol Dihydrate of low molecular weight is used in histological staining, where it provides enhanced tissue penetration and uniform staining results.

    Melting Point 210°C: Phloroglucinol Dihydrate with a melting point of 210°C is used in organic synthesis, where thermal stability allows for efficient high-temperature reactions.

    Particle Size < 100 µm: Phloroglucinol Dihydrate with particle size under 100 µm is used in analytical chemistry, where fine particle dispersion enables precise and homogenous sample preparation.

    Stability Temperature up to 50°C: Phloroglucinol Dihydrate with stability temperature up to 50°C is used in laboratory reagent applications, where it maintains chemical integrity during storage and handling.

    Hydration Level 2H2O: Phloroglucinol Dihydrate with a defined hydration level of 2H2O is used in colorimetric assays, where consistent water content ensures reproducible and accurate results.

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    Certification & Compliance
    More Introduction

    Understanding Phloroglucinol Dihydrate: A Reliable Choice for Lab and Industry

    Phloroglucinol Dihydrate stands out for chemists and researchers who need a dependable compound with well-documented properties. I remember my first encounter with this chemical during a stubborn synthesis project; its unique characteristics made a tough job manageable. The substance appears as fine, slightly yellowish crystals, dissolving swiftly in water and ethanol, a feature appreciated when speed and consistency matter in both testing and production.

    Breaking Down the Product: Model, Purity, and Everyday Value

    Not all Phloroglucinol Dihydrate looks or acts the same. Labs will often stock the standard analytical grade, with a typical purity of 99% or higher. For those working on pharmaceutical-level applications, this level of purity becomes non-negotiable due to strict regulatory scrutiny. One immediately practical point – the dihydrate form makes weighing and transferring simpler. Moisture content stays controlled, keeping measurements trustworthy whether you’re running a titration or scaling up a synthesis. Those little frustrations of inconsistent results disappear when you count on a batch that’s reliably uniform from start to finish.

    From Lab Bench to Pill Bottle: Usage in Real Life

    Phloroglucinol Dihydrate serves more than theoretical needs. In the pharmaceutical world, it often appears in antispasmodic drugs. Doctors and scientists trust it for its muscle relaxant action, helping people struggling with digestive cramps. I recall fielding questions from physicians about how this translates into real benefits for patients – the answer lies in research spanning decades. Unlike some alternatives, it doesn’t come with a long tail of severe gastrointestinal side effects, increasing patient comfort.

    Beyond medicine, plant biologists use it as a staining reagent in lignin analysis, which aids in understanding the structural complexity of plant tissues. I’ve sat in on long discussions about how staining choices affect botanical findings; switching to Phloroglucinol Dihydrate can make differences visible that obscure markers might miss. Researchers value the clarity, not only of results but of interpretation, when using such a well-characterized compound.

    Comparing Alternatives: How Does Phloroglucinol Dihydrate Measure Up?

    Every scientist faces a crossroads eventually: stick with the tried-and-true or branch out to save a few dollars. Some turn to anhydrous phloroglucinol or synthetically similar compounds, hoping for similar performance. In practice, the dihydrate form often proves more manageable. The fixed water content makes calculations straightforward, eliminating the need to adjust concentrations after every bottle opened. Anhydrous options can draw in moisture at unpredictable rates, quickly throwing off results.

    Other chemical agents might look similar on paper, but Phloroglucinol Dihydrate enjoys a better track record in terms of predicted reactions and stability in open lab environments. I’ve seen junior chemists run side-by-side tests, only to return to the dihydrate form for reproducibility and shelf life. It also withstands routine storage without excessive caking or degradation, sparing organizations from costly replacements or rushed inventory turnover.

    Quality Control – Not Just a Buzzword

    Reliable outcomes spring from reliable sources. Whenever I work with Phloroglucinol Dihydrate, traceability and provenance matter just as much as purity. Reputable suppliers publish certificates of analysis with every lot. The published melting point—usually between 107°C and 110°C—serves as a quick reference check. Monitoring batch-to-batch consistency protects research from subtle pitfalls and supports the trust downstream users build on each step.

    I’ve advised labs that cut corners to save money, only to find unexpected byproducts in their results. It’s those tiny deviations—sometimes invisible until the final stage—that slow progress. With trusted, high-purity Phloroglucinol Dihydrate, routine QC checks tend to yield clean chromatograms and reproducible spectra. Budget-conscious buyers are sometimes tempted by off-brand alternatives, but past experience has shown that true cost emerges over the whole experiment, not just at the moment of purchase.

    Safe Handling and Storage – Lessons Learned from Real Life

    Even well-trodden chemicals deserve respect. Early in my career, I handled a poorly capped bottle and noticed clumping after a month, which sparked a valuable lesson. The dihydrate version resists atmospheric moisture better than some alternatives, but tight lids and cool, dry conditions prevent headaches down the line. Storage recommendations aren’t guesswork—they reflect patterns of real world mishaps, and those who follow them avoid lost time and spoiled stock.

    Information sheets advise against inhalation and recommend gloves, which always strikes me as simple insurance. Even seasoned lab techs can become complacent, but one slip can mean a call to the safety office. Consistently following best practices saves more than just health; it safeguards years of work.

    Environmental and Ethical Considerations

    Growth in green chemistry leads many to reevaluate traditional reagents, even dependable ones like Phloroglucinol Dihydrate. Careful sourcing and responsible disposal matter, and I’ve witnessed efforts by suppliers to cut down on excessive packaging. Used in controlled quantities, the compound presents modest risk when handled according to accepted standards. Still, long-term sustainability means encouraging recycling of glassware and minimizing waste streams wherever feasible.

    Transparency through the supply chain matters to modern labs. I’ve seen colleagues request full disclosure of manufacturing practices as part of their procurement process, and certifying bodies have stepped up. This reflects growing awareness around environmental footprint, ensuring science progresses without unnecessary harm.

    Supporting Innovation in Field Testing and Beyond

    Constant refinement keeps research moving forward. Innovative test kits have started incorporating Phloroglucinol Dihydrate for quick screening in agriculture, where time counts. Because the compound reacts in a predictable fashion with certain plant constituents, on-site botanists receive actionable results almost immediately. I’ve seen these kits in the field, from crop researchers to forest ecologists leveraging reliable chemical responses to assess wood quality or diagnose disease.

    Accessibility supports creative problem solving. Small, portable vials have replaced larger glass bottles, encouraging careful dosing and less waste. When educators introduce undergraduates to hands-on chemistry, phloroglucinol-based reactions provide visible, memorable results that cement key lessons. Those lightbulb moments keep the next generation of researchers engaged.

    Reproducibility and the Modern Research Climate

    With scientific publishing scrutinized like never before, reproducibility stands as a top priority. Sourcing Phloroglucinol Dihydrate from established suppliers under constant review reduces concerns about experimental discrepancies caused by hidden impurities. I’ve sat through lab meetings where a month’s worth of work unraveled because of a tainted batch purchased cheaply. Lessons learned—the small investment in reputable, thoroughly vetted product pays off every time data hits review.

    Even as automation enters more labs, manual preparation and measurement persist for compounds like this. The tactile reliability means even small research groups can achieve consistency without relying on high-dollar robotic liquid handlers. Trusted reagents bridge resource gaps and keep doors open to discovery for institutions operating outside major research hubs.

    Beyond the Shelf: Social Accountability and Scientific Trust

    Science depends on more than accuracy—it requires public trust. Phloroglucinol Dihydrate carries a legacy of transparency, with clear documentation and decades of published validation. Having taught students on the importance of chemical provenance, I continue stressing the intangible benefit of choosing reagents with proven, accessible safety records. Open channels between supplier and user reduce ambiguity and support the entire ecosystem of knowledge sharing.

    Growing demands for open data include full disclosure of experimental conditions. Clear, stable compounds like Phloroglucinol Dihydrate simplify this process and reduce variables that can obscure results. Efforts to digitize lab recordkeeping thrive on clarity; thus, products with consistent molecular profiles serve as the cornerstone for collaborative research worldwide.

    Challenges in Access and Pricing

    Stable demand sometimes leads to tight supply, especially in regions where chemical imports face regulatory hurdles. Sudden price jumps have caught more than one project manager off-guard, forcing researchers to seek alternatives or scale back ambitious plans. Pooled purchasing groups and consortia provide one path forward, spreading costs and guaranteeing larger, more stable contracts that can result in fairer pricing for academic institutions.

    Some users turn to local chemical distributors, but these middle steps can invite quality concerns if the supply trail turns murky. The market rewards transparency; end users feel empowered knowing exactly where and how their chemicals originate. Only through these direct relationships can costs be balanced with confidence in every carton and flask.

    Opportunity for Process Improvements

    Production processes for organic chemicals like Phloroglucinol Dihydrate have evolved, but energy usage and waste management remain relevant hurdles. I’ve toured facilities working toward greener alternatives, incorporating closed-loop systems and catalytic methods to reduce environmental impact. Such improvements trickle down the value chain, making purchasing decisions meaningful all the way from boardroom to bench.

    Customers can push for these changes, asking for documentation of sustainability initiatives and reduced emissions footprints. By making choices not only on purity or cost but also on ethical production, group buying power nudges the sector toward continual improvement. I’ve seen lab managers flag emissions paperwork as a tie-breaker when choosing between suppliers.

    Empowering the Next Generation of Users

    Education opens doors to safe and impactful application. Workshops and conferences frequently spotlight best practices, ensuring new users develop strong habits. Early exposure during undergraduate coursework demystifies both the risks and the real-world benefits of reagents like Phloroglucinol Dihydrate. From interactive demonstrations to independent projects, hands-on learning leaves stronger impressions than rote safety memoranda.

    Legacy users serve as informal mentors, passing along safety advice as well as tricks for fast, accurate measurement. These shared experiences build a culture of reliability and curiosity that keeps science dynamic and innovative. I vividly remember an instructor guiding students while explaining the story behind each chemical, rooting abstract concepts in concrete classroom memories

    Potential Solutions and Future Directions

    Striving for better outcomes, the industry can lean into new modes of packaging to reduce exposure risks and limit spoilage. Vacuum-sealed, break-resistant containers hold promise, especially for remote or high-throughput operations. In parallel, supplier adoption of digital inventory-tracking tools allows labs to minimize expired stock and curb unnecessary waste. Early tests of such systems have reduced annual disposal costs and kept shelf spaces tidier.

    Supply interruptions persist as a risk. Collaborative forecasting between buyers and suppliers smooths order cycles and keeps operations humming. I’ve watched organizations enroll in early alert systems to stay ahead of sudden shortages, giving them time to source alternatives or temporarily pause lower-priority work. Integrating artificial intelligence for demand planning could further stabilize pricing and keep research timelines predictable.

    Conclusion: Value Rooted in Reliability

    Through its distinct combination of physical and chemical stability, tightly controlled purity, and long-standing record of clinical and laboratory success, Phloroglucinol Dihydrate finds a place as a trusted ally across scientific fields. By focusing procurement and application decisions around credibility, traceability, and ethical production, users safeguard not only their own work but also the broader trust underpinning scientific progress. From early lessons at the lab bench to decisive moments in production, choosing the right supplier for Phloroglucinol Dihydrate supports every stage where certainty and safety matter most.