Lecture 4: MORB petrogenesis
Outline1) Overview of igneous petrogenesis
2) Mid-Ocean Ridges – how are they characterized?
3) MORB – where and how do they form?
4) Geochemical variations in MORB (major elements, trace elements and isotopic characteristics)
Igneous Petrogenesis
1. Mid-ocean ridges
2. Continental rifts
3. Island Arcs
4. Active continental margins
5. Back-arc basins
6. Ocean Islands
7. Intraplate hotspot activity, carbonatites, or kimberlites
Mid-ocean ridgesMid-ocean ridges produce ~ 21 km3 of lava per year
~60% of the earth’s surface is covered with oceanic crust
Mid-ocean Ridges
Spreading rate influences thermal structure, physical structure, crustal thickness and amount of melting
-2
0
2
4
6
8
10
0 2 4 6 8 10Vp (km/s)
Water
Moho
Mantle = altered peridotite
Layer 3 = gabbro
Layer 2 = extrusives
Layer 2a = dikes
Layer 1 = sediment
Spreading rate and structure
Slow-spreading Mid-Atlantic Ridge
Fast-spreading East Pacific Rise• Thermal structure is warmer
• Crust is thicker, lithosphere is thinner
• Higher degrees of melting
• Sustained magma chambers and volcanism
• Less compositional diversity
• Thermal structure is cooler
• Crust is thinner, lithosphere is thicker
• lower degrees of melting
• Episodic volcanism
• Higher compositional diversity
The Axial Magma Chamber: original model
• Semi-permanent
• MORB magmas are produced by fractional crystallization within the chamber
• Periodic reinjection of fresh, primitive MORB
• Dikes upward through extending/faulting roof
• Crystallization at top and sides successive layers of gabbro (layer 3) “infinite onion”
• Dense olivine and pyroxene crystals ultramafic cumulates (layer 4)
• Moho?? Seismic vs. Petrologic
Figure 13.16. From Byran and Moore (1977) Geol. Soc. Amer. Bull., 88, 556-570.
Hekinian et al. (1976)Contr. Min. Pet. 58, 107.
After Perfit et al. (1994) Geology, 22, 375-379.
A modern concept of the axial magma chamber beneath a
fast-spreading ridge
Model for magma chamber beneath a slow-spreading ridge, such as the Mid-Atlantic Ridge
• Most of body well below the liquidus temperature, so convection and mixing is far less likely than at fast ridges
• numerous, small, ephemeral magma bodies occur at slow ridges• Slow ridges are generally less differentiated than fast ridges - no continuous
liquid lenses, so magmas entering the axial area are more likely to erupt directly to the surface
Distance (km)10 105 50
2
4
6
8
Dep
th (
km)
Moho
Transitionzone
Mush
Gabbro
Rift Valley
After Sinton and Detrick (1992) J. Geophys. Res., 97, 197-216.
Oceanic Crust and Upper Mantle Structure
1) Geophysical studies
2) Mantle xenoliths
3) Ophiolites: uplifted oceanic crust + upper mantle
Lithology and thickness of a typical ophiolite sequence, based on the Samial Ophiolite in Oman. After
Boudier and Nicolas (1985) Earth Planet. Sci. Lett., 76, 84-92.
Rock types in the mantlePeridotite is the dominant rock type of the Earth’s upper mantle• Lherzolite: fertile unaltered mantle; mostly composed of olivine,
orthopyroxene (commonly enstatite), and clinopyroxene (diopside), and have relatively high proportions of basaltic ingredients (garnet and clinopyroxene).
• Dunite (mostly olivine) and Harzburgite (olivine + orthopyroxene) are refractory residuum after basalt has been extracted by partial melting
• Wehrlite: mostly composed of olivine plus clinopyroxene.
wehrlite lherzolite
Ocean Crust Geology
Modern and ancient pillow basalts
Glassy pillow rinds are used to infer original melt compositions
P. Asimow
Magma: mixture of molten rock, gases and mineral phases, produced by mantle melting
Mantle melts between ~800-1250ºC due to:
1) Increase in temperature
2) Decrease in pressure
3) Addition of volatile phases
Adiabatic rise of mantle material with no heat loss – decompression melting
Mid-Ocean Ridges
Partial melting
A model for mantle melting• Several models are possible of how and where the melt is extracted
and what happens to it during transport• This average melt is primary mid-ocean ridge basalt (MORB).• Hot mantle starts melting at deeper depths, thus has a larger melt
triangle or area over which melting occurs than a cooler mantle • Mantle rising nearer axis of plume traverses greater portion of
triangle and thus melts more extensively
Hot mantle cool mantle
Asimow et al., 2004
Igneous rock classification by composition• There are several classifications, of individual rocks or rock suites.• By silica percentage:%SiO2 Designation % Dark Minerals Designation Example rocks>66 Acid <40 Felsic Granite, rhyolite52-66 Intermediate 40-70 Intermediate Diorite, andesite45-52 Basic 70-90 Mafic Gabbro, basalt<45 Ultrabasic >90 Ultramafic Dunite, komatiite
The common crystallization sequence at mid-ocean ridges is: olivine ( Mg-Cr spinel), olivine + plagioclase ( Mg-Cr spinel), olivine + plagioclase + clinopyroxene
After Bowen (1915), A. J. Sci., and Morse (1994)
(plagioclase)
(olivine)(clinopyroxene)
“Fenner-type” variation diagrams for basaltic glasses from the Afar region of the MAR. From Stakes et al. (1984)
The major element chemistry of MORBs
• MORBs are the product of fractional crystallization, melt aggregation, seawater interaction and crustal contamination
• MgO contents are a good index for fractional crystallization (typically, more primitive melts have higher MgO)
• Data is often “corrected” back to 8 wt% MgO to estimate primary melt compositions and to compare data sets
Increased fractional crystallization
Global systematics• The values of regionally-averaged Na8 (i.e., Na2O concentration
corrected to 8% MgO), Fe8, water depth above the ridge axis, and crustal thickness show significant global correlations.
– Where Na8 is high, Fe8 is low
– Where Na8 is high, the ridges are deep
– Where Na8 is high, the crust is thin
1.5
2.5
3.5
2.0
3.0
6 7 8 9 10 11 12Fe8.0
Na8.0
Deep ridges
Shallow ridges
Na8 is an incompatible element, thus an indicator of mean extent of melting.
Fe8 is an indicator of mean pressure of melting.
Axial depth is an indicator of mantle temperature, extent of melting, and crustal thickness combined – see slide #5
Synthesis of global systematics• The global correlation implies that extent of melting and pressure of
melting are positively correlated, on a global scale. This relates to the mantle potential temperature.
• If melting continues under the axis to the base of the crust everywhere, then high potential temperature means: long melting column high mean extent of melting low Na8 and high crustal thickness shallow axial depth; high mean pressure of melting high Fe8. Cold mantle yields the opposite.
sea level
crust
axial depth
solidus 1.5 GPa
solidus 4.5 GPa
5%10%15%20%25%
Fmean P
mean F
5%
10%15%20%25%
F30%
35%
40%
mean Pmean F
Cold mantle Hot mantle
P. Asimow
Spider diagram of crust vs mantle
Workman and Hart, 2005
Figure 13-15. After Perfit et al. (1994) Geology, 22, 375-379.
A modern concept of the axial magma chamber beneath a fast-
spreading ridge
Generating enriched signatures in MORB1) Low degrees of melting
2) Mantle source enrichment
• N-MORB: normal MORB• T-MORB: transitional MORB• E-MORB: enriched MORB
Isotope systematics of MORB
Radiogenic isotope systems (Sr, Nd, Pb) are used to see mantle enrichments due to relative compatibilities of radiogenic parents and daughters
e.g., 87Rb 87Sr, Rb is more incompatible than Sr so high 87Sr/86Sr ratios indicate an enriched source
Compared to ocean islands and subduction zones, MORBs are relatively homogeneous
Stable isotopes
• Like radiogenic isotopes, stable isotope can be used to trace source enrichments and are not influenced by degrees of melting
• Oxygen, boron, helium and nitrogen isotopes show very little variability in MORB, and are distinct from enriched OIB and subduction related lavas
Macpherson et al., 2000
Manus
Craig and Lupton (1981)Craig and Lupton (1981)
He isotopes:3He : key tracer of a primordial component4He : representing a radiogenic component (U+Th decay)
3He anomalies at ridges is evidence for degassing of primordial gases from the earth
Typical 3He/4He ratios:
Crust : 0.01-0.05 RA
MORB : 8 ± 1 RA
Arcs: 5 - 8 RA
Hotspots: up to 37RA