Post on 26-Feb-2021
P-T-D-t paths from granulites:
a guide to what’s possible
The limits of conventional thermobarometry
Understanding reaction microstructures
Deformation sequences in relation to melting
Linking geochronology to reactions
2
P- and T-sensitive equilibria
Assemblages and petrogenetic grids
• Observed changes of mineral assemblage compared
with predicted stability on petrogenetic grids and
pseudosections
Multivariant equilibria (continuous net transfer
reactions)
• Changes of mineral composition in sliding reactions,
e.g. grossular + 2 kyanite + quartz = 3 anorthite
Ca transferred from plagioclase to garnet with increasing P
Cation distributions (cation exchange reactions)
• e.g. Fe and Mg distribution between garnet and biotite.
Fe prefers garnet, but gets less fussy at higher T.
Solvi and miscibility gaps
• e.g. Cpx-Opx, Cal-Dol, Ab-Or.
• Gaps usually close towards higher T A B
2phases
T
KD
ln K
P
P
T
T
3
Thermobarometry in granulites
Useful thermometers:
Fe-Mg exchange: Grt-Cpx, Grt-Opx, Grt-Crd
Pyroxene thermometry: Opx-Cpx miscibility gap
Most thermometers are exchange equilibria
Useful barometers
P-sensitive, anhydrous equilibria (large DV):
Plag = Grt e.g. En + An = Grs + Prp + Qtz
Crd = Grt e.g. Crd = Grt + Sil + Qtz
Most barometers are net-transfer equilibria
Retrograde changes during slow cooling
affect exchange equilibria:
• without visibly affecting rock texture
affect the net-transfer reactions:
• visibly: reaction rims & intergrowths
4
Compositional zoning from retrograde cation diffusion
Pattison & Begin 1994, J Metamorphic Geol 12, 387-410
5
Grain boundary or volume diffusion?
• O’Brien 1999
Min Mag 63,
227-238
Mg
6
Problems in high grade rocks
• Metapelite, peak assemblage
Grt-Crd-Sil-Qtz
• Thermometer: Grt-Crd Fe-Mg
exchange
• Barometer: Grt + Sil + Qtz =
Crd
1. Cores preserve Grt-Crd-Sil-Qtz
matrix equil;
2. Rims record final closure of
Fe-Mg exchange
“Granulite uncertainty principle” -
peak conditions may not be
preserved
Rims in contact
Grt
Crd
%M
gO
%M
gO
Comp at peakComp at peak
Core Core
Fictive P,Grt + Crd notin equil. withSil + Qtz
Peak P-T (can't be determined)
Fe-Mg exchange ceasesPhases cease to homogenise
Actual P-T path
Apparent P-T path
P
T
12
7
Discordant geothermometry
8
Grt-Crd migmatite
• Grt (neosome) and Crd
(palaeosome) physically
separated
9
Opx-Crd-Bt-Grt gneiss
• Mafic minerals all in contact, easy
exchange?
• But detailed microstructure suggests
garnet growth is late – was it there at
the peak? Is this diffusion zoning or
(down-T) growth zoning?
10
P-T paths from phase relations: Reaction coronas
• Corona shows progress of the continuous reaction
Grt + Qtz = Crd + Opx
• Rock has crossed flat-lying isopleths in down-P direction
Grt + Crd + Opx + Qtz
Temperature
Press
ure
Grt + Opx + Qtz
Grt + Crd + Qtz
11
Isothermal decompression and isobaric cooling paths
Compilation from Harley 1989 Geol Mag 126 215-247
12
Prograde reaction microstructures?
Prograde metamorphic P-T path is an important discriminator.
Can it be determined?
Loss of aqueous fluid reduces mobility of material, despite
higher T.
• reaction rims
• pseudomorphs after amphibolite-facies porphyroblasts.
Ductility contrasts between refractory rocks and enclosing
migmatites.
• strain partitioned into migmatites
• early microstructures preserved in refractory rock-types
13
Spinel + quartz
• Hercynite-rich spinel(Fe,Mg)Al2O4
produced by reactionCrd Hcss + Qtz
Waters (1991) Eur J Min 3, 367-386.
14
Use assemblages (facies type)
Establish which minerals
coexisted stably at the
metamorphic peak
15
Locate facies type on petrogenetic grid
Waters (1986) J Petrology 27,
541-565
16
Reaction sequences
Identify progress of model
divariant equilibria
• Crd + Spl + Crn -> Spr
• Opx + Sil -> Spr + Crd
17
P-T path from assemblage changes
18
P-T segments from different rock types
Metapelites: lost Ms before start of melting, peak at 5 kbar, >800°C
Mg-Al gneisses:Sapphirine-forming reactions constrain slope
Hercynite-quartz metapelites, retrograde reactions
19
Namaqualand P-T path summary
From Waters (1989) with new monazite age data
20
Sequences of deformation and reaction
• Melt generation as a time marker: overprinting older fabrics;
structural control of leucosomes; deformation and recrystallisation of
leucosomes.
• Melting as a control on rock rheology, enhancing lithological contrasts,
allowing preservation of history in low-strain refractory domains.
21
Neosomes define linear fabric, but...
22
Neosomes define later planar fabric
23
Linking geochronology to mineral development
Petrological framework for migmatitic
biotite gneisses
Prograde evolution, up to Sil zone
Biotite gneiss, just Al-saturated (trace
Sil)
Metamorphic peak
Dehydration melting, garnet appears
in neosome only, textural
modification of neosome (melt
present)
Retrograde evolution
Cooling and partial back-reaction with
melt, Grt -> Bt
24
Synthesis of rock evolution
• Early cores show outward decreasing Th,
increasing Y, U. Prograde growth, over ca.
400 - 700°C if xenotime present. No Grt.
• Main zones, lobes Y+HREE depleted,
consistent with Grt growth. Big grains in
neosome = dehydration melting.
• Rims: higher, then lower Th. Outer rims
have v. high Y+HREE, released by Grt
breakdown (this grain in Bt after Grt).
25
Preliminary results and regional pattern
DWN57 migmatitic metapelite
Core zones 1063 ± 24 n = 6
Main growth zones 1038 ± 11 n = 13
Rims 1013 ± 11 n = 14
800850900950100010501100115012001250
DWN57 coresDWN57 mainDWN57 rims
DWN673DWN673 mainDWN673 rims
BP3 coresBP3 main
BP3 high ThBP3 rims
Age (Ma)
Early magmatism Spektakel suite
Koperberg suite
Zircon rim growth
26
Nanga Parbat: constraining rapid exhumation
• Very young ages, e.g. xenotime 0.7-1.1 Ma (Bowring, Hodges,
Searle, Waters, in prep.)
27
Nanga Parbat migmatites
28
Garnet rimmed by cordierite in neosome
29
REE chemistry of xenotimes
Xenotime in garnet has depleted HREE.
Xenotime in cordierite corona has enriched HREE
Chemistry, and so U-Th-Pb system, records the visible reaction