| Material | Li3PO4: B2O3 |
| Purity | 99.9% |
| Shape | Planar Disc |
Stanford Advanced Materials (SAM) presents the Boron Oxide-Doped Lithium Phosphate Target (Li₃PO₄: B₂O₃), a premium sputtering material meticulously developed for solid-state electrolyte and thin film applications. This target is engineered to deliver superior ionic conductivity and enhanced stability, making it ideal for cutting-edge lithium battery technologies and advanced microelectronic devices.
Note: Specifications provided are based on theoretical data. For customized specifications and detailed inquiries, please contact our sales team.
Related Products: Lithium Sputtering Target, Li, Lithium Cobalt Oxide Sputtering Target, LiCoO2, Lithium Phosphate Sputtering Target, Li3PO4, Lithium Iron Phosphate Sputtering Target, LiFePO4, Boron Sputtering Target, B, Boron Nitride Sputtering Target, BN
The Boron Oxide-Doped Lithium Phosphate Target (Li₃PO₄: B₂O₃) combines the robust properties of lithium phosphate with the versatile characteristics of boron oxide. Lithium phosphate (Li₃PO₄) is renowned for its exceptional chemical stability, broad electrochemical window, and commendable ionic conductivity, making it a standout candidate for solid-state electrolytes. By doping with boron oxide (B₂O₃), the glassy structure of lithium phosphate is enhanced, promoting an amorphous nature that boosts ionic mobility. This doped target excels in forming uniform, high-quality thin films with excellent compatibility across various substrates. It maintains structural integrity during the sputtering process, offers superior thermal stability, and ensures the deposition of smooth, stoichiometrically consistent films. These features render it perfect for applications like thin-film batteries, protective electrode coatings, and sophisticated microelectronic components.
Our Boron Oxide-Doped Lithium Phosphate Targets are packaged with precision to ensure their safety and integrity during transit and storage. Depending on the size, smaller targets are securely packed in polypropylene (PP) boxes, while larger ones are shipped in bespoke wooden crates. We prioritize customized packaging solutions and utilize appropriate cushioning materials to provide maximum protection.
Packaging Options:
Q1: What benefits does Boron Oxide-Doped Lithium Phosphate offer as a sputtering target?
A1: It provides outstanding ionic conductivity, exceptional chemical stability, and excellent film-forming properties, making it ideal for applications in thin-film batteries and other electrochemical devices.
Q2: What are the common uses of Li₃PO₄: B₂O₃ targets?
A2: These targets are primarily used in the production of solid-state lithium-ion batteries, thin-film batteries, and as solid electrolytes or protective layers in various electrochemical devices.
Q3: Is the target compatible with both RF and DC sputtering systems?
A3: Yes, the Boron Oxide-Doped Lithium Phosphate Target is suitable for use in both RF and DC sputtering techniques, depending on the specific system design and process requirements.
| Property | Li₃PO₄: B₂O₃ | Li₃PO₄ (Standard) | LiFePO₄ | YBCO (YBa₂Cu₃O₇) | STO (SrTiO₃) |
|---|---|---|---|---|---|
| Composition | Li₃PO₄ doped with B₂O₃ | Pure Li₃PO₄ | Olivine LiFePO₄ | Yttrium Barium Copper Oxide | SrTiO₃ Perovskite |
| Purity | 95%+ | 99% | 99% | 99.99% | 99.95% |
| Ionic Conductivity (S/cm) | ~1×10⁻⁴ (optimized) | ~1×10⁻⁵ | ~1×10⁻¹⁴ | Superconducting (below Tc) | High resistivity (~10¹² Ω·cm) |
| Thermal Stability (°C) | Up to 1200 | Up to 1000 | Up to 800 | Up to 900 (sintering) | Up to 1400 |
| Key Applications | Radiation detectors, optoelectronic films | Solid electrolytes, interface coatings | Cathodes for lithium-ion batteries | Superconducting films, quantum devices | Dielectric layers, substrates |
| Form (Target) | Custom shapes (disc, rectangular) | Powder, thin films | Pellets, powders | Sputtering targets | Single-crystal substrates |
Lithium is a soft, silvery-white alkali metal with atomic number 3, recognized as the lightest metal and one of the most reactive elements. It is highly flammable and reacts vigorously with water to produce lithium hydroxide and hydrogen gas. Due to its low atomic mass and high electrochemical potential, lithium is indispensable in energy storage systems, particularly in lithium-ion and lithium-polymer batteries. Additionally, lithium is utilized in ceramics, glass production, aerospace alloys, and nuclear fusion processes. In thin film and sputtering applications, lithium compounds are essential as cathode materials for rechargeable batteries.
Phosphorus is a non-metallic element with atomic number 15, existing in multiple allotropic forms, predominantly white and red phosphorus. It is vital for all living organisms, being a fundamental component of DNA, RNA, and ATP. Industrially, phosphorus is extensively used in fertilizers, flame retardants, metallurgy, and specialty glass and coatings due to its reactive and versatile nature.
Boron is a metalloid with atomic number 5, known for its high melting point, complex bonding characteristics, and diverse structural forms. It plays a crucial role in the production of borosilicate glass, ceramics, semiconductors, and composite materials. Boron compounds, such as boric acid and boron carbide, are valued for their thermal stability, hardness, and applications in advanced materials, including nuclear reactors and permanent magnets.
