Aluminum Oxide (Al2O3) Sputtering Targets
Purity: 99.99%, Size: 2”, Thickness: 0.250”
Sputtering is a proven technology capable of depositing thin films from a wide variety of materials onto diverse substrate shapes and sizes. The process using sputter targets is repeatable and can be scaled from small research and development projects to production batches involving medium to large substrate areas. Chemical reactions may occur on the target surface, in-flight, or on the substrate depending on the process parameters. Although sputter deposition involves many variables, these parameters give experts significant control over film growth and microstructure.
Applications of Sputtering Targets
Sputtering targets are used for film deposition. The deposition achieved by sputter targets is a method of forming thin films through sputtering, which involves eroding material from a “target” source onto a “substrate” such as a silicon wafer.
Semiconductor sputtering targets are used to etch the target, especially when a high degree of anisotropy is required and selectivity is not a primary concern.
Sputter targets are also used for analytical purposes by etching away the target material. One example occurs in secondary ion spectroscopy (SIMS), where the target sample is sputtered at a constant rate. As the target is sputtered, the concentration and identity of sputtered atoms are measured using mass spectrometry. This method allows determination of the target composition, including extremely low impurity levels.
Sputtering targets also have applications in space. Sputtering is one form of space weathering, a process that changes the physical and chemical properties of airless bodies such as asteroids and the Moon.
Aluminum oxide is a chemical compound of aluminium and oxygen with the formula Al2O3. It is widely used in producing aluminium metal, as an abrasive due to its hardness, and as a refractory material because of its high melting point. Aluminum oxide thin films produced using aluminum oxide sputtering targets are widely applied in mechanical, optical, and microelectronic fields because of their strength, hardness, transparency, high abrasion and corrosion resistance, and insulating and optical properties. These film properties depend on sputtering system parameters such as sputtering rate, target–substrate distance, and reactive gas pressures.
Aluminum oxide thin films used in optoelectronics, tribology, sensorics, and nanolithography have been deposited using techniques such as magnetron sputtering, atomic layer deposition, electron beam evaporation, spray pyrolysis, and oxidation of aluminum films.
Summary
Al2O3 exhibits unique properties including chemical inertness, mechanical strength and hardness, high abrasion and corrosion resistance, a high electrical breakdown field, and a high dielectric constant. Thin films produced using aluminum oxide sputtering targets continue to attract significant research interest worldwide. These targets are used in various mechanical and microelectrical applications such as protective coatings, diffusion barriers, electronic seals, dielectric layers, and optical layers.
