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HS Code |
477501 |
| Chemical Name | Lanthanum Metal |
| Chemical Symbol | La |
| Appearance | Silvery-white, metallic |
| Purity | Typically 99.9% |
| Form | Solid, usually pieces or lumps |
| Cas Number | 7439-91-0 |
| Density | 6.145 g/cm3 |
| Melting Point | 920°C |
| Boiling Point | 3464°C |
| Storage | Immersed in kerosene |
| Reactivity | Highly reactive with air and moisture |
| Molecular Weight | 138.91 g/mol |
| Solubility | Insoluble in water |
| Odor | Odorless |
| Protection | Stored under kerosene to prevent oxidation |
As an accredited Lanthanum Metal [Immersed In Kerosene] factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 1kg of Lanthanum Metal, sealed in a metal canister filled with kerosene, clearly labeled with hazard symbols and handling instructions. |
| Shipping | **Shipping Description:** Lanthanum Metal [Immersed In Kerosene] must be shipped as a hazardous material. It is packed under kerosene to prevent reaction with air or moisture. Use airtight, leak-proof containers, keep away from oxidizers or acids, label as “Dangerous When Wet”, and comply with relevant UN regulations (UN 3131). |
| Storage | Lanthanum metal, when immersed in kerosene, must be stored in tightly sealed containers to prevent air and moisture exposure, as the metal reacts readily with oxygen and water. Store the containers in a cool, dry, well-ventilated area, away from strong oxidizers, acids, and sources of ignition. Avoid heat and direct sunlight to minimize reaction risks and ensure chemical stability. |
Applications of Lanthanum Metal [Immersed In Kerosene] in Industrial ManufacturingLanthanum Metal stabilized in kerosene supports multiple advanced manufacturing sectors. We supply directly to end-use industries, enabling precise control over alloy composition, catalyst formulation, and electronic component manufacturing. The following real-world applications reflect current best practices and regulatory environments for lanthanum metal-based processes. 1. Hydrogen Storage Alloys for Nickel-Metal Hydride BatteriesHydrogen storage alloy producers use lanthanum as a critical base metal in the production of AB5 alloys, essential for nickel-metal hydride (NiMH) batteries. The stabilized form in kerosene allows easier handling and minimizes oxidation during alloying. The metal dissolves into the melting furnace after degreasing, followed by formulation with nickel, cobalt, manganese, and aluminum under controlled atmospheres. End users apply these alloys in rechargeable batteries for automotive hybrid vehicles, power tools, and consumer electronics. Industry compliance standards
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2. Fluid Catalytic Cracking (FCC) Catalyst ManufacturingLanthanum serves as a performance additive in zeolite-based catalysts for petroleum fluid catalytic cracking. Raw lanthanum metal, protected by kerosene, undergoes conversion to lanthanum nitrate or oxide before being incorporated during spray drying or impregnation onto the zeolite matrix. It stabilizes catalyst structure, enhances activity, and improves resistance to hydrothermal deactivation, supporting refiners’ needs for higher yields and longer run times. Industry compliance standards
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3. Optical Glass and Specialized Lens ManufacturingLanthanum improves refractive index and clarity in specialty glass formulations for high-end optical lenses. Direct delivery to glass melting lines as small ingots in kerosene ensures the additive enters the melt without oxidation loss. Glass engineers add it alongside other rare earths under atmospheric or reducing conditions, producing materials for precise imaging and enhanced UV resistance. Industry compliance standards
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4. Metal Hydride Hydrogen Storage MaterialsSpecialty metal hydride manufacturers formulate storage alloys with lanthanum for use in solid-state hydrogen storage cylinders. Purified lanthanum metal, protected in kerosene for safe handling, is alloyed with nickel and selected transition metals under vacuum induction melting. The resulting alloys offer high hydrogen storage density and rapid charge/discharge performance, supporting mobile hydrogen power systems and backup energy supplies. Industry compliance standards
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5. High Purity Lanthanum Compounds for Electronic CeramicsProducers of electronic ceramics convert high-purity lanthanum metal to lanthanum oxide or carbonate precursors for doping barium titanate and related dielectric ceramics. The metal, shipped immersed in kerosene for safety and oxidation prevention, undergoes dissolution and purification before combination with titanium and barium oxides via solid-state or sol-gel synthesis methods. This results in materials with specific dielectric and ferroelectric performance, critical for multilayer capacitors and piezoelectric devices. Industry compliance standards
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At our facility, producing Lanthanum Metal immersed in kerosene has been a commitment shaped by decades of hands-on manufacturing and feedback from industrial users. Many businesses across metallurgy, electronics, and special chemical sectors contact us looking for a reliable, consistent source for rare earth elements. There are many options available, but the method and form of supply matter more than some realize. Out here, protection during shipment and storage is just as important as the purity of the metal itself.
We manufacture lanthanum metal rods, cubes, buttons, and various custom shapes, each supplied immersed in kerosene from the moment it leaves our final processing line. Our standard grade delivers a purity of 99.5% minimum, with custom high-purity grades for certain applications. The kerosene immersion is no afterthought—it acts as an active shield. Lanthanum reacts quickly with air and moisture, tarnishing within seconds, developing an oxide layer that interferes with lab results, melt reactions, or vacuum processes. Covering the metal with kerosene preserves its silvery appearance and reactive surface through transportation and storage, keeping it as workable as the day it was produced.
Handling reactive metals can exasperate any lab technician or foundry worker. Over the years, we have tried different protection media—paraffin, vacuum-packing, even sealed inert atmospheres. In practice, kerosene protection wins out for cost, ease of removal, and overall preservation during extended shipping. Paraffin is tricky to remove. Vacuum-packed options allow small leaks, risking gradual oxidation. Kerosene forms a full-contact barrier against humidity and oxygen, wipes off easily, and never leaves residue that interferes with most downstream processes.
Customers often remark on the metallic brightness when opening a container of our lanthanum. Some even share how competition stock already carries a thin oxide. That’s not just aesthetics—oxidation can alter batch yields, upset catalyst development, raise costs in later processing, or degrade electrical functions in sensitive components. We push for these details because our own partnerships rely on outcomes, not just meeting a written spec.
Lanthanum’s use stretches across a wide field. In cathode materials for nickel-metal hydride batteries, clean starting metal is vital. Trace oxide and water content can cut the hydrogen storage capacity and shorten cycle life. Analytical research and electronics fabrication want lanthanum with minimal surface oxide to ensure precise doping levels, reproducible testing, and smooth melting. In specialized metallurgy, such as alloying or desulfurization of steel, even a few milligrams of oxide will shift reactivity, often with significant commercial results.
We work with process engineers who remember the difficulties of unseen corrosion. Each time a client loads lanthanum into a vacuum arc furnace or glass formulation, they risk introducing oxidized fragments if the metal didn’t ship perfectly protected. You can minimize that risk with kerosene immersion, since it preserves the entire lot until the operator is ready to cleanse and use it. From small R&D samples to bulk multi-kilogram shipments, we maintain this procedure purely because years of experience confirm it performs better than clamshell sealing, vacuum bags, or wax baths.
Our main grades of lanthanum metal cover 99.5% and 99.9% minimum purity. Impurity profiles stay consistent across lots—iron, silicon, calcium, and trace rare earths. Receiving consistent feedback from industrial chemists, we have learned which contaminant thresholds matter for high-temperature alloying and which impact catalyst outputs. We don’t market laboratory pipedreams—our purity numbers reflect reliable, measured batches, aligned with real-world needs. Most lots ship as 1 kg or 5 kg tins, each fully filled with kerosene, but custom packaging supports more specialized requirements.
Physical forms can range from lump, broken rod, buttons, to powder, but our standard is 20 mm cut rods, mostly because storage and controlled dosing prove easier in this shape. Some customers want thin foil or small slugs for direct loading in crucibles or vacuum tubes. Each time, the immersion in kerosene is the same—no exposed surfaces, every piece submersed before being sealed and boxed for shipment.
While laboratory purity draws attention, everyday chemical handling matters just as much. Our teams have worked through spills, oxidation mishaps, and failed seals. Since kerosene immerses fully across every batch, its protection works for months. In outdoor dockyards, high humidity storage, air-freight across equatorial climates, and simple temperature cycling in stockrooms, kerosene suppresses both oxidation and hydration for as long as the container stays closed.
In years of supply, we have witnessed how paraffin coatings collapse under thermal stress or minor impacts. Those wax residues cling to fine lanthanum metal, fouling further cleaning steps. Alternatives like argon packing push shipping costs up, only for an accidental puncture or open valve to kill the protection. Rarely does a material solution emerge that serves the entire shipping lifecycle the way kerosene immersion does. It accommodates batch handling and partial withdrawal—take some metal, replace the kerosene, and reseal.
Lanthanum sourced in pure air environments or protected by plastic alone seldom arrives in optimal condition. Many traders and some re-casters repackage lanthanum from larger ingots, introducing more steps for oxidation and contamination. By working directly with raw ore up to final shape, and moving product immediately from reduction to kerosene bath, we avoid exposures that degrade metal. Our process leaves every surface protected until it reaches the hands of the end-user.
Other rare earth metals may come stabilized using different carriers or under vacuums. With lanthanum’s high affinity for atmospheric oxygen and water, this philosophy leads to inconsistent results. Even short exposures—during cutting, counting, or repackaging—compromise bulk metal. The instant the surface appears dull or forms a white powder, its functional value for advanced work drops, sometimes beyond recovery. Feedback from chemical engineers tells us that switching to kerosene-protected supplies shrinks batch failures, reduces initial cleaning steps, and raises consistency across their workflows.
In an international context, variable environmental controls mean supply chains face points of failure from port to laboratory. Kerosene immersion cuts through those risks, functioning equally well regardless of where customers receive their stock—sub-Saharan freight or arctic labs show the same end result: usable, pure, bright lanthanum.
Documenting safety requirements or listing regulatory numbers fills pages, but reality in a metal shop or research lab turns on reliability. Over our manufacturing history, we have dropped, frozen, and accidentally left stock open during high-humidity months. In these cases, kerosene performed as a forgiving barrier. No system is perfect, but we choose immersion methods because they are proven to save stock for reprocessing rather than replacing metal due to surface damage. Insurance against wasted batches matters, and this method regularly proves itself better than lower-cost options.
We source kerosene with a precise boiling point, ensuring that it won’t evaporate easily in hot climates but pours away without residue. Trace contaminants from protection media, including sulfur or unsaturated organics, risk catalyzing undesired reactions once customers employ the metal. We learned long ago to triple clean and filter our kerosene before the metal meets it.
Compliance grows stricter each year. Analysts track impurities at the ppm level. If lanthanum metal absorbs contaminants from a poor-quality protectant or packaging, those impurities pass straight to downstream chemistries, electronic devices, or glass melts. Keeping every step controlled safeguards the integrity of our product—one reason so many long-term partners rely on direct supply from us instead of third-parties or resellers.
In many industries, lanthanum metal remains out of sight, quietly driving reactions or forming the backbone for new materials. It never gets the fanfare of high-profile alloys or battery chemistries. Yet an oxidized or compromised batch puts whole projects at risk. We hear stories from buyers sent poorly protected metal, with layers of white corrosion or oxide dust, resulting in project slowdowns or outright laboratory shutdowns while new supply is arranged.
On our production line, batches that don’t immediately go into kerosene receive a full recount and recasting. The workflow slows, but the result is less waste, happier partners, and real process improvements for customers. Oxidized scrap goes back for salvage, not into the outgoing stock. This quality loop isn’t about hype; it reflects a deeper manufacturing discipline, honed through years of feedback from frustrated engineers who value predictability.
Most buyers switch to kerosene-immersed lanthanum after bad experiences with compromised material. The difference shows not only in clear analysis figures, but in less downtime, fewer cleaning cycles, and sharper experimental outputs.
Lanthanum’s use in hydrogen storage, optics, phosphors, ceramics, and catalyst sets depends on surface reactivity and overall cleanliness as much as basic purity. In hydrogen getter applications, even trace oxidation can halve storage capacity. Glass formulations demand near spotlessness to avoid streaks or inclusions. Electronics and superconducting applications lean heavily on batch consistency and low-oxygen surfaces. Across each, kerosene immersion lets us promise a surface fit for high-precision applications, not just bulk production.
Some industries look for alternatives—hydrocarbon-free, solid liners, or novel polymer coatings. Our R&D team keeps samples on hand for potential evolutionary steps, but track records, cost, and end-user performance all point back to kerosene as the real-world champion for protecting lanthanum metal. We have learned to listen to the real circumstances in which industry works—fluctuating temperatures, transportation delays, and long-term storage—rather than assuming laboratory ideals will hold up outside research environments.
Having worked closely with refineries, glassmakers, and technology startups, we value frank feedback on what actually arrives, not just what ships. This real-world perspective shapes every batch’s production, immersion, and packaging. We test and recalibrate both purity analytics and protection methods against the unpredictable realities of global logistics. Even as process automation grows, final inspection, immersion, and sealing are managed by staff trained to spot the smallest defect. That human touch remains vital for sensitive materials, especially when handling reactive rare earths.
Many experienced buyers call or write to recount problems they have had before shifting to our immersion-protected lanthanum—sometimes confessing that they doubted the benefit until they saw differences in result. Our own lab teams run side-by-side comparisons each year, exposing lanthanum to both kerosene and inert gas flushes, then simulating high-humidity and temperature cycling. The results continue to show kerosene delivers preserved, fully reactive surfaces even after long delays or transit across ocean shipments.
We see our role as more than moving material out the door. Supplying lanthanum metal immersed in kerosene reflects choices refined through trial, error, and a history of learning from customers. It isn’t a category leader on price alone, but delivers long-term savings, reduced rework, and productivity gains. Small details—filtered kerosene, double-sealed tins, hand-checked rods—set results apart, especially for users who rely on consistent process outcomes.
Some producers shift to automated packaging or lower-grade protectants for cost-cutting. We pay extra to maintain kerosene immersion on all production lots. Our team pays the greatest attention to each step because it’s easier to get things right from the start than recover from preventable lapses. End-users in battery development, specialty alloys, glass or ceramics deserve metal that supports process and innovation, not just fills a spec sheet.
Lanthanum will continue to play a critical supporting role in emerging sectors, from clean energy to advanced materials. We will keep listening, adjusting, and applying proven approaches, staying grounded in practical experience rather than cliché or untested methods.
Handling and disposing of kerosene requires attention to local regulations and facility practices. We supply guidance and recommendations drawn from decades of shipments, helping customers establish safe decanting and metal retrieval processes that avoid loss, contamination, or environmental concern. Shippers and receivers require compatible facilities—our packing aims for practical handling by extending shelf life to allow flexible inventory planning.
Routine handling of reactive metals always carries risk—personnel protection, spill management, and tool cleanliness. We design our packaging for field use, knowing that not every customer has a glovebox or advanced nitrogen atmosphere. Our immersion delivers a balance of protection and simplicity for operators.
Over time, some customers explore returning spent kerosene to our facilities for reprocessing or safe disposal—closed-loop approaches that minimize waste footprint. We’ve set up routes for collection and collaborate closely with buyers looking to align with changing regulatory and environmental norms, while not compromising on protection.
Transport regulations for flammable materials evolve constantly. We track the latest requirements and work with certified carriers and logistics partners to ensure uninterrupted supply, with all documentation ready and best practices followed for safety and legal compliance.
As a lanthanum metal producer, we recognize our reputation grows every time the protected product arrives bright and ready for use. We accept the higher costs and attention to detail because time, reliability, and batch confidence matter more than headline price. Our lanthanum metal immersed in kerosene fulfills roles across science and industry, enabling new research and stable production in practical settings. The difference in results speaks for itself.