Many important applications of pola

Many important applications of polarized light involve materials that display optical activity. A
material is said to be optically active if it rotates the plane of polarization of any light transmitted through
the material. The angle through which the light is rotated by a specific material depends on the length of
the path through the material and on concentration if the material is in solution. One optically active
material is a solution of the common sugar dextrose. However rotations of polarized light are not only
limited to optically active materials, but also including some optically inactive materials exposed to high
magnetic field. In magnetized medium the refractive indices for right- and left-handed circularly
polarized light are different. This effect manifests itself in a rotation of the plane of polarization of linearly
polarized light. This observable fact is called magnetooptic effect.
Magnetooptic effects are those effects in which the optical properties of certain materials are
affected by applied magnetic fields or the material’s own magnetization. Magnetooptic effects occur in
gases, liquids, and solids. In general, solids exhibit the strongest magnetooptic effects, liquids exhibit
weaker effects, and gases exhibit the weakest effects (Weber, 1995). The first magnetooptic effect was
discovered by Michael Faraday in 1845 and is now commonly known as the Faraday effect. This
phenomenon occurs when linearly polarized light propagates through a transparent isotropic materials
exposed to a magnetic field aligned parallel to the direction of propagation of the light. Under these
conditions, the plane of polarization rotates by an amount proportional to the applied magnetic field. This
action is known as Faraday rotation. One of the most important properties of Faraday rotation is its
nonreciprocal behavior. If light makes two opposite passes through a magnetooptic material, the
Faraday rotation does not cancel but rather doubles (Weber, 1995; Zvezdin and Kotov, 1997). This
property distinguishes the effect from optical activity in which reflecting the light back through the
material cancels the polarization rotation observed in a single pass through the material.
Later on, in 1854, Verdet found that the angle of rotation θ is proportional to the length l of the
path in the material and the magnetic flux density H . This rotation may be expressed by relation
θ = VHl , (1)
where V is the Verdet constant for the material. The Verdet constant is defined as the rotation per unit
path, per unit field strength. It depends upon the properties of the medium, frequency of light, and the
temperature. In fiber optic magnetic sensors based on Faraday effect, the Verdet constant is a measure
of the strength of the Faraday effect in the fiber (Udd, 1991).
Solid magnetooptic materials are the most commonly used today for sensor applications. Solids
are classified into the class of diamagnetic, paramagnetic, ferromagnetic, antiferromagnetic, and
ferrimagnetic materials. Diamagnetic materials generally offer lower Verdet constant, hence lower
measurement resolution, but they have better environmental stability, particularly temperature stability. On
the other hand, paramagnetic and ferromagnetic materials are less environmentally stable but generally
have much higher Verdet constant. For that reason, diamagnetic materials, especially diamagnetic
glasses in bulk and fiber form, are commonly chosen as the sensing element in high stability Faraday
effect sensors (Martinez et al., 2005; Williams et al., 1991). Therefore, the purpose of this present work is
to measure the Verdet constant for the diamagnetic glass using Faraday effect and compare it to a
theoretically calculated value.

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