Introduction to Light and Polarized Light

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Hillary Watkins
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$color Wavelength of Light Visible light is only a tiny, moderate energy fraction of the electromagnetic spectrum$

1 Aspects of Light Introduction to Light and Polarized Light Amplitude (height of wave) corresponds to the intensity (brightness) of light Wavelength corresponds to the energy of light In the visible spectrum wavelength corresponds to color Wavelength of Light Visible light is only a tiny, moderate energy fraction of the electromagnetic spectrum Longer wavelengths (e.g., radio waves) have less energy Shorter wavelengths have more energy Absorption and Emission of Light 1

$moves slower in other media (e.g., 1.2 x 10 8 m/s in diamond) Refraction Refraction is the change in direction of a wave due to a change in its velocity when a wave passes from one medium to another.$ $When light passes from a less dense medium to a more dense medium, the wave will bend toward the normal (perpendicular to the interface) Refractive Index (RI) Refractive Index is the ration of the$

2 Absorption Results in Color (A Familiar Example from Biology) Speed of Light The speed of light varies with the media through which it passes Light moves fastest in a vacuum (3 x 10 8 m/s) Light moves slower in other media (e.g., 1.2 x 10 8 m/s in diamond) Refraction Refraction is the change in direction of a wave due to a change in its velocity when a wave passes from one medium to another. When light passes from a less dense medium to a more dense medium, the wave will bend toward the normal (perpendicular to the interface) Refractive Index (RI) Refractive Index is the ration of the speed of light in a vacuum to the speed of light in another medium The speed of light in a vacuum is always faster than in any other medium so all RI values are >1 RI of minerals range from1.32 to 2.40, with most between 1.50 and

$RELIEF: A Visual Estimate of Relative Refractive Indices BECKE LINE: An Indicator of Positive or Negative Relief Becke line moves into higher RI when stage is lowered Positive relief:$ 54) Vibration and Polarization of Light Polarizing Filters Polarizing filters are materials in which electrons can move freely in one direction but not another.

54) Vibration and Polarization of Light Polarizing Filters Polarizing filters are materials in which electrons can move freely in one direction but not another.

Most light waves vibrate in all planes that are perpendicular with respect to the direction of propagation.

3 RELIEF: A Visual Estimate of Relative Refractive Indices BECKE LINE: An Indicator of Positive or Negative Relief Becke line moves into higher RI when stage is lowered Positive relief: Greater than epoxy (1.54) Negative relief: Less than epoxy (1.54) Vibration and Polarization of Light Polarizing Filters Polarizing filters are materials in which electrons can move freely in one direction but not another. Intuitively, you might think light polarized parallel to the direction of freedom might be able to "slip through". In fact, the opposite is the case. Most light waves vibrate in all planes that are perpendicular with respect to the direction of propagation. If the electric field vectors are restricted to a single plane by filtration of the beam with specialized materials, then the light is referred to as plane polarized with respect to the direction of propagation, Light polarized parallel to the easy direction moves the electrons back and forth. In the process it does work and is absorbed. Light oriented perpendicular to that direction cannot move the electrons very much, does no work, and passes through. 3

Polarizing Filters on a PLM The lower polarizing filter (polarizer) allows N-S vibrating light to pass The

minerals have the same structure, composition and properties in all directions Anisotropic minerals (vast

Minerals Anisotropic minerals may exhibit variations in their optical properties under a PLM as a sample is

4 Polarizing Filters on a PLM The lower polarizing filter (polarizer) allows N-S vibrating light to pass The upper polarizer (analyzer) allows E-W vibrating light to pass Isotropic vs Anisotropic Minerals Isotropic minerals have the same structure, composition and properties in all directions Anisotropic minerals (vast majority of minerals) have structures, and/or compositions, and properties that vary with direction Anisotropic Minerals Anisotropic minerals may exhibit variations in their optical properties under a PLM as a sample is rotated as a result of the variation in chemical properties with direction PLEOCHROISM: Change in Color with Orientation of Mineral 4

VARIABLE RELIEF: Change in Relief with Orientation of

Calcite: Lower Relief Calcite: Higher Relief

passes through anisotropic materials Birefringence The

perpendicular directions One ray travels straight

5 VARIABLE RELIEF: Change in Relief with Orientation of Mineral Birefringence and Interference Lecture 2 Calcite: Lower Relief Calcite: Higher Relief Decomposition of a ray of light into two rays when it passes through anisotropic materials Birefringence The two rays travel at different speeds Vibrate in perpendicular directions One ray travels straight through crystal ordinary ray Birefringence Other ray refracted through crystal extraordinary ray 5

6 Sign of Birefringence Birefringence and the PLM If ordinary ray faster than extraordinary ray positive If ordinary ray slower than extraordinary ray negative Birefringence and the PLM Retardation = Birefringence x Thickness 6

7 7

8 Interference and Color Interference Color Chart Each color has a different wavelength Each color of light will be retarded a different multiple of wavelengths Some colors pass through whereas others will be partially or completely blocked 8

The Optic Axes OPTIC AXIS: straight line through a mineral along which light does not diverge into two separate rays Along optic axis mineral behaves Some

9 The Optic Axes OPTIC AXIS: straight line through a mineral along which light does not diverge into two separate rays Along optic axis mineral behaves Some anisotropic minerals have only one optic axis Uniaxial Uniaxial Minerals Biaxial Minerals Orthoscopic vs Conoscopic Light Most anisotropic have two optic axes Biaxial 9

10 Conoscopic Light Uniaxial Interference Figure 10

EARTH MATERIALS OPTICS AND MINERALS

EARTH MATERIALS OPTICS AND MINERALS Wave Terms FREQUENCY (f) number of cycles per unit time [units = Hertz (Hz)] 1 Hz = 1 cycle/s T = 1/f; f = 1/T; T f = 1 Waves can coexist in the same space with other