Recently, researchers have detected a striking novel behaviour in a class of magnetic material known as altermagnets.

What are Altermagnets?

• Altermagnets are a newly discovered class of magnetic materials that combine the properties of both ferromagnets (which have external magnetism) and antiferromagnets (which cancel out their own magnetism).

Key Properties of Altermagnets

• Dual Nature: Altermagnets embody a unique blend of antiferromagnetic (no external magnetization) and ferromagnetic properties (electron spin splitting), allowing for controlled electron spin without external magnetic signatures.
• Spin Polarization: Altermagnets display spin polarization both in real space (atomic arrangement) and in momentum space (distribution of electron spins), enabling fine control over spin-related phenomena.
• High Spin Splitting: In materials like CrSb (Chromium Antimonide), electron spin energy levels differ significantly—up to 30 times room temperature.
• No External Magnetization: Despite their internal magnetic ordering, altermagnets show no net external magnetic moment, distinguishing them from traditional magnets.
• Thermal Stability: Altermagnets like CrSb retain their magnetic properties even at temperatures twice that of room temperature, making them viable for use in industrial and high-temperature applications.

Chromium Antimonide (CrSb) as a Promising Candidate

• Features:
  • CrSb is metallic and demonstrates the largest altermagnetic spin-splitting (30× room temperature).
  • It exhibits a unique direction-dependent conduction polarity (DDCP), displaying n-type behavior along the crystal layers and p-type behavior across the layers, a first in known magnetic materials.
  • Single-Crystalline Purity: CrSb’s high-quality single crystals allow precise measurement of its unique anisotropic conduction properties.

Applications of Altermagnets

• Spintronics: Altermagnets enable manipulation of electron spin instead of charge, which can be used for ultra-fast, low-energy memory devices and high-performance data storage.
• Compact Electronics: Their ability to function as both p-type and n-type materials eliminates the need for separate materials or doping, simplifying the design and reducing costs.
• Thermoelectrics: Altermagnets, like CrSb, enhance energy conversion efficiency, potentially improving power generation systems.
• Simplified Manufacturing: By obviating the need for heterostructures or junctions, altermagnets make the manufacturing process simpler and more cost-effective.
• Sustainability: CrSb is made from earth-abundant, non-toxic elements, making it an environmentally friendly option for the future of electronics.

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