2. Igneous Rocks Lecture 3 Types of Rock include Igneous, Sedimentary and Metamorphic Marble demo, rock specimens, Petrographic Microscope, Olivine Porphyry or Gabbro

3. Characteristics of magma Igneous rocks form as molten rock cools and solidifies Characteristics of magmas (molten rock) depend on parent material and where they crystallize Where determines speed of crystallization At surface, fast cooling makes small crystals

4. Geothermal Gradient Silica-rich rocks (with Quartz) melt at cooler temperatures. Melts are viscous Silica-poor rocks (with Olivine, Pyroxene) melt at higher temperatures Melts are very fluid Hot Cool

5. Characteristics of magma General Characteristics of molten rock Forms from partial melting of rocks inside the Earth Rocks formed from lava at the surface are classified as extrusive, or volcanic rocks Rocks formed from magma that crystallizes at depth are termed intrusive, or plutonic rocks http://www.casdn.neu.edu/~geology/department/staff/colgan/iceland/usgs/

6. Igneous Rocks Formed in Rift Igneous Rocks Formed Above Sinking Plate Two Geologic Environments Where Igneous Rocks Form

7. Extrusive Igneous Rock - Lava (Hawaii)

8. Intrusive Igneous Rock (Granite) – This granite cooled 30 kilometers under the surface

9. Characteristics of magma The nature of magma Consists of three components: –A liquid portion, called melt, that is composed of mobile ions –Solids, if any, are silicate minerals that have already crystallized from the melt –Volatiles, which are gases dissolved in the melt, including water vapor (H 2 O), carbon dioxide (CO 2 ), and sulfur dioxide (SO 2 )

10. Characteristics of magma Crystallization of magma Cooling of magma results in the systematic arrangement of ions into orderly patterns The silicate minerals resulting from crystallization form in a predictable order Rock-forming minerals crystallize with increasing complexity as the magma cools. The most complex 3-D minerals crystallize last. The hottest magmas can only crystallize Olivine (Independent Tetrahedra), but as the magma cools, more complex minerals can form.

11. Crystallization of minerals in magma bodies Bowen’s reaction series and the composition of igneous rock Norman L. Bowen demonstrated that as a magma cools, minerals crystallize in a systematic fashion based on their melting points http://vgp.agu.org/bowen_paper/bowen_paper.html

12. Bowen’s Reaction Series Molten- VERY Hot Molten- Not so hot 100% Solid

13. Fine crystals Need a microscope Course crystals Easily seen Low silica, HOT, fluidHigh silica, warm, viscous Intermediate

14. Granite Hand Sample Granite Thin Section Order of Crystallization Bowens reactrion series says: as a granitic melt cools, Biotite Mica and Plagioclase Feldspar crystallize out before Quartz We can see the order of crystallization under the microscope

15. Zoned feldspar (plagioclase) showing change in composition with time in magma chamber (calcium-rich in core to sodium-rich at rim) If the first formed crystals of Calcium-rich (Ca) Plagioclase are allowed to react with the melt, they will become more sodium-rich on their outer rims Crystals can react with the melt if they touch it

16. However, if early crystals are removed the melt becomes richer in Silica A rising melt may leave its mafic components behind, and the upper part may be granitic Remove Fe, Mg, Ca Some Si Left with K and Al Most of Si You can start with a Mafic (silica-poor) magma and end up with some Felsic (silica-rich) Granites. Marble Demo

17. Characteristics of magma Crystallization of magma Texture in igneous rocks is determined by the size and arrangement of mineral grains Igneous rocks are typically classified by both: –Texture –Mineral composition

18. Igneous textures Texture is used to describe the overall appearance of a rock based on the size, shape, and arrangement of interlocking minerals Most important is crystal size Factors affecting crystal size Rate of cooling –Slow rate promotes the growth of fewer but larger crystals

19. Igneous textures Factors affecting crystal size Rate of cooling (continued) –Fast rate forms many small crystals –Very fast rate forms glass Amount of silica (SiO 2 ) present Amount of dissolved gases

20. Types of Igneous textures Types of igneous textures Aphanitic (fine-grained) texture –Rapid rate of cooling of lava or magma –Microscopic crystals –May contain vesicles (holes from gas bubbles) Phaneritic (coarse-grained) texture –Slow cooling –Crystals can be identified without a microscope

21. Aphanitic texture Fine grained because it cooled quickly at the surface

22. Phaneritic texture Coarse crystals cooled slowly at great depth

23. Igneous textures Types of igneous textures Porphyritic texture –Minerals form at different temperatures as well as differing rates –Large crystals, called phenocrysts, are embedded in a matrix of smaller crystals, called the groundmass Glassy texture –Very rapid cooling of molten rock –Resulting rock is called obsidian

24. Porphyritic texture Granite

25. Glassy texture Obsidian

26. More types of Igneous textures Types of igneous textures Pyroclastic texture –Various fragments ejected during a violent volcanic eruption –Textures often appear to more similar to sedimentary rocks

27. Pyroclastic Rock - Superheated Flows

28. Naming igneous rocks – pyroclastic rocks Composed of fragments ejected during a volcanic eruption Varieties Tuff – ash-sized fragments Volcanic breccia – particles larger than ash

29. Ash and pumice layers

30. Still more types of Igneous textures Types of igneous textures Pegmatitic texture –Exceptionally coarse grained crystals –Form in late stages of fractionation of magmas –This is often what prospectors are looking for

31. A Pegmatite with Feldspar and Zircon Zircon is very good for obtaining radiometric ages

32. Igneous Compositions Igneous rocks are composed primarily of silicate minerals that include: dark (or ferromagnesian) colored silicates –Olivine –Pyroxene –Amphibole –Biotite mica –And … “MAFIC” Magnesium and Iron Show tray of Mafic Minerals

33. Igneous Compositions Igneous rocks also contain light colored silicate minerals that include: –Quartz –Muscovite mica –Feldspars “FELSIC” Feldspar and Silica Show tray of Felsic Minerals

34. Igneous Rock Classification- Bowen’s Reaction Series on its side Felsic rocks crystallize from warm meltsMafic from hot melts Note Minerals in

35. Igneous compositions Granitic composition –Composed of light-colored silicates –Designated as being felsic (feldspar and silica) in composition –Contains high amounts of silica (SiO 2 ) –Major constituents of continental crust

36. Igneous compositions Naming igneous rocks – granitic (felsic) rocks Granite –Phaneritic –Over 20 percent quartz, about 25 percent or more feldspar (usually much more feldspars). –Plagioclase is Sodium-rich –Abundant and often associated with mountain building –The term granite covers a wide range of mineral compositions

37. Igneous compositions Naming igneous rocks – granitic (felsic) rocks Rhyolite –Extrusive equivalent of granite –May contain glass fragments and vesicles –Aphanitic texture (means fine grained minerals) –Less common and less voluminous than granite –Phenocrysts can include quartz and feldspar Figure 3-7 continued

38. Rhyolite fine grained because extruded, so crystallized quickly

39. Igneous compositions Basaltic composition can be fine or coarse –Composed of dark Olivine and Pyroxene and grey calcium-rich plagioclase feldspar –No Potassium-rich feldspar (no K-spar ‘Microcline’) –Designated as being mafic (magnesium and ferrum, for iron) in composition –Much denser than granitic rocks - sinks –Comprises the ocean floor as well as many volcanic islands such as Hawaii. Also rift valley lavas

40. Igneous compositions Naming igneous rocks – basaltic (mafic) rocks: Fine-grained Basalt –Volcanic origin –Aphanitic texture –Composed mainly of pyroxene, some olivine and also calcium-rich plagioclase feldspar –Most common extrusive igneous rock

41. Scoria type Basalt note Gas Bubbles

42. Igneous compositions Naming igneous rocks – basaltic (mafic) rocks: Coarse Grained Gabbro –Intrusive equivalent of basalt –Phaneritic texture consisting of pyroxene and calcium-rich plagioclase (med. grain “diabase”) –Makes up a significant percentage of the oceanic crust, beneath the basalt pillow lavas.

43. Gabbro - a mafic igneous rock. A large- grain version of Basalt

44. Igneous compositions Other compositional groups Intermediate (or andesitic) composition –Contain at least 25 percent dark silicate minerals –Associated with explosive volcanic activity –Often gray

45. Igneous compositions Intermediate rocks Andesite –Volcanic origin –Aphanitic texture –Often resembles rhyolite –Intermediate silica content –Frequent composition in volcanoes above subduction zones, e.g. in Andes Mountains

46. Igneous compositions Extrusive products can include: Pumice –Volcanic –Glassy texture, very light weight, mostly air –Frothy appearance with numerous voids (extrusive foam) –Forms when lavas have a lot of water and other volatiles Common with intermediate compositions

47. Igneous compositions Intermediate rocks Diorite –Plutonic equivalent of andesite –Coarse grained –Intrusive –Composed mainly of intermediate feldspar and amphibole

48. Igneous compositions Silica content influences a magma’s behavior Granitic magma –High silica content –Extremely viscous –Liquid exists at temperatures as low as 700 o C –Huge explosion if it erupts (Yellowstone, Toba) Plutonic “Granite” Volcanic “Rhyolite”

49. Igneous compositions Silica content influences a magma’s behavior Basaltic magma –Much lower silica content –Fluid-like behavior –Crystallizes at higher temperatures –Gurgles when it erupts (Hawaii)

50. Origin of Magma Generating magma from solid rock Produced from partial melting of rocks in the crust and upper mantle Role of heat –Temperature increases within Earth’s upper crust with increasing depth. The geothermal gradient averages between 20 o C to 30 o C per kilometer

51. Origin of Magma Role of heat –Rocks in the lower crust and upper mantle are near their melting points –Any additional heat (from rocks descending into the mantle or rising heat from the mantle) may induce melting

52. Origin of Magma Role of Pressure –Reducing the pressure lowers the melting temperature – the rock probably melts –RIDGE: When confining pressures drop, decompression melting occurs

53. Decompression melting At a Mid-Ocean Ridge

54. Origin of Magma Role of volatiles - WATER –Volatiles (primarily water) cause rocks to melt at lower temperatures –This is particularly important where oceanic lithosphere descends into the mantle in a subduction zone

55. The role of water Pillow Lavas Water promotes melting despite high pressures

56. Evolution of magmas Processes responsible for changing a magma’s composition Assimilation –Changing a magma’s composition by the incorporation of foreign matter (surrounding rock bodies) into a magma – The rising magma melts near surface rock, changing the composition of the melt. Magmatic differentiation = Fractionation –Separation of a melt from earlier formed crystals causes a different composition in the remaining magma

57. Evolution of magmas Processes responsible for changing a magma’s composition Magma mixing –Involves two bodies of magma intruding one another –Two chemically distinct magmas may produce a composition quite different from either original magma

58. Assimilation and magmatic differentiation Show Samples

59. Evolution of magmas Partial melting and magma formation Incomplete melting of rocks is known as partial melting Formation of basaltic magmas –Most originate from partial melting of ultramafic rock in the mantle –Basaltic magmas form at mid-ocean ridges by decompression melting of rising mantle material –also by partial melting of ocean crust + sediments+ water in subduction zones

60. Basalts forming in rifts Decompression Melting: Magma under lithosphere heats and cracks it. Mantle rock is exposed to low pressures – it partially melts

61. Origin of Andesite & Diorite: intermediate silica content Good diagram for the Andes Mountains Small blobs, not much heat in them Assimilate some crust, fractionate

62. 62 Plate Tectonics - Andesite Line Andesites form above the deep portions of a subduction zone Andes

63. Origin of Granitic Rocks Can also get granites from deep rock burial Huge blobs w/ low temps but lots of magma, fractionation & assimilation => Granite Batholiths

64. End of Lecture 3