Intraplate magmatism Intraplate magmatism l l Hotspots Rift

Intraplate magmatism l l Hotspots Rift zones (often associated with hotspots) Intra-oceanic plate: Tholeitic

Ocean islands and seamounts Commonly associated with hot spots Figure 14 -1. After Crough

Types of OIB Magmas l Two principal magma series Tholeiitic series (dominant type) Parental

Hawaiian Scenario Cyclic, pattern to the eruptive history 1. Pre-shield-building stage somewhat alkaline and

Hawaiian Scenario 3. Waning activity more alkaline, episodic, and violent (Mauna Kea, Hualalai, and

Evolution in the Series Tholeiitic, alkaline, and highly alkaline Figure 14 -2. After Wilson

Trace Elements l l The LIL trace elements (K, Rb, Cs, Ba, Pb 2+

Trace Elements l l HFS elements (Th, U, Ce, Zr, Hf, Nb, Ta, and

Trace Elements: REEs Figure 14 -2. After Wilson (1989) Igneous Petrogenesis. Kluwer.

MORB-normalized Spider Diagrams Figure 14 -3. Winter (2001) An Introduction to Igneous and Metamorphic

Generation of tholeiitic and alkaline basalts from a chemically uniform mantle Figure 10 -2

Ne Pressure effects: E 3 GPa Volatile-free E 2 Gpa Figure 10 -8 After

l l Tholeiites favored by shallower melting F 25% melting at <30 km tholeiite

$Isotope Geochemistry l l Isotopes do not fractionate during partial melting of fractional melting$

Simple Mixing Models Binary Ternary All analyses fall between two reservoirs as magmas mix

Figure 14 -6. After Zindler and Hart (1986), Staudigel et al. (1984), Hamelin et

Mantle Reservoirs 1. DM (Depleted Mantle) = N-MORB source Figure 14 -6. After Zindler

2. BSE (Bulk Silicate Earth) or the Primary Uniform Reservoir Figure 14 -6. After

3. EMI = enriched mantle type I has lower 87 Sr/86 Sr (near primordial)

5. PREMA (PREvalent MAntle) Figure 14 -6. After Zindler and Hart (1986), Staudigel et

Pb Isotopes Pb produced by radioactive decay of U & Th l 238 U

Figure 14 -8. After Wilson (1989) Igneous Petrogenesis. Kluwer. Data from Hamelin and Allègre

A Model for Oceanic Magmatism Continental Reservoirs DM OIB EM and HIMU from crustal

“Marble cake” model for mantle convection & mixing

Continental Flood Basalts Large Igneous Provinces (LIPs) l Oceanic plateaus l Some rifts l

CFB’s l l Associated to major continental break-up … or/and to plume head impact

Figure 15 -2. Flood basalt provinces of Gondwanaland prior to break-up and separation. After

Figure 15 -3. Relationship of the Etendeka and Paraná plateau provinces to the Tristan

Bimodal magmas l Basalts and rhyolites Secondary melting? F Effect of the two eutectics?

Figure 15 -7. Condrite-normalized rare earth element patterns of some typical CRBG samples. Winter

Figure 15 -13. A model for the origin of the Columbia River Basalt Group

Continental alkaline series Alkali volcanoes – basaltic strombolian cone in front, trachytic pelean dome

Continental alkaline series l l l Rift (or hotspot) related Large diversity (possibly >

Common features of continental alkali series l l l Alkaline (!) Undersaturated to just

Alkaline series Mildly alkaline Strongly alkaline

Figure 18 -2. Alumina saturation classes based on the molar proportions of Al 2

Trace elements enriched Figure 19 -5. Chondrite-normalized REE variation diagram for examples of the

Enriched mantle source Figure 19 -3. 143 Nd/144 Nd vs. 87 Sr/86 Sr for

$Generated from low to very low melt fractions Figure 19 -14. Grid showing the$

The alkali eutectic Figure 19 -7. Phase diagram for the system Si. O 2

Diversity of alkaline continental magmas – some examples l l Saturated alkaline series Undersaturated

Figure 19 -1. Variations in alkali ratios (wt. %) for oceanic (a) and continental

Continental Alkaline Magmatism. The East African Rift Figure 19 -2. Map of the East

East African rift (Afar) – mildly alkaline

Central African Rift – Strongly alkaline

Two main series l Basalts-Trachydandesites-Trachydacites. Rhyolites (stronly bimodal): (just) saturated alkali series A-type granites

Figure 19 -9. Hypothetical cross sections (same vertical and horizontal scales) showing a proposed

Bimodal associations again (the « Daly gap » ) l l l Mantle vs.

The oddities… l l Carbonatites Lamproites, kimberlites, etc.

Chapter 19: Continental Alkaline Magmatism. Carbonatites

Carbonatites Figure 19 -11. Idealized cross section of a carbonatite-alkaline silicate complex with early

Chapter 19: Continental Alkaline Magmatism. Carbonatites Figure 19 -15. Silicate-carbonate liquid immiscibility in the

Chapter 19: Continental Alkaline Magmatism. Carbonatites Figure 19 -15. Schematic cross section of an

Lamproites and kimberlites l l … many, many rock types … many, many different

Chapter 19: Continental Alkaline Magmatism. Kimberlites

Chapter 19: Continental Alkaline Magmatism. Lamproites Figure 19 -18 a. Initial 87 Sr/86 Sr

Chapter 19: Continental Alkaline Magmatism. Lamproites Figure 19 -17. Chondrite-normalized rare earth element diagram

Chapter 19: Continental Alkaline Magmatism. Kimberlites Figure 19 -19. Model of an idealized kimberlite

Chapter 19: Continental Alkaline Magmatism. Kimberlites Figure 19 -20 a. Chondrite-normalized REE diagram for

Chapter 19: Continental Alkaline Magmatism. Kimberlites Figure 19 -20 b. Hypothetical cross section of

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Intraplate magmatism

Intraplate magmatism l l Hotspots Rift zones (often associated with hotspots) Intra-oceanic plate: Tholeitic to alkaline series; mostly basalts (OIB = Oceanic Islands Basalts), some differenciated alkaline terms Intra-continental plate: F F either large tholeitic basaltic provinces (CFB = Continental Flood Basalts), occasionally bimodal (ass. with rhyolites) or smaller, alkaline to hyper-alkaline, differenciated intrusions/volcanoes (syenites/phonolites; carbonatites; kimberlites; and more…)

Ocean islands and seamounts Commonly associated with hot spots Figure 14 -1. After Crough (1983) Ann. Rev. Earth Planet. Sci. , 11, 165 -193.

Oceanic islands

Hotspots

Mantle convection and mantle plumes

Types of OIB Magmas l Two principal magma series Tholeiitic series (dominant type) Parental ocean island tholeiitic basalt, or OIT F Similar to MORB, but some distinct chemical and mineralogical differences F l Alkaline series (subordinate) Parental ocean island alkaline basalt, or OIA F Two principal alkaline sub-series s silica undersaturated s slightly silica oversaturated (less common series) F

Hawaiian Scenario Cyclic, pattern to the eruptive history 1. Pre-shield-building stage somewhat alkaline and variable 2. Shield-building stage begins with tremendous outpourings of tholeiitic basalts

Hawaiian Scenario 3. Waning activity more alkaline, episodic, and violent (Mauna Kea, Hualalai, and Kohala). Lavas are also more diverse, with a larger proportion of differentiated liquids 4. A long period of dormancy, followed by a late, post-erosional stage. Characterized by highly alkaline and silica-undersaturated magmas, including alkali basalts, nephelinites, melilite basalts, and basanites

Evolution in the Series Tholeiitic, alkaline, and highly alkaline Figure 14 -2. After Wilson (1989) Igneous Petrogenesis. Kluwer.

Trace Elements l l The LIL trace elements (K, Rb, Cs, Ba, Pb 2+ and Sr) are incompatible and are all enriched in OIB magmas with respect to MORBs The ratios of incompatible elements have been employed to distinguish between source reservoirs F F F N-MORB: the K/Ba ratio is high (usually > 100) E-MORB: the K/Ba ratio is in the mid 30’s OITs range from 25 -40, and OIAs in the upper 20’s Thus all appear to have distinctive sources

Trace Elements l l HFS elements (Th, U, Ce, Zr, Hf, Nb, Ta, and Ti) are also incompatible, and are enriched in OIBs > MORBs Ratios of these elements are also used to distinguish mantle sources F The Zr/Nb ratio s N-MORB generally quite high (>30) s OIBs are low (<10)

Trace Elements: REEs Figure 14 -2. After Wilson (1989) Igneous Petrogenesis. Kluwer.

MORB-normalized Spider Diagrams Figure 14 -3. Winter (2001) An Introduction to Igneous and Metamorphic Petrology. Prentice Hall. Data from Sun and Mc. Donough (1989).

Generation of tholeiitic and alkaline basalts from a chemically uniform mantle Figure 10 -2 After Wyllie, P. J. (1981). Geol. Rundsch. 70, 128 -153.

Ne Pressure effects: E 3 GPa Volatile-free E 2 Gpa Figure 10 -8 After Kushiro (1968), J. Geophys. Res. , 73, 619 -634. d e t ra g) u t sa earin e nd - b lts u ly line asa h b e g Hi eph kali (n al d e t ra alts u t rsa bas e d ic Un leiit tho Fo En E 1 GPa Ab E 1 atm Oversaturated (quartz-bearing) tholeiitic basalts Si. O 2

l l Tholeiites favored by shallower melting F 25% melting at <30 km tholeiite F 25% melting at 60 km olivine basalt Tholeiites favored by greater % partial melting F 20 % melting at 60 km alkaline basalt s F incompatibles (alkalis) initial melts 30 % melting at 60 km tholeiite

$Isotope Geochemistry l l Isotopes do not fractionate during partial melting of fractional melting$

Isotope Geochemistry l l Isotopes do not fractionate during partial melting of fractional melting processes, so will reflect the characteristics of the source OIBs, which sample a great expanse of oceanic mantle in places where crustal contamination is minimal, provide incomparable evidence as to the nature of the mantle

Simple Mixing Models Binary Ternary All analyses fall between two reservoirs as magmas mix All analyses fall within triangle determined by three reservoirs Figure 14 -5. Winter (2001) An Introduction to Igneous and Metamorphic Petrology. Prentice Hall.

Figure 14 -6. After Zindler and Hart (1986), Staudigel et al. (1984), Hamelin et al. (1986) and Wilson (1989).

Mantle Reservoirs 1. DM (Depleted Mantle) = N-MORB source Figure 14 -6. After Zindler and Hart (1986), Staudigel et al. (1984), Hamelin et al. (1986) and Wilson (1989).

2. BSE (Bulk Silicate Earth) or the Primary Uniform Reservoir Figure 14 -6. After Zindler and Hart (1986), Staudigel et al. (1984), Hamelin et al. (1986) and Wilson (1989).

3. EMI = enriched mantle type I has lower 87 Sr/86 Sr (near primordial) 4. EMII = enriched mantle type II has higher 87 Sr/86 Sr (> 0. 720, well above any reasonable mantle sources Figure 14 -6. After Zindler and Hart (1986), Staudigel et al. (1984), Hamelin et al. (1986) and Wilson (1989).

5. PREMA (PREvalent MAntle) Figure 14 -6. After Zindler and Hart (1986), Staudigel et al. (1984), Hamelin et al. (1986) and Wilson (1989).

Figure 14 -6. After Zindler and Hart (1986), Staudigel et al. (1984), Hamelin et al. (1986) and Wilson (1989).

Pb Isotopes Pb produced by radioactive decay of U & Th l 238 U 234 U 206 Pb 235 U 207 Pb 232 Th 208 Pb Pb isotopes also characterize the different reservoirs (see paper presentation Hart 1984) l

Figure 14 -8. After Wilson (1989) Igneous Petrogenesis. Kluwer. Data from Hamelin and Allègre (1985), Hart (1984), Vidal et al. (1984).

Kellogg et al. (1999)

A Model for Oceanic Magmatism Continental Reservoirs DM OIB EM and HIMU from crustal sources (subducted OC + CC seds) Figure 14 -10. Nomenclature from Zindler and Hart (1986). After Wilson (1989) and Rollinson (1993).

“Marble cake” model for mantle convection & mixing

Continental Flood Basalts Large Igneous Provinces (LIPs) l Oceanic plateaus l Some rifts l Continental flood basalts (CFBs) Figure 15 -1. Columbia River Basalts at Hat Point, Snake River area. Cover of Geol. Soc. Amer Special Paper 239. Photo courtesy Steve Reidel.

Trapp volcanism

LIPs (Large Igneous Provinces)

CFB’s l l Associated to major continental break-up … or/and to plume head impact

Figure 15 -2. Flood basalt provinces of Gondwanaland prior to break-up and separation. After Cox (1978) Nature, 274, 47 -49.

Figure 15 -3. Relationship of the Etendeka and Paraná plateau provinces to the Tristan hot spot. After Wilson (1989), Igneous Petrogenesis. Kluwer.

Geochemistry l Deccan traps basalts

Bimodal magmas l Basalts and rhyolites Secondary melting? F Effect of the two eutectics? F

Figure 15 -7. Condrite-normalized rare earth element patterns of some typical CRBG samples. Winter (2001). An Introduction to Igneous and Metamorphic Petrology. Prentice Hall. Data from Hooper and Hawkesworth (1993) J. Petrol. , 34, 1203 -1246.

Figure 15 -13. A model for the origin of the Columbia River Basalt Group From Takahahshi et al. (1998) Earth Planet. Sci. Lett. , 162, 63 -80.

LIPs and mass extinctions

Continental alkaline series Alkali volcanoes – basaltic strombolian cone in front, trachytic pelean dome behind– in the West European rift

Continental alkaline series l l l Rift (or hotspot) related Large diversity (possibly > 80% of the rock names, for <1% volume !) Strange rocks (carbonatites…)

Common features of continental alkali series l l l Alkaline (!) Undersaturated to just oversaturated Peralkaline

Alkaline series Mildly alkaline Strongly alkaline

Figure 18 -2. Alumina saturation classes based on the molar proportions of Al 2 O 3/(Ca. O+Na 2 O+K 2 O) (“A/CNK”) after Shand (1927). Common non-quartzo-feldspathic minerals for each type are included. After Clarke (1992). Granitoid Rocks. Chapman Hall.

Trace elements enriched Figure 19 -5. Chondrite-normalized REE variation diagram for examples of the four magmatic series of the East African Rift (after Kampunzu and Mohr, 1991), Magmatic evolution and petrogenesis in the East African Rift system. In A. B. Kampunzu and R. T. Lubala (eds. ), Magmatism in Extensional Settings, the Phanerozoic African Plate. Springer-Verlag, Berlin, pp. 85 -136. Winter (2001) An Introduction to Igneous and Metamorphic Petrology. Prentice Hall.

Enriched mantle source Figure 19 -3. 143 Nd/144 Nd vs. 87 Sr/86 Sr for East African Rift lavas (solid outline) and xenoliths (dashed). The “cross-hair” intersects at Bulk Earth (after Kampunzu and Mohr, 1991), Magmatic evolution and petrogenesis in the East African Rift system. In A. B. Kampunzu and R. T. Lubala (eds. ), Magmatism in Extensional Settings, the Phanerozoic African Plate. Springer-Verlag, Berlin, pp. 85 -136. Winter (2001) An Introduction to Igneous and Metamorphic Petrology. Prentice Hall.

$Generated from low to very low melt fractions Figure 19 -14. Grid showing the$

Generated from low to very low melt fractions Figure 19 -14. Grid showing the melting products as a function of pressure and % partial melting of model pyrolite mantle with 0. 1% H 2 O. Dashed curves are the stability limits of the minerals indicated. After Green (1970), Phys. Earth Planet. Inter. , 3, 221 -235. Winter (2001) An Introduction to Igneous and Metamorphic Petrology. Prentice Hall.

The alkali eutectic Figure 19 -7. Phase diagram for the system Si. O 2 -Na. Al. Si. O 4 -KAl. Si. O 4 -H 2 O at 1 atm. pressure. Insert shows a T-X section from the silicaundersaturated thermal minimum (Mu) to the silica-oversaturated thermal minimum (M s). that crosses the lowest point (M) on the binary Ab-Or thermal barrier that separates the undersaturated and oversaturated zones. After Schairer and Bowen (1935) Trans. Amer. Geophys. Union, 16 th Ann. Meeting, and Schairer (1950), J. Geol. , 58, 512 -517. Winter (2001) An Introduction to Igneous and Metamorphic Petrology. Prentice Hall.

Diversity of alkaline continental magmas – some examples l l Saturated alkaline series Undersaturated alkaline series Series with a true geological importance Carbonatites Lamprophyres, kimberlites & co. Oddities and curiosities – but economic importance!

Figure 19 -1. Variations in alkali ratios (wt. %) for oceanic (a) and continental (b) alkaline series. The heavy dashed lines distinguish the alkaline magma subdivisions from Figure 8 -14 and the shaded area represents the range for the more common oceanic intraplate series. After Mc. Birney (1993). Igneous Petrology (2 nd ed. ), Jones and Bartlett. Boston. Winter (2001) An Introduction to Igneous and Metamorphic Petrology. Prentice Hall.

Continental Alkaline Magmatism. The East African Rift Figure 19 -2. Map of the East African Rift system (after Kampunzu and Mohr, 1991), Magmatic evolution and petrogenesis in the East African Rift system. In A. B. Kampunzu and R. T. Lubala (eds. ), Magmatism in Extensional Settings, the Phanerozoic African Plate. Springer-Verlag, Berlin, pp. 85 -136. Winter (2001) An Introduction to Igneous and Metamorphic Petrology. Prentice Hall.

East African rift (Afar) – mildly alkaline

Central African Rift – Strongly alkaline

Two main series l Basalts-Trachydandesites-Trachydacites. Rhyolites (stronly bimodal): (just) saturated alkali series A-type granites can be formed there F Role of the preexisting crust? F l Basanite-Foidite (nephelinite)-Phonolite: strongly undersaturated alkali series

Figure 19 -9. Hypothetical cross sections (same vertical and horizontal scales) showing a proposed model for the progressive development of the East African Rift System. a. Pre-rift stage, in which an asthenospheric mantle diapir rises (forcefully or passively) into the lithosphere. Decompression melting (cross-hatch-green indicate areas undergoing partial melting) produces variably alkaline melts. Some partial melting of the metasomatized sub-continental lithospheric mantle (SCLM) may also occur. Reversed decollements (D 1) provide room for the diapir. b. Rift stage: development of continental rifting, eruption of alkaline magmas (red) mostly from a deep asthenospheric source. Rise of hot asthenosphere induces some crustal anatexis. Rift valleys accumulate volcanics and volcaniclastic material. c. Afar stage, in which asthenospheric ascent reaches crustal levels. This is transitional to the development of oceanic crust. Successively higher reversed decollements (D 2 and D 3) accommodate space for the rising diapir. After Kampunzu and Mohr (1991), Magmatic evolution and petrogenesis in the East African Rift system. In A. B. Kampunzu and R. T. Lubala (eds. ), Magmatism in Extensional Settings, the Phanerozoic African Plate. Springer-Verlag, Berlin, pp. 85 -136 and P. Mohr (personal communication). Winter (2001) An Introduction to Igneous and Metamorphic Petrology. Prentice Hall.

Bimodal associations again (the « Daly gap » ) l l l Mantle vs. Crustal sources? Remelting of underplated basalts? Simply an effect of the different eutectics?

The oddities… l l Carbonatites Lamproites, kimberlites, etc.

Chapter 19: Continental Alkaline Magmatism. Carbonatites

Carbonatites Figure 19 -11. Idealized cross section of a carbonatite-alkaline silicate complex with early ijolite cut by more evolved urtite. Carbonatite (most commonly calcitic) intrudes the silicate plutons, and is itself cut by later dikes or cone sheets of carbonatite and ferrocarbonatite. The last events in many complexes are late pods of Fe and REE-rich carbonatites. A fenite aureole surrounds the carbonatite phases and perhaps also the alkaline silicate magmas. After Le Bas (1987) Carbonatite magmas. Mineral. Mag. , 44, 133 -40. Winter (2001) An Introduction to Igneous and Metamorphic Petrology. Prentice Hall.

Chapter 19: Continental Alkaline Magmatism. Carbonatites Figure 19 -15. Silicate-carbonate liquid immiscibility in the system Na 2 O-Ca. O -Si. O 2 -Al 2 O 3 -CO 2 (modified by Freestone and Hamilton, 1980, to incorporate K 2 O, Mg. O, Fe. O, and Ti. O 2). The system is projected from CO 2 for CO 2 -saturated conditions. The dark shaded liquids enclose the miscibility gap of Kjarsgaard and Hamilton (1988, 1989) at 0. 5 GPa, that extends to the alkali-free side (A-A). The lighter shaded liquids enclose the smaller gap (B) of Lee and Wyllie (1994) at 2. 5 GPa. C-C is the revised gap of Kjarsgaard and Hamilton. Dashed tie-lines connect some of the conjugate silicate-carbonate liquid pairs found to coexist in the system. After Lee and Wyllie (1996) International Geology Review, 36, 797819. Winter (2001) An Introduction to Igneous and Metamorphic Petrology. Prentice Hall.

Chapter 19: Continental Alkaline Magmatism. Carbonatites Figure 19 -15. Schematic cross section of an asthenospheric mantle plume beneath a continental rift environment, and the genesis of nephelinitecarbonatites and kimberlitecarbonatites. Numbers correspond to Figure 19 -13. After Wyllie (1989, Origin of carbonatites: Evidence from phase equilibrium studies. In K. Bell (ed. ), Carbonatites: Genesis and Evolution. Unwin Hyman, London. pp. 500 -545) and Wyllie et al. , (1990, Lithos, 26, 3 -19). Winter (2001) An Introduction to Igneous and Metamorphic Petrology. Prentice Hall.

Lamproites and kimberlites l l … many, many rock types … many, many different names – mostly purely local and after the one known occurrence of that rock type (Vosgesite, Wyomingite, …)

Chapter 19: Continental Alkaline Magmatism. Kimberlites

Chapter 19: Continental Alkaline Magmatism. Lamproites Figure 19 -18 a. Initial 87 Sr/86 Sr vs. 143 Nd/144 Nd for lamproites (red-brown) and kimberlites (red). MORB and the Mantle Array are included for reference. After Mitchell and Bergman (1991) Petrology of Lamproites. Plenum. New York. Typical MORB and OIB from Figure 10 -13 for comparison. Winter (2001) An Introduction to Igneous and Metamorphic Petrology. Prentice Hall.

Chapter 19: Continental Alkaline Magmatism. Lamproites Figure 19 -17. Chondrite-normalized rare earth element diagram showing the range of patterns for olivine-, phlogopite-, and madupitic-lamproites from Mitchell and Bergman (1991) Petrology of Lamproites. Plenum. New York. Typical MORB and OIB from Figure 10 -13 for comparison. Winter (2001) An Introduction to Igneous and Metamorphic Petrology. Prentice Hall.

Chapter 19: Continental Alkaline Magmatism. Kimberlites Figure 19 -19. Model of an idealized kimberlite system, illustrating the hypabyssal dike-sill complex leading to a diatreme and tuff ring explosive crater. This model is not to scale, as the diatreme portion is expanded to illustrate it better. From Mitchell (1986) Kimberlites: Mineralogy, Geochemistry, and Petrology. Plenum. New York. Winter (2001) An Introduction to Igneous and Metamorphic Petrology. Prentice Hall.

Chapter 19: Continental Alkaline Magmatism. Kimberlites Figure 19 -20 a. Chondrite-normalized REE diagram for kimberlites, unevolved orangeites, and phlogopite lamproites (with typical OIB and MORB). After Mitchell (1995) Kimberlites, Orangeites, and Related Rocks. Plenum. New York. and Mitchell and Bergman (1991) Petrology of Lamproites. Plenum. New York. Winter (2001) An Introduction to Igneous and Metamorphic Petrology. Prentice Hall.

Chapter 19: Continental Alkaline Magmatism. Kimberlites Figure 19 -20 b. Hypothetical cross section of an Archean craton with an extinct ancient mobile belt (once associated with subduction) and a young rift. The low cratonal geotherm causes the graphite-diamond transition to rise in the central portion. Lithospheric diamonds therefore occur only in the peridotites and eclogites of the deep cratonal root, where they are then incorporated by rising magmas (mostly kimberlitic- “K”). Lithospheric orangeites (“O”) and some lamproites (“L”) may also scavenge diamonds. Melilitites (“M”) are generated by more extensive partial melting of the asthenosphere. Depending on the depth of segregation they may contain diamonds. Nephelinites (“N”) and associated carbonatites develop from extensive partial melting at shallow depths in rift areas. After Mitchell (1995) Kimberlites, Orangeites, and Related Rocks. Plenum. New York. Winter (2001) An Introduction to Igneous and Metamorphic Petrology. Prentice Hall.