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Cerium Bismuth Ferrite Sputtering Targets

Cerium Bismuth Ferrite Sputtering Targets

Cerium Bismuth Ferrite Sputtering Targets
Product No NRE-43211
CAS No. NA
Formula Ce2.2Bi0.8Fe5O12
Molecular Weight NA
Purity >99.9%
Density NA
Thickness 3 mm ± 0.5mm (can be customized)
Diameter 50 mm ± 1mm (can be customized)
Shape Round
Resistivity NA
Thermal Conductivity NA

Cerium Bismuth Ferrite Sputtering Targets

Cerium bismuth ferrite (Bi₁₋ₓCeₓFeO₃) sputtering targets are used in various advanced applications due to their unique combination of ferroelectric, magnetic, and optical properties. Here’s an overview of some key product applications for cerium bismuth ferrite sputtering targets.

Multiferroic Materials:

Data Storage: Cerium bismuth ferrite is a multiferroic material, which means it exhibits both ferroelectric and magnetic properties. This makes it suitable for advanced data storage technologies, such as magnetic data storage devices, where both electrical and magnetic information can be manipulated.

Memory Devices: In memory devices like multiferroic RAM (FeRAM), cerium bismuth ferrite can be used to improve the performance and density of non-volatile memory.

Sensors and Actuators:

Ferroelectric Sensors: The ferroelectric properties of cerium bismuth ferrite make it useful in sensors that detect changes in electric fields, temperature, or pressure. Its ability to respond to both electric and magnetic fields can enhance the sensitivity and functionality of these sensors.

Actuators: In actuators, cerium bismuth ferrite can be used to convert electrical energy into mechanical motion or vice versa, leveraging its multiferroic properties for precise control.

Optoelectronic Devices:

Optical Modulators: Cerium bismuth ferrite thin films can be used in optical modulators to control light transmission based on electrical or magnetic fields, benefiting applications in telecommunications and imaging.

Photonic Devices: The material’s optical properties can be utilized in photonic devices for manipulating light in various ways, including filters, switches, and waveguides.

Magnetoelectric Devices:

Magnetoelectric Sensors: The coupling of electric and magnetic properties in cerium bismuth ferrite can be exploited in magnetoelectric sensors, which detect changes in magnetic fields and convert them into electric signals.

Advanced Coatings:

Protective Coatings: The material’s stability and unique properties can be used to create protective coatings for electronic devices, enhancing their durability and performance.

Functional Coatings: In addition to protection, cerium bismuth ferrite coatings can add functional properties such as improved magnetic or electric response.

Energy Harvesting:

Energy Harvesting Devices: The multiferroic nature of cerium bismuth ferrite makes it a candidate for use in energy harvesting devices, where it can convert ambient energy (such as vibrations or thermal gradients) into electrical energy.

Catalysis:

Catalytic Reactions: While less common, cerium bismuth ferrite may be used in catalytic applications, particularly those involving reactions where its unique electronic or magnetic properties can enhance catalyst performance.

 

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