Lanthanum Praseodymium Calcium Manganate Sputtering Targets
Lanthanum Praseodymium Calcium Manganate Sputtering Targets
| Lanthanum Praseodymium Calcium Manganate Sputtering Targets | |
| Product No | NRE-43235 |
| CAS No. | NA |
| Formula | La(1-x-y)PrxCayMnO3 |
| 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 |
Lanthanum Praseodymium Calcium Manganate Sputtering Targets
Introduction
Lanthanum praseodymium calcium manganate (LPCMO) is a complex oxide material known for its unique electronic and magnetic properties. This perovskite-structured compound exhibits intriguing phenomena, such as high-temperature superconductivity, colossal magnetoresistance, and spin-dependent transport. Sputtering targets made from LPCMO are essential for depositing high-quality thin films used in various advanced applications.
Applications
Spintronic Devices:
LPCMO’s spin-dependent transport properties make it suitable for spintronic applications, where information is processed using both the charge and spin of electrons. This can lead to more efficient data storage and processing technologies.
High-Temperature Superconductors:
LPCMO exhibits superconducting properties at elevated temperatures, making it relevant for applications in power transmission, magnetic levitation, and quantum computing.
Magnetoresistive Sensors:
The colossal magnetoresistance effect in LPCMO can be harnessed in sensors that detect magnetic fields, used in various industrial and consumer electronics applications.
Multiferroic Materials:
LPCMO can exhibit both ferromagnetic and ferroelectric properties, making it a candidate for multiferroic applications, which could lead to innovative devices in memory storage and data manipulation.
Thin Film Coatings:
The material is also utilized in creating thin film coatings that enhance the performance of electronic components, including capacitors and inductors, by improving their magnetic and electrical properties.
Thermoelectric Devices:
Due to its thermal and electrical conductivity properties, LPCMO may find applications in thermoelectric devices, which convert temperature differences into electrical energy.
