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Library » Research Skills » Lent Reading List - Option 8

Lent Reading List - Option 8: Oceanic and Continental Margins

Please note that if references are marked with an asterisk (*) , they have been highlighted by your lecturers as being particularly useful to you.

Journal References

If available online the journal title will be linked to ABSTRACT LEVEL. You will have the option to download full-text or pdfs.

A number of these references will be available in the part II/III reprint collection housed in the Library Office. A full listing of what is in this collection is available on the Library website.

Lecture One

R S White

• Campbell, I. H. (2007). Testing the plume theory, Chemical Geology, 241, 153-176. 
• Courtney, R.C. & White, R.S. (1986). Anomalous heat flow and geoid across the Cape Verde Rise: evidence for dynamic support from a thermal plume in the mantle. Geophysical Journal of the Royal Astronomical Society , 87, 815-868.
•  Jones, S. M., White, N. J. & Maclennan, J. C. (2002). V-shaped ridges around Iceland: implications for spatial and temporal patterns of mantle convection, G3 Geochemistry Geophysics Geosystems, 10.1029, Pages: 2002GC000361 .
• Kent, G. M., Singh, S. C., Harding, A. J., Sinha, M. C., Orcutt, J. A., Barton,  P. J., White,  R. S.,  Bazin, S. K., Hobbs,  R. W., Tong,  C. H. & Pye,  J. W. (2000). Evidence from three-dimensional seismic reflectivity images for enhanced melt supply beneath mid-ocean-ridge discontinuities. Nature, 406, 614–618.
• Watson, S. & McKenzie, D. (1991). Melt generation by plumes: a study of Hawaiian volcanism. Journal of Petrology , 32, 501-537.
• White, R. S., Bown, J. W. & Smallwood, J. R. (1995). The temperature of the Iceland plume and origin of outward propagating V-shaped ridges. Journal of the Geological Society, London, 152, 1039-1045
• White, R.S. McKenzie, D. & O’Nions, R.K. (1992). Oceanic crustal thickness from seismic measurements and rare earth element inversions. Journal of Geophysical Research , 97, 19,683- 19,715.
• White, R. S. (1997). Rift-plume interaction in the North Atlantic. Philosophical Transactions of the Royal Society, London, Series A , 355, 3 19—339

Lecture Two

R S White

• Bown, J. W. & White, R. S. (1994). Variation with spreading rate of oceanic crustal thickness and geochemistry. Earth and Planetary Science Letters , 121,435—449.
• Dick, HJB, Lin, J & Schouten, H (2003), An ultraslow-spreading class of ocean ridge, Nature , vol. 426, pp. 405-412
• Katz, R. F. (2010), Porosity-driven convection and asymmetry beneath mid-ocean ridges, Geochem. Geophys. Geosyst., 11, Q0AC07, doi:10.1029/2010GC003282.
• White, R. S., Minshull, T. A., Bickle, M. J. & Robinson, C. J. (2001). Melt generation at very slow-spreading oceanic ridges: constraints from geochemical and geophysical data. Journal of Petrology , 42, 1171—1196.

Lecture Three

R S White

• Barton, A.J. & White, R.S. 1997). Crustal structure of the Edoras Bank continental margin and mantle thermal anomalies beneath the North Atlantic. Journal of Geophysical Research , 102, 3,109-3,129.(Contains review of structure of North Atlantic margins at end of paper.)
• Barton, A.J. & White, R.S. (1997). Volcanism on the Rockall continental margin. Journal of the Geological Society of London , 154, 53 1-536.(Short paper with good figures of seismic profiles across seaward dipping reflectors).
  
• Coffin, M F & Eldholm,  1994. Large igneous provinces: Crustal structure, dimensions, and external consequences. Reviews of Geophysics, 32, p. 1-36. (review article)
• White, R.S. (1992 ). Crustal structure and magmatism of North Atlantic continental margins. J. Geol. Soc ., 149, 841-854.(Review of volcanic and non-volcanic continental margins in the North Atlantic and the effect of mantle temperature on magmatism).
  
• *White R. S.  L. K. Smith, A. W. Roberts, P. A. F. Christie, N. J. Kusznir & the rest of the iSIMM Team Lower-crustal intrusion on the North Atlantic continental margin Nature 452, 460-464 plus supplementary information at www.nature.com, doi:10.1038/nature06687
• *White, R. S. & Smith, L. K. (2009). Crustal structure of the Hatton and the conjugate east Greenland rifted volcanic continental margins, NE Atlantic, Journal of Geophysical Research, 114, B02305, doi:10.1029/2008JB005856
• *White, R. & McKenzie, D. (1989). Magmatism at rift zones: The generation of volcanic continental margins and flood basalts. Journal of Geophysical Researc h, 94, 7,685-7,729.(A global review of volcanic continental margins and the concomitant flood basalts).
• White, R.S. & McKenzie, D.P. (1989). Volcanism at rifts, Scientific American , July 1989, 261, 62-71 (An easy read which summarises much of the material in the paper listed above)
• *White R. S. & D. McKenzie (1995). Mantle plumes and flood basalts. Journal of Geophysical Research, 100,  17,543-17,585, 1995 (Shows how depth of melting can be derived from re analysis of flood basalts.)

Lecture Four

R S White

• *White, R. & McKenzie, D. (1989). Magmatism at rift zones: The generation of volcanic continental margins and flood basalts. Journal of Geophysical Researc h, 94, 7,685-7,729.
• White, R.S. & McKenzie, D.P. (1989). Volcanism at rifts, Scientific American , July, 261, 62-71
• Coffin, M F & Eldholm, 0 (1994) Large igneous provinces: Crustal structure, dimensions, and external consequences. Reviews of Geophysics, 32, p. 1-36.
• Mahoney, J J & Coffin, M F (eds.) (1997) Large Igneous Provinces: Continental, Oceanic and, Planetary Flood Volcanism. Geophysical Monograph, 100.
• White, R.S. (1992 ). Crustal structure and magmatism of North Atlantic continental margins. J. Geol. Soc ., 149, 841-854.
• *White, R.S. & McKenzie, D. (1995). Mantle plumes and flood basalts. Journal of Geophysical Research , 100, 17,543-17,585.
• Barton, A.J. & White, R.S. (1997). Crustal structure of the Edoras Bank continental margin and mantle thermal anomalies beneath the North Atlantic. Journal of Geophysical Research , 102, 3,109-3,129.
• Barton, A.J. & White, R.S. (1997). Volcanism on the Rockall continental margin. Journal of the Geological Society of London , 154, 53 1-536.
• White, R.S. (1997). Mantle plume origin for the Karoo and Ventersdorp flood basalts, South Africa. South African Journal of Geology , 100, 27 1-282.
• Hopper, J. R., Dahl-Jensen, T., Holbrook, W. S., Larsen, H. C., Lizarralde, D., Korenaga, J., Kent, , G. M., & Kelemen, P. B. (2003). Structure of the SE Greenland margin from seismic reflection and refraction data: Implications for nascent spreading center subsidence and asymmetric crustal accretion during North Atlantic opening. Journal of Geophysical Research , 108, B5: 2269—2291.

Lecture Five

R S White

• Bown, J.W. & White, R.S. (1995). Effect of finite extension rate on melt generation at rifted continental margins. J. Geophys. Res ., 100, 18,011-18,029.
• ODP Leg 173 Shipboard Scientific Party (1998). Drilling reveals transition from continental breakup to early magmatic crust. EOS , 79, pp. 173, 180-181.
• Reston, T.3., Krawczyk, C.M. & Klaeschen, D. (1996). The S reflector west of Galicia (Spain): evidence from prestack depth migration for detachment faulting during continental breakup. J. Geophys. Res ., 101, 8075-8091.
• T. M. Minshull, S. M. Dean, R. B. Whitmarsh, S. M. Russell, K. E. Louden, and D. Chian (1998). Deep structure in the vicinity of the ocean-continent transition zone under the southern Iberia Abyssal Plain. Geology , 26, 743-746.
• Chian, D., Keen, C., Reid, I. & Louden, K.E. (1995). Evolution of nonvolcanic rifted margins: new results from the conjugate margins of the Labrador Sea. Geology, 23, 589-592.
• White, R.S. (1992 ). Crustal structure and magmatism of North Atlantic continental margins.J. Geol. Soc ., 149, 841-854.
• Horsefield, S.J. Whitmarsh, R.B., White, R.S. & Sibuet, 3.-C. (1994). Crustal structure of the Goban Spur rifted continental margin, NE Atlantic. Geophys. J. Int ., 119, 1-19.
• Whitmarsh, R.B., White, R.S., Horsefield, S.J., Sibuet, 3.-C., Recq, M. & Level. V. (1996). The ocean-continent boundary off the western continental margin of Iberia: crustal structure west of Galicia Bank. J. Geophys. Res ., 101, 28,291-28,314
• Whitmarsh, R.B. & Sawyer, D.S. (1996). The ocean/continent transition beneath the Iberia abyssal : Plain and continental-rifting to seafloor-spreading processes. Proc. ODP., Sci. Results, 149, 713- 733.
• Minshull, T. A., Dean, S. M., White, R. S. & Whitmarsh, R. B. (2001). Anomalous melt production after continental breakup in the southern Iberia Abyssal Plain, in Wilson, R. C., Whitmarsh, R. B., Taylor, B. & Froitzheim, N. (eds.), Non-Volcanic Rifting of Continental Margins: A Comparison of Evidence from Land and Sea, Special Publication, Geological Society of London, 187, pp. 537—550.

Lecture Six

• Darbyshire, F. A., White, R. S. & Priestley, K. P. (2000). Structure of the crust and uppermost mantle of Iceland from a combined seismic and gravity study. Earth and Planetary Science Letters, 181, 409–428.
• Key, J., White, R. S., Soosalu, H. E. & Jakobsdóttir, S. S. (2011). Multiple melt injection along a spreading segment at Askja, Iceland. Geophysical Research Letters, in press, or CamTools.
• Sigmundsson, F. et al., (2010), Intrusion triggering of the 2010 Eyjafjallajökull explosive eruption, Nature, 468, 426–432
• Smallwood, John R., Staples, Robert K., Richardson, K. Ruth, White, Robert S. & FIRE Working Group (1999). Crust generated above the Iceland mantle plume: from continental rift to oceanic spreading center. Journal of Geophysical Research, 104, 22,885–22,902
• Staples, R. K., White, R. S., Brandsdóttir, B., Menke, W., Maguire, P. K. H. & McBride, J. H. (1997). Färoe-Iceland Ridge Experiment, 1. Crustal structure of northeastern Iceland. Journal of Geophysical Research, 102, 7849–7866.
• White,  R. S., Drew, J., Martens,  H. K., Key, A. J., Soosalu, H. & Jakobsdóttir, S. S. (2011). Dynamics of dyke intrusion in the mid-crust of Iceland, Earth and Planetary Science Letters, in press - in Camtools.

Reading list for Steve Roecker's lectures (7, 8 & 9). Key papers are indicated by a star (*).

References: Introduction and Rate- and State Friction

• R. McCaffrey. Global frequency of magnitude 9 earthquakes. Geology, 36(3):263-266, 2008. doi: 10.1130/G24402A.1.
• L. Ruff and H. Kanamori. Seismicity and the subduction process. Phys. Earth Planet. Int., 23:240-252, 1980.
• *C. H. Scholz. Earthquakes and friction laws. Nature, 391:37-42, 1998. A good summary of rate-and state friction and the implications for earthquakes and faults. A more extensive treatment is found in Chris Scholz's book, chapter 2. C. H. Scholz. The mechanics of earthquakes and faulting. Cambridge Univ. Press,, 2nd edition, 2002.
• S. Stein and E. A. Okal. Ultralong period seismic study of the december 2004 Indian Ocean earthquake and implications for regional tectonics and the subduction process. Bul. Seism. Soc. Am., 97(1A): S279- S295, 2007. doi: 10.1785/0120050617.

References: The Megathrust

• S.E. Barrientos and S.N. Ward. The 1960 Chile earthquake: inversion for slip distribution from surface deformation. Geophys. J. Int., 103:589-598, 1990.
• Bostock, R.D. Hyndman, S. Rondenay, and S.M. Peacock. An inverted continental Moho and serpentinization of the forearc mantle. Nature, 417:536-538, 2002.
• E. Byrne, D. M. Davis, and L. R. Sykes. Loci and maximum size of thrust earthquakes and the mechanics of the shallow region of subduction zones. Tectonics, 7:833-857, 1988.
• Comte, A. Eisenberg, E. Lorca, M. Pardo, L. Ponce, R. Saragoni, S.K. Singh, and G. Suarez. The 1985 Central Chile Earthquake: A Repeat of Previous Great Earthquakes in the Region? Science, 233:449-452, 1986.
• R. DeShon and S. Y. Schwartz. Evidence for serpentinization of the forearc mantle wedge along the Nicoya Peninsula, Costa Rica. Geophys. Res. Let., 31:L21611, 2004. doi: 10.1029/2004GL021179.
• *R. D. Hyndman, M. Yamano, and D. A. Oleskevich. The seismogenic zone of subduction thrust faults. Island Arc, 6:244-260, 1997. Contains the key ideas on the determinants of the width of the seismogenic zone.
• McKenzie, J. Jackson, and K. Priestley. Thermal structure of oceanic and continental lithosphere. Earth Planet. Sci. Let., 233:337-349, 2005. doi: 10.1016/j.epsl.2005.02.005.
• C. Moore and D. Saffer. Updip limit of the seismogenic zone beneath the accretionary prism of southwest Japan: An effect of diagenetic to low-grade metamorphic processes and increasing effective stress. Geology, 29(2):183-186, 2001.
• A.V. Newman, S.Y. Schwartz, V. Gonzales, H.R. DeShon, J.M. Protti, and L.M. Dorman. Along-strike variability in the seismogenic zone below Nicoya Peninsula, Costa Rica. Geophys.Res.Let., 29 (20): 1977, 2002. doi: 10.1029/2002GL015409.
• *E. Norabuena, T. H. Dixon, S. Schwartz, H. DeShon, A. Newman, M. Protti, V. Gonzalez, L. Dorman, E. R. Flueh, P. Lundgren, F. Pollitz, and D. Sampson. Geodetic and seismic constraints on some seismogenic zone processes in Costa Rica. J. Geophys. Res., 109:B11403, 2004. An interesting article on the challenge to interpret interseismic seismicity and geodetic data. Note that their GPS network might still not be su ffi cient to constrain details of slip SW of the islands.
• D. P. Robinson, S. Das, and A. B. Watts. Earthquake rupture stalled by a subducting fracture zone. Science, 312:1203-1205, 2006.

References: Outer Rise events

• * D. H. Christensen and L. J. Ruff. Seismic coupling and outer rise earthquakes. J. Geophys. Res., 93(B11):13,421-13,444, 1988. Outer rise earthquakes and the seismic cycle.
• E. Contreras-Reyes, I. Grevemeyer, E. R. Flueh, M. Scherwath, and M. Heesemann. Alteration of the subducting oceanic lithosphere at the southern central Chile trench-outer rise. Geochem., Geophys. Geosyst., 8:Q07003, 2007. doi: 10.1029/2007GC001632.
• A. T. Fisher, C. A. Stein, R. N. Harris, K. Wang, E. A. Silver, M. Pfender, M. Hutnak, A. Cherkaoui, R. Bodzin, and H. Villinger. Abrupt thermal transitions reveals hydrothermal boundary and role of seamounts within the Cocos plate. Geophys. Res. Let., 30(11):1550, 2003. doi: 10.1029/2002GL016766.I.
• Grevemeyer, N. Kaul, J. L. Diaz-Naveas, H. W. Villinger, C. R. Ranero, and C. Reichert. Heat flow and bending-related faulting at subduction trenches: Case studies offshore of Nicaragua and Central Chile. Earth Planet. Sci. Let., 236:238-248, 2005.
• T. Lay, L. Astiz, H Kanamori, and D. H. Christensen. Temporal variation of large intraplate earthquakes in coupled subduction zones. Phys. Earth Planet. Int., 54:258-312, 1989.
• S. Mueller, G. L. Choy, and W. Spence. Inelastic models of lithospheric stress-I. Theory and application to outer-rise plate deformation. Geophys. J. Int., 125:39-53, 1996a.
• S. Mueller, W. Spence, and G. L. Choy. Inelastic models of lithospheric stress-II. Implications for outer-rise seismicity and dynamics. Geophys. J. Int., 125:54-72, 1996b.
• * C. R. Ranero, J. Phipps Morgan, K. McIntosh, and C. Reichert. Bending-related faulting and mantle serpentinization at the Middle America trench. Nature, 45:367 - 373, 2003. A short article on the evidence for deep-bending related faulting and its consequences for water cycling.
• C. R. Ranero and R. von Huene. Subduction erosion along the Middle America convergent margin. Nature, 404:748-752, 2000.
• * C.H. Scholz and C. Small. The effect of seamount subduction on seismic coupling. Geol., 25:487-490, 1997.
• * R. von Huene and D. W. Scholl. Observations at convergent margins concerning sediment subduction, subduction erosion, and the growth of continental crust. Rev. Geophys., 29(3):279-316, 1991. Review paper covering the geological and geophysical evidence for subduction erosion.

References: Slow Slip Events and Seismic Tremor

• H. Dragert, K . Wang, and T. S. James. A silent slip event on the deeper Cascadia subduction interface. Science, 292:1525-1528, 2001.
• H. Kanamori. The energy release in great earthquakes. J. Geophys. Res., 82:1981-1987, 1977.
• S. Kodaira, T. Iidaka, A. Kato, J.-O. Park, T. Iwasaki, and Y. Kaneda. High pore fluid pressure may cause silent slip in the Nankai Trough. Science, 304:1295-1298, 2004.
• M. M. Miller, T. Melbourne, D.J. Johnson, and W.Q. Sumner. Periodic Slow Earthquakes from the Cascadia Subduction Zone. Science, 295:2423, 2002.
• K. Obara. Nonvolcanic deep tremor associated with subduction in southwest Japan. Science, 296: 1679-1626, 2002.
• J. Polet and H. Kanamori. Shallow subduction zone earthquakes and their tsunamigenic potential. Geophys. J. Int., 142:684-702, 2000.
• G. Rogers and H. Dragert. Episodic tremor and slip on the Cascadia subduction zone: the chatter ofsilent slip. Science, 300:1942-1943, 2003.
• *S. Y. Schwartz and J. M. Rokosky. Slow slip events and seismic tremor at circumpacific subduction zones. Rev. Geophys., 45:RG3004, 2007. doi: 2006RG000208. Excellent review paper describing the state-of-the-art from 2 years ago in this fast-moving field.

References: Intermediate and Deep Events

• G. A. Abers. Plate structure and the origin of double seismic zones. In G. E. Bebout et al., editor, Subduction Top to Bottom, volume 96 of Geophys. Monograph Ser., pages 223-228. AGU,Washington D.C., 1996.
• M. R. Brudzinski, C. H. Thurber, B. R. Hacker, and E. R. Engdahl. Global prevalence of double Benioff zones. Science, 316:1472-1474, 2007. doi: 10.1126/science.1139204.
• B. Emmerson and D. McKenzie. Thermal structure and seismicity of subducting lithosphere. Phys. Earth Planet. Int., 163:191-208, 2007.
• C. Frohlich. Deep Earthquakes. Cambridge University Press, 2006. Contains nearly everything there is to know about deep and intermediate earthquakes. Of course, it is far too comprehensive for this course.
• * B. R. Hacker, S. N. Peacock, G. A. Abers, and S. D. Holloway. Subduction factory - 2. are intermediate depth earthquakes in subducting slabs linked to metamorphic dehydration reactions? J. Geophys. Res., 108, 2003. doi: 10.0129/JB001129.
•  Kawakatsu. Downdip tensional earthquakes beneath the Tonga arc - a double seismic zone. J. Geophys. Res., 91(B6):6432-6440, 1986.
• S. Kirby, E. R. Engdahl, and R. Denlinger. Intermediate-depth intraslab earthquakes and arc volcanism as physical expressions of crustal and uppermost mantle metamorphism in subducting slabs. In G. E. Bebout et al., editor, Subduction Top to Bottom, volume 96 of Geophys. Monograph Ser., pages 195- 214. AGU, Washington D.C., 1996.
• S. H. Kirby. Localized polymorhic phase transformations in high-pressure faults and applications to the physical mechanism of deep earthquakes. J. Geophys. Res., 92:13789-13800, 1987. 
• D. McKenzie, J. Jackson, and K. Priestley. Thermal structure of oceanic and continental lithosphere. Earth Planet. Sci. Let., 233:337-349, 2005. doi: 10.1016/j.epsl.2005.02.005. 
• S. Nothard, D. McKenzie, J. Haines, and J. Jackson. Gaussian curvature and the relationship between the shape and the deformation of the tonga slab. Geophys. J. Int., 127:311-327, 1996.
• * S. M. Peacock. Are the lower planes of double seismic zones caused by serpentine dehydration in subducting oceanic mantle? Geology, 29(4):299-302, 2001.
• A. Rietbrock and F. Waldhauser. A narrowly spaced double-seismic zone in the subducting Nazca plate. Geophys. Res. Let., 31:L10608, 2004. doi: 10.1029/2004GL019610. 
• D. A. Wiens, J. J. McGuire, P. J. Shore, M. G. Bevis, K. Draunidalo, G. Prasad, and S. P. Helu. A deep earthquake aftershock sequence and implications for the rupture mechanism of deep earthquakes. Nature, 372:540-543, 1994.

Lecture Seven

J Maclennan

• * Plank T and Langmuir CH (1998), The chemical composition of subducting sediment and its consequences for the crust and mantle. Chemical Geology l45, 325-394
• Von Huene, R et al (2004) Generic model of subduction erosionGeology 32(10), 913-916
• Poli & Schmidt (2002) Petrology of subduction slabs Annual Reviews of Earth and Planetary Sciences 2002, 207-235
• Elliott, T. et al (1997) Element transport from slab to volcanic front at the Mariana arc Journal of Geophysical Research Solid Earth 102 (B7) 14991-15019
• *Plank T (2005) Constraints from thorium/lanthanum on sediment recycling at subduction zones and the evolution of the continents Journal of Petrology 46 (5): 921-944
• Kelley, KA et al (2003) Composition of altered oceanic crust at ODP sites 801 and 1149 G-cubed 4, art no 8910
• Elliott, T et al (2004) The terrestrial Li isotope cycle: light-weight constraints on mantle convection Earth and Planetary Science Letters 220(3-4) 231-245
• *Elliott, T (2003) Tracers of the slab IN: Eiler, J, (ed,) Inside the Subduction Factory. Geophysical Monograph Volume 138, pp. 23-46
• Marschall, H.R. et al., The lithium isotopic composition of orogenic eclogites and deep subducted slabs, Earth and Planetary Science Letters, 262, 563-580, 2007.

Lecture Eight

J Maclennan

Lecture Nine

J Maclennan

• Plank T and Langmuir CH (1998), The chemical composition of subducting sediment and its consequences for the crust and mantle. Chemical Geology l45, 325-394

Lecture Ten

J Maclennan

• Jarrard RD, Subduction fluxes of water, carbon dioxide, chlorine, and potassium, (2003) Geochem. Geophys. Geosyst., 4 (5), 8905, doi:10.102912002GC000392,
• Yang, JJ et al (2006) Calculated phase relations in the system NA2O-CaO-K2O-FeO-MgO-Al2O3-SiO2-H2O with applications to UHP eclogites and whiteschistsJournal of Petrology 47:2047-2071
• Pawley, AR (1998) The reaction talc plus forsterite = enstatite plus H2O: new experimental results and petrological implicationAmerican Mineralogist 83: 51-57
• Bromiley and Pawley (2003) The stability of antigorite in the systems MgO-SiO2-H2O (MSH) and MgO-Al2O3-SiO2-H2O (MASH): The effects of Al3+ substitution on high-pressure stabilityAmerican Mineralogist 88: 99-108
• Bromiley and Pawley (2002) The high-pressure stability of Mg-sursassite in a model hydrous peridotite: a possible mechanism for the deep subduction of significant volumes of H2OContributions to Mineralogy and Petrology 142: 714-723
• Iwamori, H (2004) Phase relations of peridotites under H2O-saturated conditions and ability of subducring plates for transportation of H2O Earth and Planetary Science Letters 227: 57-71
• Grove et al (2006) The influence of H2O on mantle wedge melting Earth and Planetary Science Letters 249: 74-89
• Smith and Asimow (2005) Adiabat_1ph: A new public front-end to the MELTS, pMELTS, and pHMELTS modelsG-cubed 6: Art no. Q02004
• Katz, RF et al (2003) A new parameterization of hydrous mantle meltingG-cubed 4: Art no. 1073
• Peacock, SM et al (1994) Partial melting of subducting oceanic crust Earth and Planetary Science Letters, 121:227-244
• Connolly, JAD (2005) Computation of phase equilibria by linear programming: A tool for geodynamic modeling and its application to subduction zone decarbonation, Earth and Planetary Science Letters, 236: 524-541
• Manning CE,(2004) The chemistry of subduction-zone fluids, Earth and Planetary Science Letters, 223, 1
• Rupke, L. et al(2004) , Serpentine and the subduction zone water cycle, Earth and Planetary Science Letters , 223, 17-34

Practical 13

• Creager, KC & TM Boyd (1991) The geometry of Aleutian subduction: three-dimensional kinematic flow model Journal of Geophysical Research 96: 2293-2307
• Kay, RW & SM Kat (1988) Crustal recycling and the Aleutian arcGeochim. Cosmochim Acta 52: 1351-1359
• Kay, RW et al (1978) Pb and Sr isotopes in volcanic rocks fro the Aleutian islands and Pribilof islands, AlaskaGeochim. Cosmochim Acta 42: 263-273
• Monaghan, MC et al (1988) The origin of 10Be in island-arc volcanic rocks Earth and Planetary Science Letters , 89: 288-298
• Myers, JD et al (1987) Aleutian lead isotopic data: additional evidence for the evolution of lithospheric plumbing systemsGeochim. Cosmochim Acta 51: 1833-1842
• Tera, F et al (1986) Sediment incorporation in island-arc margins: inferences from 10BeGeochim. Cosmochim Acta 50: 535-550
• Von Drach, V et al( 1986) Nd and Sr isotopes in the Aleutians: multicomponent parenthood of island arc magmas Contributions to Mineralogy and Petrology 92: 13-34

Lecture Fourteen

J Maclennan

• Kelemen, P (2003) One view of the geoche3mistry of subduction-related magmatic arcs, with emphasis on primitive andesite and lower crust. IN: Treatise of geochemistry Volume 3, The Crust. (Eds Rudnick, Holland & Turekian.)
• Pearce and Peate (1995) Tectonic implications of the composition of volcanic arc magmas.Annual Review of Earth and Planetary Sciences 23: 251-285
• Rupke et al (2002) Are the regional variations in Central American arc lavas due to differing basaltic versus peridotitic slab sources of fluids?Geology 30: 1035-1038
• * Plank, Balzer & Carr (2002) Nicaraguan volcanoes record paleoceanographic changes accompanying closure of the Panama gateway. Geology 30: 1087-1090.
• *Feigenson, MD et al (2004) Lead isotope composition of central American volcanoes; influence of the Galapagos plume.Geochemistry. Geophysics, Geosystems 5. Art no. Q06001.
• Defant, MJ et al (1992) The geochemistry of young volcanism throughout western Panama and southeastern Costa Rica, and overview. Journal of the Geological Society (London) 149: 569-579.
• *Carr, MJ et al (2004) Volcanism and Geochemistry in Central America: progress and problems. IN: Geophysical Monograph Series Volume 138 (Inside the Subduction Factory).
• Patino, LC et al (2000) Local and regional variations in Central American arc lavas controlled by variations in subducted sediment input. Contributions to Mineralogy and Petrology 138: 265-283
• Plank & Langmuir (1988) An evaluation of the global variations in the major element chemistry of arc basalts.Earth and Planetary Science Letters 90: 349-370

Practical 14

• Macdonald et al (2000) The lesser Antilles volcanic chain: a study in arc magmatism. Earth Science Reviews 49: 1-76
• Plank, Langmuir (1993) Tracing trace-elements from sediment input to volcanic output at subduction zones. Nature 362: 739-743
• Toothill et al (2007) A complex petrogenesis for an arc magmatic suite, St. Kitts, Lesser Antilles. Journal of Petrology 48: 3-42
• Housh, Luhr (1991) Plagioclase-melt equilibria in hydrous systems. American Mineralogist 76: 477-492
• Heath et al (1998) Magmagenesis at Soufriere Volcano, St.. Vincent, Lesser Antilles Arc. Journal of Petrology 39: 1721-1764. (pdf available if you do a google search)
• Turner et al (1996) U-series isotopes and destructive plate margin magma genesis in the Lesser Antilles.Earth and Planetary Science Letters 142: 191-207

Lecture Fifteen

J Maclennan

• *Elliott, T. et al (1997) Element transport from slab to volcanic front at the Mariana arcJournal of Geophysical Research Solid Earth 102 (B7) 14991-15019
• *Turner et al (2003) Insights into magma genesis at convergent margins from U-series isotopes.Reviews in Mineralogy and Geochemistry 52: 255-315
• Sigmarsson, Martin and Knowles( 1998) Melting of a subducting oceanic crust from U-Th disequilibrian in austral Andean lavas.Nature 394: 566-569
• Turner, Hawkesworth (1997) Constraints on flux rates and mantle dynamics bneath island arcs from Tonga-Kermadec lava geochemistryNature 389: 568-573
• Morris, Leeman, Tera (1990) The subducted component in island –arc lavas – contraints from Be isotopes and B-Be systematics Nature 344:31-36
• Tera, F et al (1986) Sediment incorporation in island-arc margins: inferences from 10BeGeochim. Cosmochim Acta 50: 535-55
• Morris & Tera (1989) 10 Be and 9Be in mineral separates and whole rocks from volcanic arcs: Implications for sediment subduction . Geochimica et cosmochimica acta 53: 3197-3206
• McKenzie (2000) Constraints on melt generation and transport from U-series activity ratiosChemical Geology 162: 81-94
• Bourdon et al (2003) Introduction to U-series geochemistryReviews in Mineralogy and Geochemistry 52: 1-21
• Kessel, Schmidt et al (2005) Trace element signature of subduction-zone fluids, melts and supercritical liquids at 120-180 kmm depthNature 437: 724-727

Practical 15

• *Elliott, T. et al (1997) Element transport from slab to volcanic front at the Mariana arcJournal of Geophysical Research Solid Earth 102 (B7) 14991-15019
• Turner et al (2001) Ultrafast source-to-surface movement of melt at island arcs from Ra-226-Th-230 systematicsScience 292: 1363-1366

Lecture Sixteen

J Maclennan

• Davidson et al (2005) Crustal forensics in arc magmasJournal of volcanology and Geothermal Research 140: 157-170
• *Annen, Blundy & Sparks (2006) The genesis of intermediate and silicic magmas in deep crustal hot zonesJournal of Petrology 47: 505-539
• Grove et al (2003) Fractional crystallization and mantle-melting controls on calc-alkaline differentiation trendsContributions to Mineralogy and Petrology 145: 515-533
• Muntener, Kelemen & Grove (2001) The role of H2O during crystallization of primitive arc magmas under uppermost mantle conditions and genesis of igneous pyroxenites: an experimental study. Contributions to Mineralogy and Petrology 141: 643-658
• Garrido et al (2006) Petrogenesis of mafic garnet granulite in the lower crust of the Kohistan paleo-arc complex (Northern Pakistan): implications for intra-crustal differentiation of island arcs and generation of continental crustJournal of Petrology 47: 1873-1914
• Greene et al (2006) A detailed geochemical study of island arc crust: the Talkeetna Arc section, south-central Alaska Journal of Petrology 47: 1051-1093

Practical 16

• Lejeune & Richet (1995) Rheology of crystal-bearing silicate melts: an experimental study at high viscosities. Journal of Geophysical Research 100 pp4215-4230
• Blundy & Cashman (2001) Ascent-driven crystallization of dacite magmas at Mount St. Helens, 1980-1986Contributions to Mineralogy and Petrology 140: 631-650
• Blundy, Cashman, Humphreys (2006) Magma heating by decompression-driven crystallization beneath andesite volcanoesNature 443: 76-80
• Hess & Dingwell (1996) Viscosities of hydrous leucogranitic melts: a non-Arrhenian model. American Mineralogist 81: 1297-1300

Last updated on 27-Feb-13 17:19