FINAL

Question 1

FELDSPARS 1

Answer 1

Orthoclase (K)
Albite (Na)
Anorthite (Ca)

Question 2

TWINNING

Answer 2

• Polysynthetic: Plag, Albite
• Tartsun (Plaid): Microcline
• Simple/Contact: Ortho
• Penetration: andalusite

Question 3

ANISOTROPIC1

Answer 3

Anisotropic Xerals behave different w/ light. Light ray will split into 2 rays

Question 4

Types of Extinction

Answer 4

1. Random: extinct 4x upon rotation, no well-defined cleavage
2. Inclined: most common. extinct when NOT in E-W or N-S.
3. Parallel: extinct when long axis paralell to E-W or N-S. Usually uniaxial
4. Symmetric: If xeral has symmetric outline and it goes extinct when symmetry is aligned to E-W or N-S
5. Undulatory: band of darkness as stage is rotated

Question 5

INDICATRIX

Answer 5

THE VARIATION OF LIGHT VELOCITY WITHIN XERAL (x, y, z)
* Isotropic xeral: a sphere

Question 6

Uniaxial vs (Biaxial)

ANISOTROPIC

Answer 6

• Optical axis with singular (double) direction in which light does not split.
• axis is the specific direction in an aniso where the light ray behaves as isotrop.
• UNI: Tetragonal, Hexagonal
• BI: Orthorhombic, Monoclinic, Triclinic

Question 7

Uniaxial

Answer 7

• light ray enters, splits in one fast and one slow ray. vibrate perpend. to ea. other
• ALL ANISO
• Double refraction. 2 images bc of different speed of rays
• orientation where light does NOT split is when ray (optic axis, extinct) is parallel. to C axis
• ordinary ray follows Snell law. extra. does not (on long axis)
• acc. plate to change the retardation of the mineral grain. > increase in color when slow ray in xeral parall. to slow ray on plate

Question 8

BIAXIAL

Answer 8

• indicatrix with axes of different lengths (X:Fast, Z: Slow, Y: interm). POS: optic axis acute about “Z”. NEG: optic axis acute about “X”
• two optic axes and two circular sections (extinct)
• ALL ANISO
• 2 optic axes NOT coincident with xtallography axes
• split isogyres
• 2V angle: acute angle bw optic axes
• 2E angle: apparent 2v angle

Question 9

Uniaxial Optic Sign

Answer 9

= v(ordinary ray) - v(extra ray)
E = extinct direction. if BIGGER, sign is POSITIVE
w = max. birefring. if BIGGER, optic sign is NEGATIVE
max. biref = w-E

Question 10

Interference Fig

Answer 10

• Bertrand Lens to align optical components and focal planes
• Melatope: emergence of optical axis(es)
• Isogyres: cross. extinction angles
• Isochromes: circle center
• BURP

Question 11

Si Tetrahedron

SiO4

Answer 11

• Isolated: olivine. Nesosil
• Pairs: epidote. Sorosil.
• Rings: beryl. Cyclosil
• Single Chain: pyroxenes. Inosil
• Double Chain: amphiboles. Inosil
• Sheets: micas/clays. Phyllosil
• 3D rotating network: quartz/feldspars. Tectosilicates

Question 12

Silicate Characteristics

Answer 12

NESO (ol. garn. Al-silicates, Zirc. stauro. topaz. SiO4)
* bond strength equal in all directions
* Equidimensional habit
* No cleavage
SORO (rare. Si2O7)
* accessory xerals, widely distributed
INO (fiber. pyroxenes(SI2O6) amphib(Si4O11))
* Pyroxenoids: distorted/twisted chains
CYCLO (usually hexagonal. Si6O18)
PHYLLO (leaf. Si2O5)
TECTO (building. SiO2)

Question 13

Olivine

Answer 13

Mg2SiO4 <> Fe2SiO4
Forsterite <> Fayalite

Question 14

Non-Silicates

Answer 14

CARBONATES
SULFATES
PHOSPHATES

Question 15

Gibbs

Answer 15

• you want negative (stable) to nucleate
• surface area overwhelms volume in small embryo then you increase radius…
• ^ increasing radius & volume you outpace DELTAG(surface area)
• CRITICAL RADIUS needed for xtallyzation
• embryo will only form if total free energy of embryo is less than free energy of melt
• DELTAG = DELTAG(surf) + DELTAG(volume)
• Heterogenous Nucleation when xeral uses pre-existing xeral surface for nucleation site
• rapidly growing faces grow themselves out of existence. most prominent faces are the slow ones