In condensed matter physics, altermagnetism is a type of persistent magnetic state in ideal crystals. [1] [2] [3] [4] [5] Altermagnetic structures are collinear and crystal-symmetry compensated, resulting in zero net magnetisation. [1] [5] [6] [7] Unlike in an ordinary collinear antiferromagnet, another magnetic state with zero net magnetization, the electronic bands in an altermagnet are not Kramers degenerate, but instead depend on the wavevector in a spin-dependent way. [1] Related to this feature, key experimental observations were published in 2024. [8] [9] It has been speculated that altermagnetism may have applications in the field of spintronics. [6] [10]
In altermagnetic materials, atoms form a regular pattern with alternating spin and spatial orientation at adjacent magnetic sites in the crystal. [5] [7]
Atoms with opposite magnetic moment are in altermagnets coupled by crystal rotation or mirror symmetry. [1] [5] [6] [7] [8] [9] The spatial orientation of magnetic atoms may originate from the surrounding cages of non-magnetic atoms. [7] [11] The opposite spin sublattices in altermagnetic manganese telluride (MnTe) are related by spin rotation combined with six-fold crystal rotation and half-unit cell translation. [7] [8] In altermagnetic ruthenium dioxide (RuO2), the opposite spin sublattices are related by four-fold crystal rotation. [7] [9]
One of the distinctive features of altermagnets is a specifically spin-split band structure [7] which was first experimentally observed in work that was published in 2024. [8] Altermagnetic band structure breaks time-reversal symmetry, [7] [11] Eks=E-ks (E is energy, k wavevector and s spin) as in ferromagnets, however unlike in ferromagnets, it does not generate net magnetization. The altermagnetic spin polarisation alternates in wavevector space and forms characteristic 2, 4, or 6 spin-degenerate nodes, respectively, which correspond to d-, g, or i-wave order parameters. [7] A d-wave altermagnet can be regarded as the magnetic counterpart of a d-wave superconductor. [12]
The altermagnetic spin polarization in band structure (energy–wavevector diagram) is collinear and does not break inversion symmetry. [7] The altermagnetic spin splitting is even in wavector, i.e. (kx2-ky2)sz. [7] [8] It is thus also distinct from noncollinear Rasba or Dresselhaus spin texture which break inversion symmetry in noncentrosymmetric nonmagnetic or antiferromagnetic materials due to the spin-orbit coupling. Unconventional time-reversal symmetry breaking, giant ~1eV spin splitting and anomalous Hall effect was first theoretically predicted [11] and experimentally confirmed [13] in RuO2.
Direct experimental evidence of altermagnetic band structure in semiconducting MnTe and metallic RuO2 was first published in 2024. [8] [9] Many more materials are predicted to be altermagnets – ranging from insulators, semiconductors, and metals to superconductors. [6] [7] Altermagnetism was predicted in 3d and 2d materials [3] [6] with both light as well as heavy elements and can be found in nonrelativistic as well as relativistic band structures. [7] [8] [11]
Altermagnets exhibit an unusual combination of ferromagnetic and antiferromagnetic properties, which remarkably more closely resemble those of ferromagnets. [1] [5] [6] [7] Hallmarks of altermagnetic materials such as the anomalous Hall effect [11] have been observed before [13] [14] (but this effect occurs also in other magnetically compensated systems such as non-collinear antiferromagnets [15]). Altermagnets also exhibit unique properties such as anomalous and spin currents that can change sign as the crystal rotates. [16]
In condensed matter physics, altermagnetism is a type of persistent magnetic state in ideal crystals. [1] [2] [3] [4] [5] Altermagnetic structures are collinear and crystal-symmetry compensated, resulting in zero net magnetisation. [1] [5] [6] [7] Unlike in an ordinary collinear antiferromagnet, another magnetic state with zero net magnetization, the electronic bands in an altermagnet are not Kramers degenerate, but instead depend on the wavevector in a spin-dependent way. [1] Related to this feature, key experimental observations were published in 2024. [8] [9] It has been speculated that altermagnetism may have applications in the field of spintronics. [6] [10]
In altermagnetic materials, atoms form a regular pattern with alternating spin and spatial orientation at adjacent magnetic sites in the crystal. [5] [7]
Atoms with opposite magnetic moment are in altermagnets coupled by crystal rotation or mirror symmetry. [1] [5] [6] [7] [8] [9] The spatial orientation of magnetic atoms may originate from the surrounding cages of non-magnetic atoms. [7] [11] The opposite spin sublattices in altermagnetic manganese telluride (MnTe) are related by spin rotation combined with six-fold crystal rotation and half-unit cell translation. [7] [8] In altermagnetic ruthenium dioxide (RuO2), the opposite spin sublattices are related by four-fold crystal rotation. [7] [9]
One of the distinctive features of altermagnets is a specifically spin-split band structure [7] which was first experimentally observed in work that was published in 2024. [8] Altermagnetic band structure breaks time-reversal symmetry, [7] [11] Eks=E-ks (E is energy, k wavevector and s spin) as in ferromagnets, however unlike in ferromagnets, it does not generate net magnetization. The altermagnetic spin polarisation alternates in wavevector space and forms characteristic 2, 4, or 6 spin-degenerate nodes, respectively, which correspond to d-, g, or i-wave order parameters. [7] A d-wave altermagnet can be regarded as the magnetic counterpart of a d-wave superconductor. [12]
The altermagnetic spin polarization in band structure (energy–wavevector diagram) is collinear and does not break inversion symmetry. [7] The altermagnetic spin splitting is even in wavector, i.e. (kx2-ky2)sz. [7] [8] It is thus also distinct from noncollinear Rasba or Dresselhaus spin texture which break inversion symmetry in noncentrosymmetric nonmagnetic or antiferromagnetic materials due to the spin-orbit coupling. Unconventional time-reversal symmetry breaking, giant ~1eV spin splitting and anomalous Hall effect was first theoretically predicted [11] and experimentally confirmed [13] in RuO2.
Direct experimental evidence of altermagnetic band structure in semiconducting MnTe and metallic RuO2 was first published in 2024. [8] [9] Many more materials are predicted to be altermagnets – ranging from insulators, semiconductors, and metals to superconductors. [6] [7] Altermagnetism was predicted in 3d and 2d materials [3] [6] with both light as well as heavy elements and can be found in nonrelativistic as well as relativistic band structures. [7] [8] [11]
Altermagnets exhibit an unusual combination of ferromagnetic and antiferromagnetic properties, which remarkably more closely resemble those of ferromagnets. [1] [5] [6] [7] Hallmarks of altermagnetic materials such as the anomalous Hall effect [11] have been observed before [13] [14] (but this effect occurs also in other magnetically compensated systems such as non-collinear antiferromagnets [15]). Altermagnets also exhibit unique properties such as anomalous and spin currents that can change sign as the crystal rotates. [16]