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HS Code |
922639 |
| Chemical Name | Nickel Nitrate |
| Chemical Formula | Ni(NO3)2·6H2O |
| Molar Mass | 290.79 g/mol |
| Appearance | Green crystalline solid |
| Purity | High Purity (typically ≥99%) |
| Solubility In Water | Highly soluble |
| Melting Point | 56.7°C (decomposes) |
| Density | 2.05 g/cm³ |
| Cas Number | 13478-00-7 |
| Odor | Odorless |
| Ph 1 Solution | Acidic |
| Boiling Point | Decomposes before boiling |
| Storage Conditions | Store in cool, dry, and well-ventilated area |
| Hazard Class | Oxidizing agent |
As an accredited Nickel Nitrate High Purity factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Nickel Nitrate High Purity, 500g, packed in a sealed amber glass bottle with screw cap, chemical safety label and hazard symbols. |
| Shipping | Nickel Nitrate High Purity is shipped in tightly-sealed, corrosion-resistant containers to prevent moisture ingress and contamination. Packages are clearly labeled with hazard warnings. Handling complies with regulations for oxidizing and toxic substances, with documentation provided for safe transport. Shipping is conducted via licensed carriers, following local and international safety guidelines. |
| Storage | Nickel Nitrate High Purity should be stored in a cool, dry, and well-ventilated area, away from direct sunlight, heat sources, and incompatible materials such as reducing agents and combustibles. Store in tightly closed, labeled containers made of corrosion-resistant material. Prevent moisture contact and avoid storage near organic materials. Ensure proper containment to prevent spillage and environmental contamination. |
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Purity 99.99%: Nickel Nitrate High Purity 99.99% is used in catalyst preparation, where high purity ensures optimal catalytic activity and minimal contamination. Molecular Weight 182.7 g/mol: Nickel Nitrate High Purity with molecular weight 182.7 g/mol is used in electroplating baths, where precise molecular consistency guarantees uniform nickel deposition. Melting Point 56.7°C: Nickel Nitrate High Purity with a melting point of 56.7°C is used in thermal decomposition studies, where controlled phase transitions permit accurate material characterization. Particle Size <10 µm: Nickel Nitrate High Purity with particle size below 10 µm is used in ceramics processing, where fine particles provide homogenous dispersion and improved sintering behavior. Stability Temperature 120°C: Nickel Nitrate High Purity stable up to 120°C is used in chemical synthesis, where enhanced stability minimizes decomposition and by-product formation. Low Residual Moisture <0.5%: Nickel Nitrate High Purity with residual moisture below 0.5% is used in battery precursor production, where low moisture reduces unwanted side reactions and prolongs material shelf life. Trace Metal Impurities <10 ppm: Nickel Nitrate High Purity containing less than 10 ppm trace metal impurities is used in pharmaceutical intermediates, where minimal impurity levels support regulatory compliance and product safety. Solubility 940 g/L (20°C): Nickel Nitrate High Purity with solubility of 940 g/L at 20°C is used in aqueous solution formulations, where high solubility enables concentrated solutions for efficient processing. Assay ≥99.9%: Nickel Nitrate High Purity with assay greater than or equal to 99.9% is used in analytical reagent preparation, where pronounced assay accuracy ensures reproducible experimental results. Free Flowing Granules: Nickel Nitrate High Purity supplied as free flowing granules is used in automated dosing systems, where enhanced flow properties improve metering accuracy and reduce handling errors. |
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Every lab technician and chemical engineer knows the relief of opening a fresh container of a reagent and instantly seeing the level of purity right on the label. Nickel Nitrate High Purity, model NN-HP98, stands out exactly for this reason. With a purity of 99.98% Ni(NO3)2·6H2O, it gives peace of mind and predictability to research and manufacturing tasks that tolerate little room for error. This product’s crystalline green surface tells a story about the attention given to proper crystallization, which comes into play during analytical work, synthesis protocols, and other sensitive applications.
My own experiences in university labs taught me never to overlook reagent purity. Inconsistent batches make it tough to reproduce results and lead to extra cost and wasted time tracking contaminant sources. Every chemist in the room had a story about a mystery misreading, often traced to a less-than-pure compound. After switching to documented high-purity sources like this, discrepancies in test results dropped, and confidence across different users improved. Years later in industry, teams looked first for this level of consistency to run plating baths reliably or get trace nickel concentrations right for catalysis and surface treatments.
Nickel salts show up in countless processes—catalysts, ceramics, electroplating, batteries, even certain diagnostic procedures. The “high purity” label changes not only the technical approach, but often project costs and outcomes. Contaminants in less refined nickel nitrate often hide as sodium, magnesium, copper, or iron. These aren’t just background noise. They can throw off sensitive catalytic cycles, lead coatings astray with visible pitting or cause electroplated layers to turn patchy and dull. When setting up a new experiment or a manufacturing run, the direct impact is clear: with a batch of Nickel Nitrate High Purity, adjustments meant for impurities fall out of the equation, and finished products or test results come out closer to expectations.
Colleagues in research have explained how, when building battery materials or specialty glass, even low levels of unseen elements change phase behaviors or color outcomes. Medical product developers worry about leaching metals, forcing repeat runs and more extensive safety checks if lower-purity reagents sneak into the supply chain. Choosing high purity at the start blocks a host of headaches. The reliability it brings lets teams spend time pushing research forward rather than tracking down the source of recurring problems.
Working with larger scale industrial materials looks attractive at first glance—lower price per kilogram, ready availability, and broader mixtures on offer. But any process where downstream purity or legal compliance matters eventually opens the books to reveal the hidden costs. Industrial grades of nickel nitrate tend to bring along non-nickel elements as baggage. It’s not always obvious right away, but trace metals, organics, and other ions can cause defects in final customer products that only appear after batches ship off to the next link in the chain.
A colleague in electroforming shared an example: their shop aimed for lustrous, flawless nickel deposits on satellite components. Any copper or iron over a few dozen ppm in the nitrate feedstock would dull the finish or introduce stress cracks in the nickel films. Low-purity inputs demanded more filtration time, routine chemical analysis, and setup for periodic stripping and rework. By contrast, with Nickel Nitrate High Purity, the team reduced these side tasks, gained tighter control over bath chemistry, and had fewer headaches when parts reached critical inspection.
Earlier in my career, project schedules revolved around batches that “just worked.” Being able to open a container and trust the numbers means researchers and technicians avoid unnecessary trial-and-error. The Nickel Nitrate High Purity, often supplied as crystalline hexahydrate, fits seamlessly into procedures calling for exact nickel concentrations. With moisture content and nickel nitrate assay closely monitored, consistent weight-to-nickel calculations minimize recalibration work across different batches.
In analytical chemistry, especially with trace metal detection or materials analysis, using a high-grade nickel nitrate helps eliminate uncertainty about what’s entering the sample. Mistakes or ambiguous results from hidden contaminants risk triggering audits, re-testing, or lost productivity. This product’s repeatability and full documentation fit naturally with requirements for ISO-certified labs and manufacturing processes bound by strict quality controls.
Electrochemical applications, such as nickel and nickel-alloy plating or as an activating agent in specialty battery work, benefit especially when the nitrate does its job without contributing unidentified factors. I watched a team chasing random plating breaks eventually solve their issues by upgrading the nickel nitrate input, eliminating variables that could slip past routine bath tests.
In research settings, Nickel Nitrate High Purity often plays a supporting role—serving as a source of nickel ions in solution, or as a precursor in materials synthesis. In crystal growth or ceramics, using pure sources avoids color variation, texture defects, and phase separation that turn up after sintering. Battery developers use it as a reliable nickel source to control cathode composition down to a fraction of a percent. Teams working with fuel cells, catalysts, or pharmaceutical intermediates frequently require the absence of iron and copper, which can derail the desired reaction path or open up safety risks.
Industrial users—plating shops, fabricators, coatings specialists—rely on this high-purity product to simplify incoming quality control routines. Blending a bath with a well-characterized chemical helps meet both customer specs and government standards for heavy metals. Extra steps spent filtering or treating for iron or magnesium drop off, offering a leaner production step. Having clear batch-to-batch traceability behind every drum pays off at audit time, as someone will always ask where the nickel originated and if it passed the right grade checks.
Modern industries face closer scrutiny over both quality and environmental impact. Battery plants tracking cobalt and nickel content rely on pure chemicals to meet tight product composition targets—falling off means customer complaints or fines from regulatory authorities. Wastewater from plating lines carries nickel nitrate traces. If incoming impurities spike unexpectedly, downstream compliance for effluent metals can lurch over limits, threatening both license renewals and public trust.
I remember a local plating firm that unwittingly failed a major audit after a shipment of lower-grade nickel nitrate introduced unexpected zinc. Because batch samples are archived in the event of disputes, their traceability helped identify the problem’s source. In this sense, high-purity reagents double as a guarantee against costly fallout—customer satisfaction, contract continuity, and environmental reputation all hang in the balance.
The move toward electric vehicles, new energy storage forms, and cleaner catalysis keeps nickel in the global spotlight. Sourcing poor-quality raw materials to cut initial costs now brings risk as end users and regulators demand more. Any shortcut on input purity forces more downstream controls, limit checks, and customer returns that outweigh the savings in procurement. Products like Nickel Nitrate High Purity stand in direct response to these pressures, offering a practical solution that scales from benchtop R&D to full-tilt production.
Some labs see reagent expense as a small share of the final product, so the temptation to shop on price feels short-sighted reading the list of failed synthesis runs and out-of-spec sheet metal. Nickel-derived products show up in consistent colorants for architects, safer alloys in medical implants, nickel catalysts for greener energy, and a growing class of high-function batteries that power everything from cell phones to city buses. In each of these fields, consistent, high-quality input chemicals show a real edge. Customers want to know every step is certified, and that care taken upstream pays off in the form of safer, better-performing, and longer-lasting results.
Working in production, the real cost of low-grade metal nitrates isn’t always in the reagent bill, but in the secondary cleanup required. Routine downtime for filter replacement, bath monitoring, and troubleshooting eats up staff hours that could be spent on expansion or innovation. Cleaner incoming material lets both people and machines focus on product improvement over patchwork defect correction. I’ve seen plating supervisors radio for a halt on new batches, only to trace back a minor glitch in the plating bath’s chemistry to an unexpected element piped in with a lower-class salt.
Labs that manage chemical stock centrally sometimes struggle to justify high-purity purchases to supervisors unfamiliar with end-product requirements. A convincing approach involves logging both the improvement in end-product quality and the reduction in troubleshooting. Once the superior purity option proves itself, staff find the cost argument tips rapidly. Maintenance schedules stretch out, rework drops, and the investment in quality raw materials gets repaid in both reduced stress and higher yield.
Everyone in the chemical supply chain, from sourcing specialists to end users, benefits from clarity about the real-world impact of input purity. Suppliers who maintain clear, up-to-date COAs and who can trace raw material back to origin offer partners protection against both technical and legal risk. In some regions, regulations around nickel and heavy metals keep tightening, so labs and manufacturers look for chemical partners that stay several steps ahead.
In academic work, access to high-purity reagents like this broadens the scope of research. Certain experiments, especially those involving nanomaterials or trace-metal catalysis, ride on the absence of interference. High-quality reagents mean saved time, cleaner data, and faster progress, easing the review process and cutting down on repetition. For science pushing boundaries, every source of uncertainty trimmed away is a step closer to reliable breakthrough.
Trends in production, energy storage, and advanced manufacturing are likely to push demand for clean, traceable nickel salts even higher. As more battery producers switch from older chemistries to nickel-intensive designs, the smallest differences in feedstock show up as real-world differences in energy density, stability, and charging capability. Pure material eliminates the shadow of “unknown unknowns” when scaling up new product lines, and makes regulation compliance less daunting as industry standards rise.
I’ve watched colleagues in materials science lose months’ worth of work trying to track down the cause of tiny but consistent shifts in magnetic alloy performance. The problem turned out to be low-level magnesium sneaking in through an unknown route in the supply chain, finally identified in a cheaper nickel nitrate batch. That experience convinced many to document their inputs with more care, and to choose product lines that provide the kind of technical support and batch continuity found with high-purity products.
So much of today’s industry circles back to environmental health, responsible supply chains, and product integrity. Fewer contaminants mean less risk of unexpected interactions, whether the concern is the lifespan of a grid-scale battery or a child’s exposure to heavy metals. By building manufacturing processes atop cleaner input streams, companies shrink their environmental footprint, lessen worker exposure, and help future-proof their business models.
In regions where environmental oversight grows each year, forward-looking firms already opt for higher grades of nickel nitrate as a matter of policy. These choices support internal process goals and send a signal about responsible manufacturing to both partners and customers. In my own work with quality managers in tech metals, showing clear, audited proof of high-purity raw materials lightened the burden of certification and made the story complete for downstream clients or public reporting.
Everyone relying on chemical manufacturing, material design, or industrial product integrity finds themselves weighed down by supply chain complexity, tightening regulation, and customer scrutiny. Stepping up to higher purity products like Nickel Nitrate High Purity means going on offense—solving known problems before they grow roots, supporting consistent outcomes, and safeguarding reputation. Whether the end goal is a clean-energy breakthrough or simply fewer headaches in daily production, the most committed teams look for every competitive edge they can find. Reliable, fully documented chemicals deliver one of the strongest foundations for sustainable achievement.
About two decades of work with stakeholders across science and manufacturing have shown the same thing: the highest returns come from careful selection at the earliest stage. High-purity reagents pay dividends that go far beyond what they cost up front. Choosing Nickel Nitrate High Purity isn’t just a move for better products. It’s a sign of respect for teams, customers, end users, and the environment—a tangible commitment to trust, reliability, and uncompromising progress.
