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Tonalite–trondhjemite–granodiorite

August 21, 2023

Tonalite–trondhjemite–granodiorite (TTG) rocks are intrusive rocks with typical granitic composition (quartz and feldspar) but containing only a small portion of potassium feldspar. Tonalite, trondhjemite, and granodiorite often occur together in geological records, indicating similar petrogenetic processes.[1] Post Archean (after 2.5 Ga) TTG rocks are present in arc-related batholiths, as well as in ophiolites (although of a small proportion), while Archean TTG rocks are major components of Archean cratons.[2][1]

Archean TTG rock outcrop in Kongling Complex, South China Craton. The white TTG rock body is intruded by dark mafic dikes, as well as light color felsic dikes. The mafic minerals in the TTG rock body, possibly biotite, were weathered, which introduced a brownish coating on the TTG rock surface.

Composition

The quartz percentage among felsic minerals in TTG rocks is usually larger than 20% but less than 60%.[1] In tonalite and trondhjemite, more than 90% of the feldspars are plagioclase, while in granodiorite, this number is between 65% and 90%.[1] Trondhjemite is a special kind of tonalite, with most of the plagioclase in the rock being oligoclase.[3] The major accessory minerals of TTG rocks include biotite, amphiboles (e.g. hornblende), epidote, and zircon.[1] Geochemically, TTG rocks often have a high silica (SiO2) content (commonly over 70 percent SiO2), high sodium oxide (Na2O) content (with low potassium oxide/Na2O ratio) compared to other plutonic rocks, and low ferromagnesian element content (the weight percentage of iron(III) oxide, magnesium oxide, manganese dioxide, and titanium dioxide added together commonly smaller than 5%).[4]

Post Archean TTG Rocks

Post Archean TTG rocks are commonly found in arc settings, especially in continental arcs.[1] Ophiolite also contains a small amount of TTG rocks.[1]

Continental arc TTG rocks

Continental arc TTG rocks are often associated with gabbro, diorite, and granite, which forms a plutonic sequence in batholiths.[5] They are formed by hundred of plutons that directly related to subduction.[5] For example, Coastal Batholith of Peru consists of 7 ~ 16% gabbro and diorite, 48 ~ 60% tonalite (including trondhjemite), and 20 ~ 30% granodiorite, with 1 ~ 4% granite.[6] These TTG rocks in continental arc batholiths may partially originate from the magma differentiation (i.e. fractional crystallisation) of the subduction induced mantle wedge melt at depth.[7] However, the large volume of such TTG rocks infer their major generation mechanism is by the crustal thickening induced partial melting of the former gabbroic underplate at the base of the continental crust.[1] Tonalitic composition rock crystallised first before the magma differentiated to granodioritic and later granitic composition at a shallow depth. Some island arc plutonic roots also have TTG rocks, e.g. Tobago, but they are rarely exposed.[8]

TTG rocks in ophiolite

Tonalites (including trondhjemites) can be found above the layered gabbro section in ophiolites, below or within sheeted dykes.[5] They are often irregular in shape and produced by magma differentiation.[5]

Archean TTG rocks

 
TTG rock sample (Tsawela gneiss) with foliation from the Kaapvaal Craton, South Africa. The white minerals are plagioclase; the light grey ones are quartz; the dark, greenish ones are biotite and hornblende, which developed foliation.

Archean TTG rocks appear to be strongly deformed grey gneiss, showing banding, lineation, and other metamorphic structures, whose protoliths were intrusive rocks.[4] TTG rock is one of the major rock types in Archean cratons.[4]

Geochemical features

In terms of trace element characteristics, Archean TTGs exhibit high light rare earth element (LREE) content yet low heavy rare earth element (HREE) content. However, they do not show Eu and Sr anomalies.[9] These features indicate the presence of garnet and amphibole, but no plagioclase in the residual phase during partial melting or precipitation phase during fractional crystallization.

Petrogenesis and classification

Confirmed by geochemical modelling, TTG type magma can be generated through partial melting of hydrated meta-mafic rocks.[10] To produce the very low HREE pattern, the melting should be conducted under a garnet-stable pressure-temperature field.[4] Given that garnet temperature stability rises dramatically with increasing pressure, strongly HREE-depleted TTG melts are expected to form under relatively high pressure.[11] Besides the source composition and the pressure, the degree of melting and temperature also influence the melt composition.[4]

Detailed studies classified Archean TTGs into three groups based on geochemical features, that are low, medium, and high pressure TTGs, although the three groups form a continuous evolution.[12] The low pressure subseries shows relatively low Al2O3, Na2O, Sr content and relatively high Y, Yb, Ta, and Nb content, corresponding to melting under 10-12 kbar with the source rock mineral assembly of plagioclase, pyroxene and possibly amphibole or garnet.[12] The high pressure group shows the opposite geochemical features, corresponding to melting at a pressure over 20 kbar, with the source rock containing garnet and rutile but no amphibolite or plagioclase.[12] The medium pressure group has transitional features between the other two groups, corresponding to melting under a pressure around 15 kbar with the source rock containing amphibole, much garnet, but little rutile and no plagioclase.[12] Medium pressure TTGs are the most abundant among the three groups.[12]

Geodynamic settings

The geodynamic setting of the Archean TTG rock generation is currently not well understood. Competing hypotheses include subduction related generation involving plate tectonics and other non-plate tectonic models.

Plate tectonic setting

 
Hypothesized Archean hot subduction induced Archean TTG generation model. The heavier oceanic crust sinks into the lighter mantle. The subducting slab is young and hot, thus when it is heated, it partially melts to generate TTG magmas, which rise and intrude into the continental crust. Light green: continental crust; dark green: oceanic crust; red: TTG melts; orange: mantle. Modified from Moyen & Martin, 2012.[4]

Geochemical similarity shared between TTGs and adakites have long been noted by researchers.[13][14][15][11][4] Adakites are one type of modern arc lavas, which differ from common arc lavas (mostly granitoids) in their felsic and sodic nature with high LREE but low HREE content.[16] Their production is interpreted to be the partial melting of young and hot subducting oceanic slabs with minor interaction with surrounding mantle wedges, rather than mantle wedge melts like other arc-granitoids.[16] Based on geochemical features (e.g. Mg, Ni, and Cr contents), adakites can be further divided into two groups, namely high SiO2 adakites (HSA) and low SiO2 adakites (LSA). It was then noted that the Archean TTGs were geochemically almost identical to high silica adakites (HSA), but slightly different from low silica adakites (LSA).[15]

This geochemical similarity let some researchers infer that the geodynamic setting of Archean TTGs was analogous to that of modern adakites.[15] They think that Archean TTGs were generated by hot subduction as well. Although modern adakites are rare and only found in a few localities (e.g. Adak Island in Alaska and Mindanao in the Philippines), they argue that due to a higher mantle potential temperature of the Earth, a hotter and softer crust may have enabled intense adakite-type subduction during Archean time.[15] TTGs packages were then generated in such settings, with large scale proto-continents formed by collisions at a later stage.[15] However, other authors doubt the existence of Archean subduction by pointing out the absence of major plate tectonic indicators during most of the Archean Eon.[17] It is also noted that Archean TTGs were intrusive rocks while the modern adakite is extrusive in nature, thus their magma should differ in composition, especially in water content.[18]

Non-plate tectonic settings

 
The delamination and underplating induced Archean TTG generation models. In the upper figure, heavier mafic crust delaminates into the lighter mantle. The pressure and temperature increases induce the partial melting of the delaminated mafic block to generate TTG magma, which rises and intrudes to the crust. In the lower figure, mantle plume rises to the base of the mafic crust and thicken the crust. The partial melting of the mafic crust due to the plume heating generates TTG magma intrusions. Modified from Moyen & Martin, 2012.[4]

Various evidence has shown that Archean TTG rocks were directly derived from preexisting mafic materials.[19][20][21] The melting temperature of meta-mafic rocks (generally between 700 °C and 1000 °C) depends primarily on their water content but only a little on pressure.[12] Different groups of TTG should therefore have experienced distinct geothermal gradients, which corresponding to different geodynamic settings.

The low pressure group has formed along geotherms around 20-30 °C/km, which are comparable to those during the underplating of plateau bases.[12] Mantle upwellings add mafic basement to the crust and the pressure due to the cumulation thickness may reach the requirement of low pressure TTG production.[4][12] The partial melting of the plateau base (which can be induced by further mantle upwelling) would then lead to low pressure TTG generation.[22]

The high pressure TTGs have experienced geotherms lower than 10 °C/km, which are close to modern hot subduction geotherms experienced by young slabs (but around 3 °C/km hotter than other modern subduction zones), whilst the geotherms for the most abundant TTG subseries, medium pressure group, are between 12 and 20 °C/km.[12] Other than hot subduction, such geotherms may also be possible during the delamination of mafic crustal base.[12] The delamination may be attributed to mantle downwelling[23] or an increase in density of the mafic crustal base due to metamorphism or partial melt extraction.[24] Those delaminated meta-mafic bodies then sink down, melt, and interact with surrounding mantle to generate TTGs. Such delamination induced TTG generation process is petrogenetically similar to that of subduction, both of which involves deep burial of mafic rocks into the mantle.[4][12][21]

See also

References

  1. ^ a b c d e f g h J. D., Winter (2013). Principles of igneous and metamorphic petrology. Pearson Education.
  2. ^ Hernández-Montenegro, Juan David; Palin, Richard M.; Zuluaga, Carlos A.; Hernández-Uribe, David (4 March 2021). "Archean continental crust formed by magma hybridization and voluminous partial melting". Scientific Reports. 11 (1): 5263. doi:10.1038/s41598-021-84300-y. PMC 7933273. PMID 33664326.
  3. ^ Barker, F. (1979), "Trondhjemite: Definition, Environment and Hypotheses of Origin", Trondhjemites, Dacites, and Related Rocks, Developments in Petrology, vol. 6, Elsevier, pp. 1–12, doi:10.1016/b978-0-444-41765-7.50006-x, ISBN 9780444417657
  4. ^ a b c d e f g h i j Moyen, Jean-François; Martin, Hervé (September 2012). "Forty years of TTG research". Lithos. 148: 312–336. Bibcode:2012Litho.148..312M. doi:10.1016/j.lithos.2012.06.010. ISSN 0024-4937.
  5. ^ a b c d M. G., Best (2003). Igneous and metamorphic petrology. Blackwell Publishers.
  6. ^ Pitcher, W. S. (March 1978). "The anatomy of a batholith". Journal of the Geological Society. 135 (2): 157–182. Bibcode:1978JGSoc.135..157P. doi:10.1144/gsjgs.135.2.0157. ISSN 0016-7649. S2CID 130036558.
  7. ^ Best, Myron G. (2013). Igneous and metamorphic petrology. John Wiley & Sons.
  8. ^ Frost, B. R.; Frost, C. D. (2013). "Essentials of igneous and metamorphic petrology". American Mineralogist. 100 (7): 1655. Bibcode:2015AmMin.100.1655K. doi:10.2138/am-2015-657.
  9. ^ Martin, H. (1986-09-01). "Effect of steeper Archean geothermal gradient on geochemistry of subduction-zone magmas". Geology. 14 (9): 753. Bibcode:1986Geo....14..753M. doi:10.1130/0091-7613(1986)14<753:eosagg>2.0.co;2. ISSN 0091-7613.
  10. ^ Johnson, Tim E.; Brown, Michael; Kaus, Boris J. P.; VanTongeren, Jill A. (2013-12-01). "Delamination and recycling of Archaean crust caused by gravitational instabilities". Nature Geoscience. 7 (1): 47–52. Bibcode:2014NatGe...7...47J. doi:10.1038/ngeo2019. hdl:20.500.11937/31170. ISSN 1752-0894.
  11. ^ a b Foley, Stephen; Tiepolo, Massimo; Vannucci, Riccardo (June 2002). "Growth of early continental crust controlled by melting of amphibolite in subduction zones". Nature. 417 (6891): 837–840. Bibcode:2002Natur.417..837F. doi:10.1038/nature00799. ISSN 0028-0836. PMID 12075348. S2CID 4394308.
  12. ^ a b c d e f g h i j k Moyen, Jean-François (April 2011). "The composite Archaean grey gneisses: Petrological significance, and evidence for a non-unique tectonic setting for Archaean crustal growth". Lithos. 123 (1–4): 21–36. Bibcode:2011Litho.123...21M. doi:10.1016/j.lithos.2010.09.015. ISSN 0024-4937.
  13. ^ Martin, H., 1986, Effect of steeper Archean geothermal gradient on geochemistry of subduction zone-magmas: Geology, v. 14, p. 753-756.
  14. ^ Drummond, M. S. and Defant, M. J., 1990, A model for tronhjemite-tonalite-dacite genesis and crustal growth via slab melting: Archean to modern comparisons: J. Geophysical Res., v. 95, p. 21,503 - 21,521.
  15. ^ a b c d e Martin, H.; Smithies, R.H.; Rapp, R.; Moyen, J.-F.; Champion, D. (January 2005). "An overview of adakite, tonalite–trondhjemite–granodiorite (TTG), and sanukitoid: relationships and some implications for crustal evolution". Lithos. 79 (1–2): 1–24. Bibcode:2005Litho..79....1M. doi:10.1016/j.lithos.2004.04.048. ISSN 0024-4937.
  16. ^ a b Defant, Marc J.; Drummond, Mark S. (October 1990). "Derivation of some modern arc magmas by melting of young subducted lithosphere". Nature. 347 (6294): 662–665. Bibcode:1990Natur.347..662D. doi:10.1038/347662a0. ISSN 0028-0836. S2CID 4267494.
  17. ^ Condie, K. C., & Kröner, A. (2008). When did plate tectonics begin? Evidence from the geologic record. In When did plate tectonics begin on planet Earth (Vol. 440, pp. 281-294). Geological Society of America Special Papers.
  18. ^ Clemens, J.D; Droop, G.T.R (October 1998). "Fluids, P–T paths and the fates of anatectic melts in the Earth's crust". Lithos. 44 (1–2): 21–36. Bibcode:1998Litho..44...21C. doi:10.1016/s0024-4937(98)00020-6. ISSN 0024-4937.
  19. ^ Johnson, Tim E.; Brown, Michael; Gardiner, Nicholas J.; Kirkland, Christopher L.; Smithies, R. Hugh (2017-02-27). "Earth's first stable continents did not form by subduction". Nature. 543 (7644): 239–242. Bibcode:2017Natur.543..239J. doi:10.1038/nature21383. ISSN 0028-0836. PMID 28241147. S2CID 281446.
  20. ^ Kemp, A.I.S.; Wilde, S.A.; Hawkesworth, C.J.; Coath, C.D.; Nemchin, A.; Pidgeon, R.T.; Vervoort, J.D.; DuFrane, S.A. (July 2010). "Hadean crustal evolution revisited: New constraints from Pb–Hf isotope systematics of the Jack Hills zircons". Earth and Planetary Science Letters. 296 (1–2): 45–56. Bibcode:2010E&PSL.296...45K. doi:10.1016/j.epsl.2010.04.043. ISSN 0012-821X.
  21. ^ a b Moyen, Jean-François; Laurent, Oscar (March 2018). "Archaean tectonic systems: A view from igneous rocks". Lithos. 302–303: 99–125. Bibcode:2018Litho.302...99M. doi:10.1016/j.lithos.2017.11.038. ISSN 0024-4937.
  22. ^ Smithies, R.H.; Champion, D.C.; Van Kranendonk, M.J. (2009-05-15). "Formation of Paleoarchean continental crust through infracrustal melting of enriched basalt". Earth and Planetary Science Letters. 281 (3–4): 298–306. Bibcode:2009E&PSL.281..298S. doi:10.1016/j.epsl.2009.03.003. ISSN 0012-821X.
  23. ^ Kröner, A.; Layer, P. W. (1992-06-05). "Crust Formation and Plate Motion in the Early Archean". Science. 256 (5062): 1405–1411. Bibcode:1992Sci...256.1405K. doi:10.1126/science.256.5062.1405. ISSN 0036-8075. PMID 17791608. S2CID 35201760.
  24. ^ Bédard, Jean H. (March 2006). "A catalytic delamination-driven model for coupled genesis of Archaean crust and sub-continental lithospheric mantle". Geochimica et Cosmochimica Acta. 70 (5): 1188–1214. Bibcode:2006GeCoA..70.1188B. doi:10.1016/j.gca.2005.11.008. ISSN 0016-7037.

August 21, 2023
tonalite, trondhjemite, granodiorite, rocks, intrusive, rocks, with, typical, granitic, composition, quartz, feldspar, containing, only, small, portion, potassium, feldspar, tonalite, trondhjemite, granodiorite, often, occur, together, geological, records, ind. Tonalite trondhjemite granodiorite TTG rocks are intrusive rocks with typical granitic composition quartz and feldspar but containing only a small portion of potassium feldspar Tonalite trondhjemite and granodiorite often occur together in geological records indicating similar petrogenetic processes 1 Post Archean after 2 5 Ga TTG rocks are present in arc related batholiths as well as in ophiolites although of a small proportion while Archean TTG rocks are major components of Archean cratons 2 1 Archean TTG rock outcrop in Kongling Complex South China Craton The white TTG rock body is intruded by dark mafic dikes as well as light color felsic dikes The mafic minerals in the TTG rock body possibly biotite were weathered which introduced a brownish coating on the TTG rock surface Contents 1 Composition 2 Post Archean TTG Rocks 2 1 Continental arc TTG rocks 2 2 TTG rocks in ophiolite 3 Archean TTG rocks 3 1 Geochemical features 3 2 Petrogenesis and classification 3 3 Geodynamic settings 3 3 1 Plate tectonic setting 3 3 2 Non plate tectonic settings 4 See also 5 ReferencesComposition EditThe quartz percentage among felsic minerals in TTG rocks is usually larger than 20 but less than 60 1 In tonalite and trondhjemite more than 90 of the feldspars are plagioclase while in granodiorite this number is between 65 and 90 1 Trondhjemite is a special kind of tonalite with most of the plagioclase in the rock being oligoclase 3 The major accessory minerals of TTG rocks include biotite amphiboles e g hornblende epidote and zircon 1 Geochemically TTG rocks often have a high silica SiO2 content commonly over 70 percent SiO2 high sodium oxide Na2O content with low potassium oxide Na2O ratio compared to other plutonic rocks and low ferromagnesian element content the weight percentage of iron III oxide magnesium oxide manganese dioxide and titanium dioxide added together commonly smaller than 5 4 Post Archean TTG Rocks EditPost Archean TTG rocks are commonly found in arc settings especially in continental arcs 1 Ophiolite also contains a small amount of TTG rocks 1 Continental arc TTG rocks Edit Continental arc TTG rocks are often associated with gabbro diorite and granite which forms a plutonic sequence in batholiths 5 They are formed by hundred of plutons that directly related to subduction 5 For example Coastal Batholith of Peru consists of 7 16 gabbro and diorite 48 60 tonalite including trondhjemite and 20 30 granodiorite with 1 4 granite 6 These TTG rocks in continental arc batholiths may partially originate from the magma differentiation i e fractional crystallisation of the subduction induced mantle wedge melt at depth 7 However the large volume of such TTG rocks infer their major generation mechanism is by the crustal thickening induced partial melting of the former gabbroic underplate at the base of the continental crust 1 Tonalitic composition rock crystallised first before the magma differentiated to granodioritic and later granitic composition at a shallow depth Some island arc plutonic roots also have TTG rocks e g Tobago but they are rarely exposed 8 TTG rocks in ophiolite Edit Tonalites including trondhjemites can be found above the layered gabbro section in ophiolites below or within sheeted dykes 5 They are often irregular in shape and produced by magma differentiation 5 Archean TTG rocks Edit TTG rock sample Tsawela gneiss with foliation from the Kaapvaal Craton South Africa The white minerals are plagioclase the light grey ones are quartz the dark greenish ones are biotite and hornblende which developed foliation Archean TTG rocks appear to be strongly deformed grey gneiss showing banding lineation and other metamorphic structures whose protoliths were intrusive rocks 4 TTG rock is one of the major rock types in Archean cratons 4 Geochemical features Edit In terms of trace element characteristics Archean TTGs exhibit high light rare earth element LREE content yet low heavy rare earth element HREE content However they do not show Eu and Sr anomalies 9 These features indicate the presence of garnet and amphibole but no plagioclase in the residual phase during partial melting or precipitation phase during fractional crystallization Petrogenesis and classification Edit Confirmed by geochemical modelling TTG type magma can be generated through partial melting of hydrated meta mafic rocks 10 To produce the very low HREE pattern the melting should be conducted under a garnet stable pressure temperature field 4 Given that garnet temperature stability rises dramatically with increasing pressure strongly HREE depleted TTG melts are expected to form under relatively high pressure 11 Besides the source composition and the pressure the degree of melting and temperature also influence the melt composition 4 Detailed studies classified Archean TTGs into three groups based on geochemical features that are low medium and high pressure TTGs although the three groups form a continuous evolution 12 The low pressure subseries shows relatively low Al2O3 Na2O Sr content and relatively high Y Yb Ta and Nb content corresponding to melting under 10 12 kbar with the source rock mineral assembly of plagioclase pyroxene and possibly amphibole or garnet 12 The high pressure group shows the opposite geochemical features corresponding to melting at a pressure over 20 kbar with the source rock containing garnet and rutile but no amphibolite or plagioclase 12 The medium pressure group has transitional features between the other two groups corresponding to melting under a pressure around 15 kbar with the source rock containing amphibole much garnet but little rutile and no plagioclase 12 Medium pressure TTGs are the most abundant among the three groups 12 Geodynamic settings Edit The geodynamic setting of the Archean TTG rock generation is currently not well understood Competing hypotheses include subduction related generation involving plate tectonics and other non plate tectonic models Plate tectonic setting Edit Hypothesized Archean hot subduction induced Archean TTG generation model The heavier oceanic crust sinks into the lighter mantle The subducting slab is young and hot thus when it is heated it partially melts to generate TTG magmas which rise and intrude into the continental crust Light green continental crust dark green oceanic crust red TTG melts orange mantle Modified from Moyen amp Martin 2012 4 Geochemical similarity shared between TTGs and adakites have long been noted by researchers 13 14 15 11 4 Adakites are one type of modern arc lavas which differ from common arc lavas mostly granitoids in their felsic and sodic nature with high LREE but low HREE content 16 Their production is interpreted to be the partial melting of young and hot subducting oceanic slabs with minor interaction with surrounding mantle wedges rather than mantle wedge melts like other arc granitoids 16 Based on geochemical features e g Mg Ni and Cr contents adakites can be further divided into two groups namely high SiO2 adakites HSA and low SiO2 adakites LSA It was then noted that the Archean TTGs were geochemically almost identical to high silica adakites HSA but slightly different from low silica adakites LSA 15 This geochemical similarity let some researchers infer that the geodynamic setting of Archean TTGs was analogous to that of modern adakites 15 They think that Archean TTGs were generated by hot subduction as well Although modern adakites are rare and only found in a few localities e g Adak Island in Alaska and Mindanao in the Philippines they argue that due to a higher mantle potential temperature of the Earth a hotter and softer crust may have enabled intense adakite type subduction during Archean time 15 TTGs packages were then generated in such settings with large scale proto continents formed by collisions at a later stage 15 However other authors doubt the existence of Archean subduction by pointing out the absence of major plate tectonic indicators during most of the Archean Eon 17 It is also noted that Archean TTGs were intrusive rocks while the modern adakite is extrusive in nature thus their magma should differ in composition especially in water content 18 Non plate tectonic settings Edit The delamination and underplating induced Archean TTG generation models In the upper figure heavier mafic crust delaminates into the lighter mantle The pressure and temperature increases induce the partial melting of the delaminated mafic block to generate TTG magma which rises and intrudes to the crust In the lower figure mantle plume rises to the base of the mafic crust and thicken the crust The partial melting of the mafic crust due to the plume heating generates TTG magma intrusions Modified from Moyen amp Martin 2012 4 Various evidence has shown that Archean TTG rocks were directly derived from preexisting mafic materials 19 20 21 The melting temperature of meta mafic rocks generally between 700 C and 1000 C depends primarily on their water content but only a little on pressure 12 Different groups of TTG should therefore have experienced distinct geothermal gradients which corresponding to different geodynamic settings The low pressure group has formed along geotherms around 20 30 C km which are comparable to those during the underplating of plateau bases 12 Mantle upwellings add mafic basement to the crust and the pressure due to the cumulation thickness may reach the requirement of low pressure TTG production 4 12 The partial melting of the plateau base which can be induced by further mantle upwelling would then lead to low pressure TTG generation 22 The high pressure TTGs have experienced geotherms lower than 10 C km which are close to modern hot subduction geotherms experienced by young slabs but around 3 C km hotter than other modern subduction zones whilst the geotherms for the most abundant TTG subseries medium pressure group are between 12 and 20 C km 12 Other than hot subduction such geotherms may also be possible during the delamination of mafic crustal base 12 The delamination may be attributed to mantle downwelling 23 or an increase in density of the mafic crustal base due to metamorphism or partial melt extraction 24 Those delaminated meta mafic bodies then sink down melt and interact with surrounding mantle to generate TTGs Such delamination induced TTG generation process is petrogenetically similar to that of subduction both of which involves deep burial of mafic rocks into the mantle 4 12 21 See also EditEoarchean geology Archean subductionReferences Edit a b c d e f g h J D Winter 2013 Principles of igneous and metamorphic petrology Pearson Education Hernandez Montenegro Juan David Palin Richard M Zuluaga Carlos A Hernandez Uribe David 4 March 2021 Archean continental crust formed by magma hybridization and voluminous partial melting Scientific Reports 11 1 5263 doi 10 1038 s41598 021 84300 y PMC 7933273 PMID 33664326 Barker F 1979 Trondhjemite Definition Environment and Hypotheses of Origin Trondhjemites Dacites and Related Rocks Developments in Petrology vol 6 Elsevier pp 1 12 doi 10 1016 b978 0 444 41765 7 50006 x ISBN 9780444417657 a b c d e f g h i j Moyen Jean Francois Martin Herve September 2012 Forty years of TTG research Lithos 148 312 336 Bibcode 2012Litho 148 312M doi 10 1016 j lithos 2012 06 010 ISSN 0024 4937 a b c d M G Best 2003 Igneous and metamorphic petrology Blackwell Publishers Pitcher W S March 1978 The anatomy of a batholith Journal of the Geological Society 135 2 157 182 Bibcode 1978JGSoc 135 157P doi 10 1144 gsjgs 135 2 0157 ISSN 0016 7649 S2CID 130036558 Best Myron G 2013 Igneous and metamorphic petrology John Wiley amp Sons Frost B R Frost C D 2013 Essentials of igneous and metamorphic petrology American Mineralogist 100 7 1655 Bibcode 2015AmMin 100 1655K doi 10 2138 am 2015 657 Martin H 1986 09 01 Effect of steeper Archean geothermal gradient on geochemistry of subduction zone magmas Geology 14 9 753 Bibcode 1986Geo 14 753M doi 10 1130 0091 7613 1986 14 lt 753 eosagg gt 2 0 co 2 ISSN 0091 7613 Johnson Tim E Brown Michael Kaus Boris J P VanTongeren Jill A 2013 12 01 Delamination and recycling of Archaean crust caused by gravitational instabilities Nature Geoscience 7 1 47 52 Bibcode 2014NatGe 7 47J doi 10 1038 ngeo2019 hdl 20 500 11937 31170 ISSN 1752 0894 a b Foley Stephen Tiepolo Massimo Vannucci Riccardo June 2002 Growth of early continental crust controlled by melting of amphibolite in subduction zones Nature 417 6891 837 840 Bibcode 2002Natur 417 837F doi 10 1038 nature00799 ISSN 0028 0836 PMID 12075348 S2CID 4394308 a b c d e f g h i j k Moyen Jean Francois April 2011 The composite Archaean grey gneisses Petrological significance and evidence for a non unique tectonic setting for Archaean crustal growth Lithos 123 1 4 21 36 Bibcode 2011Litho 123 21M doi 10 1016 j lithos 2010 09 015 ISSN 0024 4937 Martin H 1986 Effect of steeper Archean geothermal gradient on geochemistry of subduction zone magmas Geology v 14 p 753 756 Drummond M S and Defant M J 1990 A model for tronhjemite tonalite dacite genesis and crustal growth via slab melting Archean to modern comparisons J Geophysical Res v 95 p 21 503 21 521 a b c d e Martin H Smithies R H Rapp R Moyen J F Champion D January 2005 An overview of adakite tonalite trondhjemite granodiorite TTG and sanukitoid relationships and some implications for crustal evolution Lithos 79 1 2 1 24 Bibcode 2005Litho 79 1M doi 10 1016 j lithos 2004 04 048 ISSN 0024 4937 a b Defant Marc J Drummond Mark S October 1990 Derivation of some modern arc magmas by melting of young subducted lithosphere Nature 347 6294 662 665 Bibcode 1990Natur 347 662D doi 10 1038 347662a0 ISSN 0028 0836 S2CID 4267494 Condie K C amp Kroner A 2008 When did plate tectonics begin Evidence from the geologic record In When did plate tectonics begin on planet Earth Vol 440 pp 281 294 Geological Society of America Special Papers Clemens J D Droop G T R October 1998 Fluids P T paths and the fates of anatectic 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