EARTH MATERIALS OPTICS AND MINERALS

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Lorraine Wheeler
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1 EARTH MATERIALS OPTICS AND MINERALS

2 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

3 Waves can coexist in the same space with other waves. Waves interact in various ways. Waves that are in phase experience constructive interference. Image by E.B. Watson

4 waves that are out of phase experience destructive interference... Image by E.B. Watson

5 Objects radiate light because of their high temperatures - incandescent. light (EM) is produced whenever a charge is accelerated by an external force... electromagnetic wave model Image by E.B. Watson

6 Visible light part of the EM spectrum Image by E.B. Watson Longer! v =!f, and v = c

7 % Peak solar Image by E.B. Watson

8 Waves may be Absorbed Transmitted Refracted Reflected Image by E.B. Watson

$Index of refraction (n) for EM n = c v Refraction Image by E.B.$

9 Index of refraction (n) for EM n = c v Refraction Image by E.B. Watson air (0 o C) air (30 o C) Glass 1.50 Diamond 2.42 Ice 1.31 Water 1.33 Alcohol 1.36

10 You know how a stick looks bent when you put it in water? That s why I no longer take baths. Steven Wright Image by E.B. Watson

11 Image by E.B. Watson Snell s law sin! sin! i r = v B = v A n n a b

12 Critical Angle Image by E.B. Watson All you need to find this is to solve Snell s law for! r =90 O

13 Polarization Image by E.B. Watson

14 Plane Polarization Filter Image by E.B. Watson

15 When monochromatic light is transmitted through a mineral from air, its velocity slows, the waves bunch up. The frequency remains the same but the wavelength decreases.

$Refraction producing constituent wavelengths Image by E.$

16 Refraction producing constituent wavelengths Image by E.B. Watson Dispersion High f (low!) more bending in prism

17 The index of refraction decreases with increasing wavelength. The n D is at 589 nm. Abnormal dispersion of the r i (increased at higher!). Minerals with abnormal dispersion are always colored.

18 Immersion oils of fixed r i can identify the r i of an unknown grain. If the mineral has a higher r i = positive relief If the oil has a higher r i = negative relief Lowering the stage of a microscope, the focus (Becke) line moves to the material with higher r i.

$Isotropic Same in every direction. Light is refracted equally in all directions in these materials.$

19 Isotropic Same in every direction. Light is refracted equally in all directions in these materials. Isometric forms (cubic) r i is uniform Non-lattice structures Glasses, polymers, liquids, gasses.

20 Uniaxial Two principle directions at right angles. Two r i Tetragonal Hexagonal Rhomobohedral 2 configurations If c > a then (+) If c < a then (-)

21 Uniaxial Those with atoms equally spaced along two axes, elongated in the third. Requires two raypaths, one in the close packed plane, one perpendicular. The ordinary (") ray and the extraordinary (#) ray If the extraordinary ray is the slow ray, then the mineral is optically positive If the extraordinary ray is the fast ray, then the mineral is optically negative.

22 Anisotropy results when atoms are closely packed in one plane, and further apart in another. In anisotropic materials, the velocity of light varies depending on direction through the material In most directions, light that enters splits into two rays that vibrate and right angles to each other. d = thickness $ = retardation

23 Interference at the analyzer The retardation is a full wavelength - the fast and slow rays constructively interfere perpendicular to the analyzer The retardation is a half wavelength - the fast and slow rays constructively interfere in the pole of the analyzer

24 Michel-Levy Interference Color Chart Nikon Microscopes

25 Color Interference (birefringence)

26 Uniaxial

27 Uniaxial Interference figures Fast on slow -colors go low

28 Biaxial crystals Three principle directions, not necessarily at right angles. Orthorhombic Monoclinic Triclinic

29 Biaxial crystals Those with atoms unequally spaced along the three crystallographic axes. Requires three raypaths for each direction The %, &, ' rays % is lowest r i, fastest ' is highest r i, slowest & is the middle child This produces two optical axes, separated by an acute angle 2Va. If 2Va is bisected by n ', then positive. If 2Va is bisected by n %, then negative

30 Biaxial

34 Minerals retard light relative to air Light is refracted as a function of the velocity difference. Polarization eliminates all but one vibration direction Isotropic materials have only one velocity - no interference Uniaxial minerals have two raypath velocities - optic axis is on c and exhibit interference Biaxial minerals have three raypath velocities - two optic axes and exhibit interference

Introduction to Light and Polarized Light

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