The magnetostriction ${\displaystyle \lambda }$  characterizes the shape change of a ferromagnetic material during magnetization, whereas the inverse magnetostrictive effect characterizes the change of sample magnetization ${\displaystyle M}$ (for given magnetizing field strength ${\displaystyle H}$ ) when mechanical stresses ${\displaystyle \sigma }$  are applied to the sample.^[1]

Qualitative explanation of magnetoelastic effect

Under a given uni-axial mechanical stress ${\displaystyle \sigma }$ , the flux density ${\displaystyle B}$  for a given magnetizing field strength ${\displaystyle H}$  may increase or decrease. The way in which a material responds to stresses depends on its saturation magnetostriction ${\displaystyle \lambda _{s}}$ . For this analysis, compressive stresses ${\displaystyle \sigma }$  are considered as negative, whereas tensile stresses are positive.
According to Le Chatelier's principle:

${\displaystyle \left({\frac {d\lambda }{dH}}\right)_{\sigma }=\left({\frac {dB}{d\sigma }}\right)_{H}}$ 

This means, that when the product ${\displaystyle \sigma \lambda _{s}}$  is positive, the flux density ${\displaystyle B}$  increases under stress. On the other hand, when the product ${\displaystyle \sigma \lambda _{s}}$  is negative, the flux density ${\displaystyle B}$  decreases under stress. This effect was confirmed experimentally.^[2]

Quantitative explanation of magnetoelastic effect

In the case of a single stress ${\displaystyle \sigma }$  acting upon a single magnetic domain, the magnetic strain energy density ${\displaystyle E_{\sigma }}$  can be expressed as:^[1]

${\displaystyle E_{\sigma }={\frac {3}{2}}\lambda _{s}\sigma \sin ^{2}(\theta )}$ 

where ${\displaystyle \lambda _{s}}$  is the magnetostrictive expansion at saturation, and ${\displaystyle \theta }$  is the angle between the saturation magnetization and the stress's direction. When ${\displaystyle \lambda _{s}}$  and ${\displaystyle \sigma }$  are both positive (like in iron under tension), the energy is minimum for ${\displaystyle \theta }$  = 0, i.e. when tension is aligned with the saturation magnetization. Consequently, the magnetization is increased by tension.

Magnetoelastic effect in a single crystal

In fact, magnetostriction is more complex and depends on the direction of the crystal axes. In iron, the [100] axes are the directions of easy magnetization, while there is little magnetization along the [111] directions (unless the magnetization becomes close to the saturation magnetization, leading to the change of the domain orientation from [111] to [100]). This magnetic anisotropy pushed authors to define two independent longitudinal magnetostrictions ${\displaystyle \lambda _{100}}$  and ${\displaystyle \lambda _{111}}$ .

• In cubic materials, the magnetostriction along any axis can be defined by a known linear combination of these two constants. For instance, the elongation along [110] is a linear combination of ${\displaystyle \lambda _{100}}$  and ${\displaystyle \lambda _{111}}$ .
• Under assumptions of isotropic magnetostriction (i.e. domain magnetization is the same in any crystallographic directions), then ${\displaystyle \lambda _{100}=\lambda _{111}=\lambda }$  and the linear dependence between the elastic energy and the stress is conserved, ${\displaystyle E_{\sigma }={\frac {3}{2}}\lambda \sigma (\alpha _{1}\gamma _{1}+\alpha _{2}\gamma _{2}+\alpha _{3}\gamma _{3})^{2}}$ . Here, ${\displaystyle \alpha _{1}}$ , ${\displaystyle \alpha _{2}}$  and ${\displaystyle \alpha _{3}}$  are the direction cosines of the domain magnetization, and ${\displaystyle \gamma _{1}}$ , ${\displaystyle \gamma _{2}}$ ,${\displaystyle \gamma _{3}}$  those of the bond directions, towards the crystallographic directions.

Method suitable for effective testing of magnetoelastic effect in magnetic materials should fulfill the following requirements:^[3]

• magnetic circuit of the tested sample should be closed. Open magnetic circuit causes demagnetization, which reduces magnetoelastic effect and complicates its analysis.
• distribution of stresses should be uniform. Value and direction of stresses should be known.
• there should be the possibility of making the magnetizing and sensing windings on the sample - necessary to measure magnetic hysteresis loop under mechanical stresses.

Following testing methods were developed:

• tensile stresses applied to the strip of magnetic material in the shape of a ribbon.^[4] Disadvantage: open magnetic circuit of the tested sample.
• tensile or compressive stresses applied to the frame-shaped sample.^[5] Disadvantage: only bulk materials may be tested. No stresses in the joints of sample columns.
• compressive stresses applied to the ring core in the sideways direction.^[6] Disadvantage: non-uniform stresses distribution in the core .
• tensile or compressive stresses applied axially to the ring sample.^[7] Disadvantage: stresses are perpendicular to the magnetizing field.

Magnetoelastic effect can be used in development of force sensors.^[8][9] This effect was used for sensors:

• in civil engineering.^[4]
• for monitoring of large diesel engines in locomotives.^[10]
• for monitoring of ball valves.^[10]
• for biomedical monitoring.^[11]

Inverse magnetoelastic effects have to be also considered as a side effect of accidental or intentional application of mechanical stresses to the magnetic core of inductive component, e.g. fluxgates or generator/motor stators when installed with interference fits.^[12]

• Magnetostriction
• Magnetocrystalline anisotropy