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Results for DC.creator="A." AND DC.creator="S." AND DC.creator="Borovik-Romanov" in section 1.5.9 of volume D |
The difference between the magnetic anisotropies at zero strain and zero stress
International Tables for Crystallography (2013). Vol. D, Section 1.5.9.3, p. 148 [ doi:10.1107/97809553602060000904 ]
... at zero strain and zero stress The spontaneous magnetostriction makes a contribution to the magnetic anisotropy (especially in crystals with a cubic prototype). Therefore, to find the full expression for ... be written as As an example, for the ferromagnets with a cubic prototype this equation may be written asThe coefficients ...
Magnetostriction in an external magnetic field
International Tables for Crystallography (2013). Vol. D, Section 1.5.9.2, pp. 147-148 [ doi:10.1107/97809553602060000904 ]
... field There are three reasons for the magnetostriction arising in a magnetic field: (a) the transfer of the crystal into a single-domain state if the magnetic field is directed ...
Spontaneous magnetostriction
International Tables for Crystallography (2013). Vol. D, Section 1.5.9.1, pp. 145-147 [ doi:10.1107/97809553602060000904 ]
... section, we shall assume that the crystal under consideration undergoes a phase transition from the paramagnetic state into a magnetically ordered state. The latter is a single-domain state with the magnetization (or the antiferromagnetic ...
Magnetostriction
International Tables for Crystallography (2013). Vol. D, Section 1.5.9, pp. 145-148 [ doi:10.1107/97809553602060000904 ]
... The transition to an ordered magnetic state is accompanied by a spontaneous distortion of the lattice, which is denoted spontaneous magnetostriction. ... into account. The magnetoelastic energy includes both an exchange and a relativistic part. In some ferromagnets that are cubic in the ... cubic symmetry. Thus the exchange part of satisfies the relationsSuch a form of the magnetoelastic energy gives rise to an ...
International Tables for Crystallography (2013). Vol. D, Section 1.5.9.3, p. 148 [ doi:10.1107/97809553602060000904 ]
... at zero strain and zero stress The spontaneous magnetostriction makes a contribution to the magnetic anisotropy (especially in crystals with a cubic prototype). Therefore, to find the full expression for ... be written as As an example, for the ferromagnets with a cubic prototype this equation may be written asThe coefficients ...
Magnetostriction in an external magnetic field
International Tables for Crystallography (2013). Vol. D, Section 1.5.9.2, pp. 147-148 [ doi:10.1107/97809553602060000904 ]
... field There are three reasons for the magnetostriction arising in a magnetic field: (a) the transfer of the crystal into a single-domain state if the magnetic field is directed ...
Spontaneous magnetostriction
International Tables for Crystallography (2013). Vol. D, Section 1.5.9.1, pp. 145-147 [ doi:10.1107/97809553602060000904 ]
... section, we shall assume that the crystal under consideration undergoes a phase transition from the paramagnetic state into a magnetically ordered state. The latter is a single-domain state with the magnetization (or the antiferromagnetic ...
Magnetostriction
International Tables for Crystallography (2013). Vol. D, Section 1.5.9, pp. 145-148 [ doi:10.1107/97809553602060000904 ]
... The transition to an ordered magnetic state is accompanied by a spontaneous distortion of the lattice, which is denoted spontaneous magnetostriction. ... into account. The magnetoelastic energy includes both an exchange and a relativistic part. In some ferromagnets that are cubic in the ... cubic symmetry. Thus the exchange part of satisfies the relationsSuch a form of the magnetoelastic energy gives rise to an ...
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