Pleochroism is when a mineral changes color as it is rotated relative to the polarizer in plane polarized light.  This effectively shows how the color properties of the mineral vary with direction within the crystal structure.

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Some minerals that are darkly colored in hand sample will also appear to have color in thin section, even though the rock slices in thin sections are typically only 30 micrometers thick.  Sometimes the color of a mineral in plane polarized light can aid in identification (see examples in the figures below) because it is characteristic for a specific mineral.

For example, here is a cluster of quartz crystals demonstrating 6-sided prismatic form in hand sample: https://skfb.ly/6FnOZ

In this section, we explore properties that can be observed for minerals under plane polarized light, when only the lower polarizer is inserted into the polarizing light microscope.

Mineral relief is related to the refractive index of the mineral.  If a mineral has a refractive index that is much higher or lower than the surrounding materials, it will stand out relative to the surrounding material and will have thick or distinct .   In a grain mount, the surrounding material is likely to be epoxy or mineral oil.  In a thin section, the surrounding material will be adjacent minerals.  For the purposes of identifying minerals in thin section, it is sufficient to describe relief as high, intermediate, or low.

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Figure 2.6.9. Becke lines move into the material with the higher refractive index when the stage is lowered.  In these figures, “B” indicates the location of the Becke lines as the stage is lowered.  The Becke lines appear above the sample, because after the stage is lowered, the microscope is focused on a plane above the sample.

In practice, it is not necessary to measure the refractive index of the mineral or the surrounding media directly.  Instead, we look at the thickness of the grain boundaries around the mineral and how the mineral appears to either stand out or blend in with surrounding media or minerals.  Examples of high, intermediate, and low relief are shown in Figure 2.6.8.

Figure 2.6.1. Some techniques that use plane polarized light.  Earth Optics Videos, Creative Commons Attribution License.

Most of the time, however, crystals in igneous and metamorphic rocks do not grow freely.  They run up against other crystals that have already formed, or ones that are growing simultaneously.  This prevents them from being their true shape.

This video gives an overview of some of the important properties of minerals in plane polarized light.  These properties are explored in more detail in the sections below.

Figure 2.6.8. High, intermediate, and low relief minerals (click on hotspots to identify). Image taken at 25x total magnification.

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2.6 Properties Under Plane Polarized Light Copyright © by Elizabeth A. Johnson; Juhong Christie Liu; and Mark Peale is licensed under a Creative Commons Attribution 4.0 International License, except where otherwise noted.

The relative refractive indices of two materials (minerals, glass, or epoxy) adjacent to each other in a thin section can be determined using Becke lines (pronounced beck-ee).  The procedure for checking Becke lines is summarized in the video (Figure 2.6.1) at the start of this chapter. When the stage is lowered in plane polarized light, the bright Becke line will either move into or out of a mineral.  If the Becke line moves into the mineral grain, that mineral has a higher index of refraction and higher relief.  If the Becke line moves out of the grain, the mineral has a lower index of refraction and lower relief.  These properties are summarized in Figure 2.6.9 below.

Figure 2.6.1. Earth Optics Video 1: Plane Polarized Light. Earth Optics Videos, Creative Commons Attribution License. https://youtu.be/ahS5KlXqQXc

Transparent minerals transmit light, whereas opaque minerals block light from passing through them.  Because most student microscopes only have an option to look at minerals under transmitted light, this means that all opaque minerals will appear dark in plane polarized light.  Some very small opaque minerals, or minerals within a group that contains both opaque and transparent minerals (such as the spinel group) may let some light through and could appear to have some color.

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The terms euhedral, subhedral, and anhedral are used to describe how well a mineral displays its ideal form.  Euhedral minerals show perfect or nearly perfect crystal faces.  Subhedral minerals are rounded but still show the general characteristic shape of that mineral.  Anhedral crystals are completely irregular in shape and do not resemble the characteristic form for that mineral.

Question 2.6.1. The two figures above show magnetite (Figure 2.6.2) and garnet (Figure 2.6.3) in both plane polarized light (PPL) and cross polarized light (XPL).  Based upon the definition of opaque minerals, which of these are opaque? Why?

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Mineral form refers to the ideal crystal form, or the shape a mineral takes when left to grow without barriers or interference with other nearby mineral grains.  Minerals take characteristic shapes according to their crystal symmetries and structures.

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In igneous rocks, mineral shape helps us determine the crystallization order from the magma and allows us to connect observations in thin section to thermodynamic models.

The refractive index of a mineral characterizes the relationship between the speed of light in a vacuum and the speed of light in that material.  Refractive index is discussed in Section 2.3 Light and Optics.  The refractive index of a mineral can vary according to crystal orientation.  For example, the refractive index of kyanite ranges from 1.712-1.734 (Wikipedia).

polarization, property of certain electromagnetic radiations in which the direction and magnitude of the vibrating electric field are related in a specified way.

Light waves are transverse: that is, the vibrating electric vector associated with each wave is perpendicular to the direction of propagation. A beam of unpolarized light consists of waves moving in the same direction with their electric vectors pointed in random orientations about the axis of propagation. Plane polarized light consists of waves in which the direction of vibration is the same for all waves. In circular polarization the electric vector rotates about the direction of propagation as the wave progresses. Light may be polarized by reflection or by passing it through filters, such as certain crystals, that transmit vibration in one plane but not in others.

But, be cautious about relying too heavily on color as an identification tool!  Minerals within a solid solution group can have very different color characteristics in hand sample (as shown in Figure 2.6.6) and under the microscope.

Fractures are irregular cracks within a mineral.  These can form within any mineral, but when only fractures appear in a mineral, it may indicate that it has poor or no cleavage.

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Microscopes with the ability to view thin sections under both reflected and transmitted light do exist, and different opaque minerals will reflect light differently.  This type of microscope is most commonly used for studying ore deposits or other rocks containing many opaque mineral species.

Cleavage is the tendency of minerals to break along atomic planes of weakness within the crystal structure. Minerals may have one or more directions of cleavage dictated by the atomic arrangement and bonding within that mineral.