Voigt effect explained

The Voigt effect is a magneto-optical phenomenon which rotates and elliptizes linearly polarised light sent into an optically active medium.^[1] The effect is named after the German scientist Woldemar Voigt who discovered it in vapors. Unlike many other magneto-optical effects such as the Kerr or Faraday effect which are linearly proportional to the magnetization (or to the applied magnetic field for a non magnetized material), the Voigt effect is proportional to the square of the magnetization (or square of the magnetic field) and can be seen experimentally at normal incidence. There are also other denominations for this effect, used interchangeably in the modern scientific literature: the Cotton–Mouton effect (in reference to French scientists Aimé Cotton and Henri Mouton who discovered the same effect in liquids a few years later) and magnetic-linear birefringence, with the latter reflecting the physical meaning of the effect.

For an electromagnetic incident wave linearly polarized

and an in-plane polarized sample , the expression of the rotation in reflection geometry is is:$$\backslash delta\; \backslash beta\_r\; =\; \backslash frac\backslash sin[2(\backslash phi-\backslash beta)]$$and in the transmission geometry:$$\backslash delta\; \backslash beta\_t\; =\; \backslash frac,$$where $\backslash Delta\; n\; =\; \backslash frac$ is the difference of refraction indices depending on the Voigt parameter (same as for the Kerr effect), the material refraction indices and the parameter responsible of the Voigt effect and so proportional to the or in the case of a paramagnetic material.

Detailed calculation and an illustration are given in sections below.

Theory

As with the other magneto-optical effects, the theory is developed in a standard way with the use of an effective dielectric tensor from which one calculates systems eigenvalues and eigenvectors. As usual, from this tensor, magneto-optical phenomena are described mainly by the off-diagonal elements.

Here, one considers an incident polarisation propagating in the z direction:

the electric field and a homogenously in-plane magnetized sample where is counted from the [100] crystallographic direction. The aim is to calculate where is the rotation of polarization due to the coupling of the light with the magnetization. Let us notice that is experimentally a small quantity of the order of mrad. is the reduced magnetization vector defined by , the magnetization at saturation. We emphasized with the fact that it is because the light propagation vector is perpendicular to the magnetization plane that it is possible to see the Voigt effect.

Dielectric tensor

Following the notation of Hubert, the generalized dielectric cubic tensor

take the following form:where is the material dielectric constant, the Voigt parameter, and two cubic constants describing magneto-optical effect depending on . is the reduce . Calculation is made in the spherical approximation with . At the present moment, there is no evidence that this approximation is not valid, as the observation of Voigt effect is rare because it is extremely small with respect to the Kerr effect.

Eigenvalues and eigenvectors

To calculate the eigenvalues and eigenvectors, we consider the propagation equation derived from the Maxwell equations, with the convention

:$$(2)\; \backslash qquad\; n^2\; \backslash vec\; -\; \backslash vec(\backslash vec\backslash cdot\backslash vec)\; =\; \backslash varepsilon\; \backslash vec$$

When the magnetization is perpendicular to the propagation wavevector, on the contrary to the Kerr effect,

may have all his three components equals to zero making calculations rather more complicated and making Fresnels equations no longer valid. A way to simplify the problem consists to use the electric field displacement vector . Since and we have . The inconvenient is to deal with the inverse dielectric tensor which may be complicated to handle. Here calculation is made in the general case which is complicated mathematically to handle, however one can follow easily the demonstration by considering .

Eigenvalues and eigenvectors are found by solving the propagation equation on

which gives the following system of equation:$$(3)\backslash quad\; \backslash begin\; (\backslash varepsilon\_^-\backslash frac)\; D\_x\; +\; \backslash epsilon\_^\; D\_y\; =\; 0\; \backslash \backslash \; \backslash \backslash \backslash varepsilon\_^\; D\_x\; +\; (\backslash varepsilon\_^\; -\; \backslash frac)\; D\_y\; =\; 0\backslash end$$where represents the inverse element of the dielectric tensor , and . After a straightforward calculation of the system's determinant, one has to make a development on 2nd order in and first order of . This led to the two eigenvalues corresponding the two refraction indices:$$n\_^2\; =\; \backslash varepsilon+B\_1$$$$n\_^2\; =\; \backslash varepsilon(1-Q^2)$$

The corresponding eigenvectors for

and for are:

$$(4)\; \backslash qquad\; \backslash vec\_=\backslash begin\backslash cos(\backslash phi)\backslash \backslash \backslash sin(\backslash phi)\backslash \backslash 0\backslash end\; \backslash qquad\; \backslash vec\_=\backslash begin-\backslash sin(\backslash phi)\backslash \backslash \backslash cos(\backslash phi)\backslash \backslash 0\backslash end\; \backslash qquad$$

\vec_= \varepsilon^ \vec_=\begin\frac\\\frac\\0\end \qquad \vec_= \varepsilon^ \vec_=\begin\frac\\\frac\\\frac\end

Reflection geometry

Continuity relation

Knowing the eigenvectors and eigenvalues inside the material, one have to calculate

the reflected electromagnetic vector usually detected in experiments. We use the continuity equations for and where is the induction defined from Maxwell's equations by $\backslash vec\; \backslash times\; \backslash vec\; =\; \backslash frac\; \backslash frac$. Inside the medium, the electromagnetic field is decomposed on the derived eigenvectors . The system of equation to solve is:$$(5)\backslash quad\; \backslash begin\backslash alpha\; \backslash Big(\backslash frac\backslash Big)+\backslash beta\; \backslash Big(\backslash frac\backslash Big)\; +\; E\_\; =\; E\_\backslash \backslash \; \backslash \backslash \backslash alpha\; \backslash Big(\backslash frac\backslash Big)\; +\backslash beta\; \backslash Big(\backslash frac\backslash Big)\; +\; E\_\; =\; E\_\backslash \backslash \; \backslash \backslash \backslash alpha\; E\_+\backslash beta\; E\_-E\_\; =\; E\_\; \backslash \backslash \; \backslash \backslash \backslash alpha\; E\_+\backslash beta\; E\_-E\_\; =\; E\_\; \backslash end$$

The solution of this system of equation are:$$(6)\; \backslash quad\; E\_\; =\; E\_0\; \backslash frac$$$$(7)\; \backslash quad\; E\_\; =\; E\_0\; \backslash frac$$

Calculation of rotation angle

The rotation angle

and the ellipticity angle are defined from the ratio with the two following formulae:$$(8)\; \backslash quad\; \backslash tan\; 2\; \backslash delta\; \backslash beta\; =\; \backslash frac\; \backslash qquad\; (9)\; \backslash quad\; \backslash sin(2\; \backslash psi\_K)\; =\; \backslash frac,$$where and represent the real and imaginary part of . Using the two previously calculated components, one obtains:$$(10)\; \backslash qquad\; \backslash chi\; =\backslash frac\backslash frac+\backslash tan(\backslash beta).$$ This gives for the Voigt rotation:$$(11)\; \backslash qquad\; \backslash delta\; \backslash beta\; =\; \backslash operatorname\backslash left[\backslash frac\{B\_1+n\_0^2\; Q^\{2\}\}\{2\; n\_0\; (n\_0^2-1)\}\backslash right]\; \backslash sin[2(\backslash phi-\backslash beta)],$$ which can also be rewritten in the case of , , and real:$$(12)\; \backslash quad\; \backslash delta\; \backslash beta\; =\; \backslash frac\backslash sin[2(\backslash phi-\backslash beta)],$$ where } is the difference of refraction indices. Consequently, one obtains something proportional to and which depends on the incident linear polarisation. For proper no Voigt rotation can be observed. is proportional to the square of the magnetization since and .

Transmission geometry

The calculation of the rotation of the Voigt effect in transmission is in principle equivalent to the one of the Faraday effect. In practice, this configuration is not used in general for ferromagnetic samples since the absorption length is weak in this kind of material. However, the use of transmission geometry is more common for paramagnetic liquid or cristal where the light can travel easily inside the material.

The calculation for a paramagnetic material is exactly the same with respect to a ferromagnetic one, except that the magnetization is replaced by a field

( in or ). For convenience, the field will be added at the end of calculation in the magneto-optical parameters.

Consider the transmitted electromagnetic waves

propagating in a medium of length L. From equation (5), one obtains for and :$$\backslash alpha\; =\; \backslash frac$$$$\backslash beta\; =\; \backslash frac$$At the position, the expression of is:$$(13)\backslash quad\; \backslash vec\_=\; e^\; \backslash Big[\backslash alpha\; \backslash vec\{E\}\_\{\backslash parallel\}\; e^\{i\; \backslash frac\{\backslash omega\; \backslash Delta\; n\; L\}\{c\}\}+\; \backslash beta\; \backslash vec\{E\}\_\{\backslash perp\}\; e^\{-i\; \backslash frac\{\backslash omega\; \backslash Delta\; n\; L\}\{c\}\}\backslash Big]$$where and are the eigenvectors previously calculated, and is the difference for the two refraction indices. The rotation is then calculated from the ratio , with development in first order in and second order in . This gives:$$(14)\; \backslash quad\; \backslash chi\; =\; \backslash frac\; =\; \backslash frac$$

Again we obtain something proportional to

and , the light propagation length. Let us notice that is proportional to in the same way with respect to the geometry in reflexion for the magnetization. In order to extract the Voigt rotation, we consider , and real. Then we have to calculate the real part of (14). The resulting expression is then inserted in (8). In the approximation of no absorption, one obtains for the Voigt rotation in transmission geometry:$$(15)\; \backslash quad\; \backslash delta\; \backslash beta\; =\; (\backslash mu\_0\; H)^2\; \backslash frac$$

Illustration of Voigt effect in GaMnAs

As an illustration of the application of the Voigt effect, we give an example in the magnetic semiconductor where a large Voigt effect was observed.^[2] At low temperatures (in general for

) for a material with an in-plane magnetization, exhibits a biaxial anisotropy with the magnetization aligned along (or close to) <100> directions.

A typical hysteresis cycle containing the Voigt effect is shown in figure 1. This cycle was obtained by sending a linearly polarized light along the [110] direction with an incident angle of approximately 3° (more details can be found in ^[3]), and measuring the rotation due to magneto-optical effects of the reflected light beam. In contrast to the common longitudinal/polar Kerr effect, the hysteresis cycle is even with respect to the magnetization, which is a signature of the Voigt effect. This cycle was obtained with a light incidence very close to normal, and it also exhibits a small odd part; a correct treatment has to be carried out in order to extract the symmetric part of the hysteresis corresponding to the Voigt effect, and the asymmetric part corresponding to the longitudinal Kerr effect.

In the case of the hysteresis presented here, the field was applied along the [1-10] direction. The switching mechanism is as follows:

1. We start with a high negative field and the magnetization is close to the [-1-10] direction at position 1.
2. The magnetic field is decreasing leading to a coherent magnetization rotation from 1 to 2
3. At positive field, the magnetization switch brutally from 2 to 3 by nucleation and propagation of magnetic domains giving a first coercive field named here

1. The magnetization stay close to the state 3 while rotating coherently to the state 4, closer from the applied field direction.
2. Again the magnetization switches abruptly from 4 to 5 by nucleation and propagation of magnetic domains. This switching is due to the fact that the final equilibrium position is closer from the state 5 with respect to the state 4 (and so his magnetic energy is lower). This gives another coercive field named

1. Finally the magnetization rotates coherently from the state 5 to the state 6.

The simulation of this scenario is given in the figure 2, with$$\backslash operatorname\backslash left[\backslash frac\{B\_1+n\_0^2\; Q^\{2\}\}\{2\; n\_0\; (n\_0^2-1)\}\backslash right]\; P\_\backslash text\; =\; 0.5\backslash ,\backslash mathrm.$$As one can see, the simulated hysteresis is qualitatively the same with respect to the experimental one. Notice that the amplitude at

or are approximately twice of

See also

• Atomic line filter
• Cotton–Mouton effect
• Faraday effect

Further reading

• Zhao, Zhong-Quan. Excited state atomic line filters. Retrieved March 26, 2006.

Notes and References

1. .
2. Kimel. Observation of Giant Magnetic Linear Dichroism in (Ga,Mn)As . Physical Review Letters. 94 . 22. 2005. 227203 . 10.1103/physrevlett.94.227203 . 2005PhRvL..94v7203K . 16090433 . 2066/32798 . 164047 . free. .
3. Shihab. Systematic study of the spin stiffness dependence on Phosphorus alloying in (Ga,Mn)As ferromagnetic semiconductor . Applied Physics Letters . 106. 14 . 2015 . 142408 . 10.1063/1.4917423 . 2015ApPhL.106n2408S .