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1. Why need modeling?
2. Forward modeling
3. How can we do it? ADIABAT_1ph
4. Limitations of the program
5. Example
-different processes and mechanisms similar effects
(e.g. modify the composition of a magma to obtain increasing of SiO2)
-fractional crystallization of a basic magma-different % of crustal assimilation of a basic magma-different % of partial melting of crustal rocks
•experiments partial melting should leave behind important amounts of residuum with high densities
Arc models
a) need quantifying to better constrain geologic models
a) Modeling need constrains to be realistic
1. Why need modeling
2. Forward modeling
We start from unknown (or guessed), trying to arrive to what we know
Try end error method
What do we know?
-several plutons with different composition, age etc we can estimate an average composition
-from the exposed area we can do some estimations of the volume of plutons
-scarce knowledge of the plutons development and composition at greater depths
Models can work on:
-individual protoliths, plutons, residual solids etc (at local scale)
-averaged compositions of the protoliths, plutons, residual solids etc (at arc scale)
Program used for modeling compositions and physical properties
ADIABAT_1ph
Smith, P. M., and P. D. Asimow (2005)Smith, P. M., and P. D. Asimow (2005), Adiabat_1ph: A new public front-end to the MELTS, pMELTS, and pHMELTS models, Geochem. Geophys. Geosyst., 6, art. no. Q02004, doi:10.1029/2004GC000816.
It uses the MELTS family of algorithmsIt uses the MELTS family of algorithms Ghiorso, M.S., and R.O. Sack, Chemical Mass-Transfer in Magmatic Processes IV. A Revised and Internally Consistent Thermodynamic Model for the Interpolation and Extrapolation of Liquid-Solid Equilibria in Magmatic Systems at Elevated-Temperatures and Pressures, Contributions to Mineralogy and Petrology, 119 (2-3), 197-212, 1995. Asimow, P.D., and M.S. Ghiorso, Algorithmic modifications extending MELTS to calculate subsolidus phase relations, American Mineralogist, 83 (9-10), 1127-1132, 1998.
• calculates equilibrium assemblages from a given bulk composition of multicomponent systems
• anhydrous, water-undersaturated, or water-saturated systems
• options of buffering oxygen fugacity
• control on water activity
• subsolidus or suprasolidus calculations
• melting and crystallization models may be batch, fractional, or continuous.
• can simultaneously calculate trace element distributions.
• can calculate along a thermodynamic path set by the user
ADIABAT_1ph version 1.6
4. Limitations of the program
• the compositions of liquids are not realistic above 30-35 kb
•TiO2 overestimate the stability of pyroxene over other solids
• MnO overestimates the stability of liquid and olivine over other phases
• The amphibole stability field is underestimated
• pMELTS routine is to be used for ultrabasic compositions only
The compositions of melts and solids, as well as the phase proportions, are dependent on:
-small variation of H2O content-initial composition of the system (SiO2, Al2O3 etc...)-T-P-Thermodynamic type of calculation (isobaric, isentropic, fractional crystallization .....)
More variables Need simplifications:
e.g. keep some variable = ct
e.g. P=ct
Assumptions:
-isobaric processes at different depths according to a geologic model
need a geological model before starting quantifying
-plutons with heterogeneous compositions, forms, ages, depths etc
-only limited parts of the arcs are exposed
-no direct exposure of the lower levels of the arcs
EXAMPLE – ADIABAT runs for the a pluton from BC
10-15 kb
[3548] BEARD B. L.(1995)
samp. IN9220H-3
BASIN AND RANGE-GREAT BASIN / SOUTHWESTERN GREAT
BASIN / CALIFORNIA / BIG PINE VOLCANIC FIELD
LherzoliteLherzolite
Runs at 30 kb
pMELTS routine
EXAMPLE – ADIABAT runs starting at 1500 ºC
Partial melting of lherzolite (+ H2O) to produce Partial melting of lherzolite (+ H2O) to produce basaltic meltbasaltic melt
Basaltic melts in Basaltic melts in MASHMASH zone zone andesitic basaltandesitic basalt
Acid melts + residueAcid melts + residue
Runs at 15 kb
MELTS routine
Runs at 4 kb
MELTS routine
Compare the result with the composition of plutons
30 kb -Lherzolite
3% H2O
Ts ~1180 ºC
small amount of melt (~ 1 % melt at ~ 1200 º C with SiO2~ 35 %
not enough melt
not “normal” basalt composition
not realistic!!!
Phase proportions for 3% H2O
0
10
20
30
40
50
60
70
1100 1150 1200 1250 1300 1350 1400 1450 1500
T (C)
% vo
l
liquid_0
olivine
garnet
orthopyroxene
clinopyroxene
biotite
spinel
water
Liquid composition for 3% H2O
0
5
10
15
2025
30
35
40
45
1100 1150 1200 1250 1300 1350 1400 1450 1500
T (C)
% wt
SiO2
TiO2
Al2O3
Fe2O3
FeO
MgO
CaO
Na2O
K2O
H2O
Assuming a basic melt arrived at MASH zone
By assimilation and homogenization crystallization
andesitic basalt or basaltic andesite
Protolith for future melts
Runs at 15 kb
Results of different runs are compared with :
From Georoc databaseAndesitic basaltAndesitic basalt
Average composition of the Average composition of the plutonpluton
Estimated composition of composition of the the residueresidue
Initial composition: 1, 2..... X .....
...slightly modifying composition, water content etc....
untill...
...we get an acid melt similar with our pluton...
then...
The guessed initial composition protolith
..... and we can also estimate:
1. proportion of liquid and solid residue
2. temperature where the composition of pluton is valid
3. chemical and petrographic composition of residual solid
4. Estimates on the mineral chemistry of phases of the residual solid
5. density of melt and residual solid
SiO2 53.1TiO2 1.14Al2O3 18.3Fe2O3 2.85FeO 6.8CaO 9.62MgO 3.59MnO 0.19K2O 1.33Na2O 3.21P2O5 0.22H2O 0.59
Andesitic basalt as starting composition (from Georoc database)
CENTRAL AMERICAN VOLCANIC ARC / HONDURAS / SEGMENT 4 / BOQUERON / PACIFIC OCEAN [4231]
Samples averaged
SiO2 63.11
TiO2 0.71
Al2O3 16.83
FeO 5.1
Fe2O3 0.20
MnO 0.08
MgO 2.28
CaO 4.99
Na2O 4.22
K2O 1.67
P2O5 0.24
H2O 0.47
Averaged
Great Tonalite Sill
GJP-12
Great Tonalite
SillEarly
Tertiary
GJP-13
Great Tonalite
SillEarly
Tertiary
GJP-14
Great Tonalite
Sill 61 Ma
GJP-79
Great Tonalite
SillEarly
Tertiary
GJP-84
Great Tonalite
SillEarly
Tertiary
GJP-85
Great Tonalite
Sill 59 Ma
GJP-83
Great Tonalite
SillEarly
Tertiary
Andesitic basalt
Adiabat_1ph
Liquid composition
0
10
20
30
40
50
60
70
80
700 800 900 1000 1100 1200 1300 1400 1500
T (C)
% w
t
SiO2
TiO2
Al2O3
Fe2O3
FeO
MgO
CaO
Na2O
K2O
H2O
Phase proportions at 15 kb
0102030405060708090
100
700 800 900 1000 1100 1200 1300 1400 1500
T (C)
% m
as
s
liquid_0
garnet
clinopyroxene
clinoamphibole
biotite
feldspar
feldspar
quartz
kyanite
T solidus ~ 700 ºC
T liquidus ~ 1420 º C
composition similar with pluton averaged at
~ 1080 º C ( with ~ 15% melt)
Melt is 17.91 %
The residueresidue is 68.4% cpx + 13.69 %grt
P = 15 kb
~45 km depth
Composition ~ pluton
SiO2 52
TiO2 0.1
Al2O3 13
Fe2O3 0.9
FeO 8.5
CaO 12.2
MgO 10.1
K2O 0.5
Na2O 3.0
H2O 0.5
Starting composition
(Protolith)SiO2 63.66
TiO2 0.16
Al2O3 16.18
Fe2O3 0.02
FeO 6.51
MgO 0.44
CaO 5.50
Na2O 6.27
K2O 0.05
H2O 1.22
Liquid composition at T=1180ºC
Residue composition at
T=1080ºC
63.11
0.71
16.83
0.2
5.1
2.28
4.99
4.22
1.67
0.47
calculated Real average
ResidueResiduemass %mass % Estimated formulaEstimated formula
garnetgarnet 13.69 (Ca0.07Fe''0.45Mg0.48)3Al2Si3O12
clinopyroxeneclinopyroxene 68.40 Na0.16Ca0.65Fe''0.23Mg0.65Fe'''0.04Al0.41Si1.85O6
SiO2 49.12
TiO2 0.09
Al2O3 10.44
Fe2O3 1.15
FeO 9.79
MgO 12.99
CaO 14.99
Na2O 1.44
K2O 0.00
H2O 0.00
Densities (g/cm3)
solid 3.345
liquid 2.586
At T=1180 º C
Densities
00.5
11.5
22.5
33.5
4
700 800 900 1000 1100 1200 1300 1400 1500
T (C)
den
sity
(g
/cm
3)
Further Constraints on the Composition of Deep Crustal Rocks• Using the output modeling programs we
can calculate seismic properties of rocks of that composition.
• We can compare the calculated seismic properties to what we see in the batholith.
• How is this possible?
Mineral Physical Properties
• Database of mineral physical properties (Hacker et al. 2003).
• Hackers’ spreadsheet is an Excel workbook which includes database and a macro which will calculate rock physical properties (Hacker and Abers 2004).
• Input into this spread sheet is Vol% of minerals in rock.
CIPW norms
• A norm is a synthetic mineralogy calculated by apportioning chemical components into hypothetical (but hopefully realistic) minerals.
• Mode is the actual mineralologic composition of a rock, volume percentage of minerals.
• Using CIPW norms we can convert the chemical composition attained from the output of modeling programs such as Adiabat, and input the mineral assemblage into Hackers spreadsheet
Calculating CIPW norms
• What was once a The process of calculating CIPW norms can be done in Excel.
The volume % of normative minerals can be input into Hackers spreadsheet to calculate the seismic properties of a rock with that composition.
input