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|
HS Code |
596693 |
| Chemical Name | Strontium Chloride Hexahydrate |
| Chemical Formula | SrCl2·6H2O |
| Molar Mass | 266.62 g/mol |
| Cas Number | 10025-70-4 |
| Appearance | Colorless crystalline solid |
| Solubility In Water | Very soluble |
| Melting Point | 61°C (decomposes) |
| Density | 1.92 g/cm³ |
| Odor | Odorless |
| Ph 1 Solution | 5.5 - 7.5 |
| Boiling Point | Decomposes before boiling |
| Storage Conditions | Store in a cool, dry place |
| Refractive Index | 1.520 |
As an accredited Strontium Chloride Hexahydrate factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | White, sealed plastic bottle labeled "Strontium Chloride Hexahydrate, 500g." Features hazard symbols, lot number, and manufacturer details for laboratory use. |
| Container Loading (20′ FCL) | 20′ FCL can load about 18 metric tons of Strontium Chloride Hexahydrate, usually packed in 25 kg plastic or fiber drums. |
| Shipping | Strontium Chloride Hexahydrate should be shipped in tightly sealed, moisture-resistant containers to prevent contamination and hydration loss. It is classified as non-hazardous for transport but must be handled with care. Store and ship in a cool, dry place, following all applicable local, state, and international regulations for chemical transport. |
| Storage | Strontium Chloride Hexahydrate should be stored in a tightly closed container in a cool, dry, and well-ventilated area, away from moisture and incompatible substances such as strong acids and oxidizers. Protect it from physical damage and direct sunlight. Ensure appropriate labeling, and avoid storing near food or drink. Follow all local, state, and federal regulations for chemical storage. |
| Shelf Life | Strontium Chloride Hexahydrate typically has a shelf life of 3–5 years if stored in a cool, dry, tightly sealed container. |
Competitive Strontium Chloride Hexahydrate prices that fit your budget—flexible terms and customized quotes for every order.
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Strontium Chloride Hexahydrate isn’t just another commodity in our production lines. Every batch that leaves our plant is the result of years of refining our synthesis, tracking market shifts, and listening to customer questions. In the chemical manufacturing world, reliability comes not from slogans, but from delivering the same stable behavior in every drum or bag. Our process for producing Strontium Chloride Hexahydrate—often written as SrCl2·6H2O—draws on continuous feedback and field-tested adjustments, focusing on delivering a clean product with low levels of foreign ions and consistent moisture content.
You’ll find Strontium Chloride Hexahydrate offered in several grades on the market, but not all of it suits industrial or research needs. Over the years, we’ve developed a production route that keeps unwanted barium, calcium, and iron residues low. For lab and analytical work, customers have found that stray elements can skew test results or produce unpredictable reactions. In glass and ceramics, any color shift or haze tells you purity matters. Our standard powders typically range between 98-99.5% pure, tailored by controlling our raw input and filtration steps. Sometimes, a project calls for even tighter tolerances, and in those cases, we adjust our drying and screening steps, even if it reduces yield.
Moisture content is another area where shortcuts never pay off. Hexahydrate means six waters of hydration; lose a couple on storage or shipment, and you stub your toe on misleading weight or strange behavior in blending. We’ve had customers report caking issues from fast-dried or over-aged product—so we train our crews to package only at the right moment, following a sweep of moisture measurements and surface checks.
Much of the demand for Strontium Chloride Hexahydrate comes from researchers or production lines that value strontium’s flame color and ionic properties. Flame test kits and university labs reach for it when teaching analytical chemistry. In specialty glassmaking, it shows up to help control thermal expansion or boost brightness in cathode ray tubes. The growing field of pyrotechnics leans on its vivid crimson signature, and even some toothpaste producers blend it into formulas where sensitivity treatments call for strontium ions.
From our side, we see most buyers want a product that dissolves smooth and fast, leaving no flakes or residues. This is more than an aesthetic concern; undissolved clumps in reaction vessels can slow down batch work and force more pH adjustments. We routinely run trials where we check grain size and test the dissolution time in both soft and hard water. These habits weren’t adopted out of theory but after direct feedback when some of our early shipments landed in European labs with more mineral-rich water than we had anticipated.
One question that keeps coming up relates to the difference between hexahydrate and the anhydrate or even tetrahydrate forms. Chemically, the backbone remains the same; the difference comes in how much water is bound to the strontium chloride. In practice, this influences handling, weighing, and stability.
We supply both hexahydrate and anhydrous versions, but the majority of our customers lean toward the hexahydrate for a couple of practical reasons. The hexahydrate resists dusting—no small thing when you work in humid climates or batch-scale mixing rooms. The added waters help pad against rapid deliquescence, making spills less likely to evaporate into sticky patches. Anhydrous material looks easier on paper—less weight, more active compound per kilogram—but it’s greedy for moisture, sometimes drawing humidity from the air and clumping after just a few days on an open bench.
In pyrotechnics, producers stick with hexahydrate because its pre-set water content removes a variable that can throw off combustion profiles. In industrial water chemistry, a steady hydration level prevents swings in calculated dosing. The anhydrite can save on shipping costs, but only where users have controlled storage and aren’t blending by bulk weight.
Strontium Chloride should not be confused with Strontium Nitrate or Strontium Carbonate, each of which targets completely different applications. For instance, nitrate offers oxidizing properties vital to red fireworks; carbonate plays its part in specialty ceramics. Chloride brings strontium’s color and reactivity, but without the same redox activity. The difference shows up in the finished product as inconsistency if formulas are swapped incorrectly—a mistake we’ve steered new customers away from more than once.
You don’t need to be reminded about dust, clumping, or contamination problems—most of our suggestions come from talking to boiler engineers, lab techs, or industrial blenders who deal with them daily. We focused on double-bagging and moisture barriers for export shipments after we noticed that even brief exposure at port can alter appearance and quality. Packs come in a range of materials, but after testing, we found thick polyethylene liners inside fiber drums offer the best combination of strength and resealability for most applications. Whenever a customer prepares for a long trip or uncertain storage conditions, we throw in an extra moisture-absorbing pack as part of the shipping routine, not as an upcharge.
Some manufacturers cut corners on grinding and screening, and we have seen how even 5% of outsized particles can drive up downstream rejection rates in glass melts or coating lines. Our operators inspect batch samples under magnification and, for critical volumes, run cross-batch blending to keep size distribution even. Years back, we had to problem-solve ways to keep product from absorbing odors during long warehouse holds; the answer, beyond cleaning and air-exchange protocols, lay in hermetic liners and reducing stack times. It’s not a perfect process, but with every complaint and repeat order, we tweak and improve.
It’s easy to overlook the upstream choices that define product consistency and safety. Raw material sourcing makes a difference; cheap sources often carry barium or even traces of hazardous lead. Early on, our team vetted suppliers with XRF and wet chemistry to keep element profiles tight. Not all customers see these differences in small-scale use, but large-scale runs and regulatory checks reveal them quickly.
Water used in crystallization has its own challenges. We choose deionized water lines, routinely flushed, to stop mineral creep. Energy inputs—mostly steam and hot air—affect hydration levels, so cycles are programmed to prevent surface crusts and incomplete drying. On days where humidity jumps, we slow the line and lengthen drying. Production crews work longer shifts, but downtime beats a truckload of compromised product.
Downstream, we participate in voluntary purity audits for larger clients, opening the doors to our filtration logs and shipping records. Our technical team tracks every complaint, whether it comes from a glass plant in Japan or a lab in North America. Over the last decade, direct feedback led us to standardize certain particle size and color specifications—if the crystals come out more yellow than white, or if fines rise above a set threshold, that batch gets scrutinized and usually reprocessed.
Plenty of users discover the hard way that improper storage, exposure to moisture, or blending with incompatible compounds can turn a reliable ingredient into a problem source. Small leaks in container seals can draw water and trigger caking; this isn’t a theoretical issue, but one we saw firsthand in tropical warehouses before we upgraded our packaging specs. Even after years of manufacturing, we still get calls about dissolving times and compatibility questions—many of these are rooted in unexpected pH swings, overlooked ions in blending water, or inventory that’s been stored too warm.
For those asking about compatibility with stainless steel and most plastics, we’ve run our own corrosion checks and can sign off on ordinary contact for months, provided cleaning is routine. In heated reactors, build-up of deposits can crop up, and we’ve published some sample cleaning protocols using dilute acids following internal trials. We can’t control local conditions, but we keep an open file of suggestions collected from other manufacturers and end users.
Over time, we’ve seen demand for Strontium Chloride Hexahydrate shift from classic TV tube glass and educational kits to more specialized areas: dental products, pyrotechnic colorants, and even certain feedstock for organic synthesis. Peaks and valleys in the rare earth and electronic sectors ripple into strontium demand, and we adjust stock and production levels accordingly. Supply chain interruptions or regulation changes can push buyers to seek alternative sources—or to request extra certifications from established producers.
More recently, calls for “greener” strontium sources have increased. Regulators and large industrial buyers ask for detailed records of waste water treatment, energy use, and source traceability. We’ve invested in closed-loop systems for cooling and waste, and adopted solubility monitors at key steps. Not every request leads to immediate production changes, but we see a slow tightening of purity and safety standards sector by sector.
We’ve learned that real industry relationships depend on listening to repeated questions, complaints, and ideas. Every year, we run into new challenges—whether that’s a rush order for climate studies in cold storage, a custom grind for high-speed blenders, or a request for micro-analysis data. Some of these can be solved quickly, others send us back to the drawing board or require trial batches for several months.
Our largest improvements start at the receiving dock and end with our in-line quality testers. If a customer calls about changes in product color, we schedule batch checks and adjust our filtration or drying cycle. When a European partner flagged unexpected corrosion, we coordinated joint tests to simulate their conditions and updated our support materials accordingly.
Our internal training investments make a difference. New operators learn chemistry and practical handling, not just button-pushing. Topics like safe transfer, accurate weighing, and moisture testing get special focus. Customers expect more than technical data; they call with urgency about on-the-floor problems, so the more our own crew understands, the faster those answers come.
Concerns about shelf life, caking, cost, and handling pop up repeatedly. In response, we’ve trialed smaller packaging sizes, tested different liner thicknesses, and experimented with modified atmospheric packaging. Some clients value the extra protection, others stick with traditional fiber drums for mix-room ergonomics. We work with both approaches, because different plants face different logistical and weather challenges.
Custom sizing remains a request, usually to fit unusual feed hoppers or speed up dissolution. We use both rotary and hammer milling, depending on the volume and target grain size. Sometimes tight cuts result in extra screening waste, but if it means fewer downstream complaints, the loss pays for itself.
Handling training appears repeatedly in feedback. Some clients ask for instruction sessions for staff, especially where turnover or agency hiring brings in less experienced handlers. We package written guides with each order and run seasonal refreshers based on customer case studies collected from the field. Not every batch will see perfect storage, so practical advice and real troubleshooting save everyone time when issues do arise.
Markets around the world set their own purity, labeling, and traceability demands. We keep detailed records of origins, processing, and packaging for each shipment. Our teams attend both local and international technical forums to stay on top of upcoming standard changes. If a batch fails on documentation or traceability, it doesn’t ship—not a popular decision in peak season, but one that customers respect when regulators check their paperwork.
Feedback from large-volume users sometimes points to overkill in documentation. We stick to a level of recordkeeping that lets buyers pass inspections with ease, while keeping the paperwork streamlined. Where clients require deeper traceability—pharma, medical device, or specialized lab supply—we can provide full lot-level reports and retain samples for callback testing.
Trends suggest that the need for high-purity, well-characterized strontium salts won’t vanish soon. Every new market report brings more attention to electronic displays, energy storage tech, and specialized dental or medical applications. As uses grow, so do requests for documentation, purity, and custom handling. We plan new investments in our reactors, moisture control gear, and packaging automation over the coming years, drawing on conversations with end users in mining, ceramics, and specialty chemicals.
We expect ongoing demand for practical support: flow diagrams for integration into existing lines, dosing tables, and application notes tailored to specific user challenges. Greater environmental scrutiny will bring tougher waste and by-product handling—but our team welcomes those audits because every reduction in waste means a tighter, cleaner process end to end.
Strontium Chloride Hexahydrate stands as a widely used salt with broad application. Our experience on the production floor, in the packaging room, and back in customer labs shapes how we approach every order. Manufacturing isn’t just about chemistry—it’s about follow-through, problem-solving, and learning from mistakes. Every barrel we ship carries more than a chemical compound; it’s the result of trial, error, and the constant push to improve, batch by batch.
