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Todays objectives

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Why do some minerals change color when the microscope stage is rotated (without analyzer) ... How many pleochroic colors would a mineral show that stayed black in XP? ... – PowerPoint PPT presentation

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Title: Todays objectives


1
Todays objectives
  • What happens when light passes through most
    minerals?
  • Why do some minerals change color when the
    microscope stage is rotated (without analyzer)?
  • What causes the colors you saw when you inserted
    the analyzer?
  • Why do those colors go to black every 90 degrees
    of rotation?
  • How can we use those colors to help us identify
    unknown minerals?

2
Background
  • Vectors
  • Light as wave
  • Interference (2D)
  • Interference (3D)

3
Polarization
  • Light can be constrained to vibrate in a
    particular plane
  • When two light rays combine, their vibration
    vectors add (vector-wise)

ABC
4
Polarization
  • Polaroid film (in the polarizer analyzer on
    your scope) absorbs light vibrating perpendicular
    to its direction

transmitted component
polarizer direction
incoming ray
5
Anisotropic materials
  • Cause light to split into 2 rays vibrating 90 to
    each other
  • Two rays see a different crystal environment
  • different indices of refraction
  • different speeds of light
  • different paths
  • produces double refraction

6
Double refraction
  • Calcite demo
  • One ray takes unexpected path through crystal
    (extraordinary, e or E ray)
  • Special direction where this doesnt happen
    optic axis
  • calcite nw 1.658 and ne 1.486
  • which image looks deeper?

7
Double refraction
8
Pleochroism
  • Two rays are absorbed differently
  • can show different color (distribution of
    wavelengths)
  • or intensity of color

9
Pleochroism
  • Isometric - no pleo.
  • Hexagonal, tetragonal - 2 end-member colors
  • Triclinic, Monoclinic, Orthorhombic - 3
    end-members

10
Pleochroism
  • Isometric - no pleo.
  • Hexagonal, tetragonal - 2 end-member colors
  • Triclinic, Monoclinic, Orthorhombic - 3
    end-members

11
Recap - Pleochroism
  • Anisotropic grain has fast and slow directions
  • In some minerals, these show different colors
  • Because the incoming light is polarized, when one
    ray is perpendicular to that direction, it is
    excluded and the other color is displayed

12
Retardation
  • fast slow rays are 45 from polarizer
  • D d (ns - nf)
  • distance, nm

d
13
Interference
  • Retarded rays get vector-combined in analyzer
    (XP)

14
Interference
  • If Dnl, no ray passes analyzer

15
Recap Retardation / Interference
  • The slow ray is held back, so at the analyzer
    they combine with a new net vibration direction
    (retardation changes vibration direction)
  • The relationship between the retardation
    distance, grain thickness, and indices of
    refraction is
  • D d (ns - nf)
  • If the new vibration direction is 0 or 180 from
    the incoming, the ray is canceled at the analyzer
    (upper polar)
  • when Dl, or D2l , or D3l , or D4l , etc.

16
Extinction
  • When fast or slow direction polarizer
  • will occur every 90 of stage rotation
  • Calcite demo

17
Interference Colors
  • What changes for other colors (wavelengths)?
  • D d (ns - nf)

d
18
Interference Colors
  • Story above was for one wavelength (color) of
    light
  • Retardation distance (D) is same across colors,
    but
  • D n l -gt no ray (rotation 0 or 180)
  • D n l - (l/2) -gt max.ray (rot.90, 270)
  • Certain wavelengths get blocked at analyzer,
    others pass
  • produces an interference color

19
Thickness effect
  • D d (ns - nf)
  • quartz wedge demo
  • d (ns - nf) 0.009 (a small value)
  • shows change in set of transmitted wavelengths
    (i.e., color) with increasing retardation, D

20
Birefringence effect
  • D d (ns - nf) d d
  • can get same set of colors by varying d at
    constant d
  • maximum d is characteristic of mineral!
  • e.g., calcite d 0.172 (a large value)
  • orientation-dependent
  • d (ns-nf) ranges from 0 to a maximum
  • 0 is looking down optic axis

21
Interference Color Chart
  • range of colors - same as quartz wedge
  • measuring birefringence

birefringence, d
quartz?
thickness, d (µm)
birefringence, d
retardation, D (nm)
22
Interference Color Chart
  • Orders
  • Every 550 nm ( lblue)

birefringence, d
thickness, d (µm)
birefringence, d
retardation, D (nm)
23
Interference Color Chart
  • Two kinds of white
  • low-order
  • high-order

24
Next Lecture
  • How do you know which white youre looking at?
  • Wedge effect, gypsum plate
  • Mineral ID features sign of elongation,
    extinction type/angle
  • Which is the slow ray, ? or ? ?
  • Uniaxial indicatrix, conoscopic illumination
  • How are biaxial minerals different?
  • Biaxial indicatrix, conoscopic illumination

25
Questions to think about
  • How many pleochroic colors would a mineral show
    that stayed black in XP?
  • Before polarizing film, microscopes used a Nicol
    prism, made of two specially-cut pieces of
    calcite, glued together. How could you cut
    calcite to make this work?

26
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27
Accessory plates
  • Tell you fast vs. slow directions
  • Fig. 7.21, p. 129
  • Can add or subtract retardation
  • Gypsum plate has D 550 nm (l)
  • Mica plate has D 138 nm (l/4)
  • Short dimension is always slow

28
Accessory plates
  • Tell you fast vs. slow directions
  • Fig. 7.21, p. 129
  • Can add or subtract retardation
  • Gypsum plate has D 550 nm (l)
  • Mica plate has D 138 nm (l/4)
  • Short dimension is always slow

29
Using accessory plates
XP
  • 1) Find vibration directions, using extinction
  • 2) Rotate so vibration directions are diagonal
  • 3) Insert plate
  • 4) If colors add, slowmineral slowplate,
    otherwise, slowmineral fastplate

D200 nm
30
Using accessory plates
XP
  • 1) Find vibration directions, using extinction
  • 2) Rotate so vibration directions are diagonal
  • 3) Insert plate
  • 4) If colors add, slowmineral slowplate,
    otherwise, slowmineral fastplate

q
p
31
Using accessory plates
45
XP
  • 1) Find vibration directions, using extinction
  • 2) Rotate so vibration directions are diagonal
  • 3) Insert plate
  • 4) If colors add, slowmineral slowplate,
    otherwise, slowmineral fastplate

q
p
32
Using accessory plates
XP
  • 1) Find vibration directions, using extinction
  • 2) Rotate so vibration directions are diagonal
  • 3) Insert plate
  • 4) If colors add, slowmineral slowplate,
    otherwise, slowmineral fastplate

q
p
33
Using accessory plates
XP
  • 1) Find vibration directions, using extinction
  • 2) Rotate so vibration directions are diagonal
  • 3) Insert plate
  • 4) If colors add, slowmineral slowplate,
    otherwise, slowmineral fastplate

p slow
q
p
D750 nm
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