geochemistry lab exercise: crystallization of magmas john c. ayers vanderbilt university
DESCRIPTION
Skill: Creating plots in Excel and Interpreting What rock did your group work on? ______________________ Use the Excel template NormCalc.xlt to calculate the normative mineralogy of your rock. What are the normative minerals in your rock, and their percentages?NormCalc.xlt Enter major element concentrations into cells C2:E2 on sheet “My Data” in the Excel template Alkalinity.xlt. Is your rock alkaline or subalkaline? What rock type is it classified as in the TAS (Total Alkalis vs. Silica) diagram?Alkalinity.xlt For samples QLO-1 and GSP-2 only: Enter the normative composition of your rock into cells B17:D17 on sheet “Ternplot” in the Excel template TTGternaryplot.xlt. What is the classification of your rock?TTGternaryplot.xlt Enter trace element concentrations into cells B3:B10 on sheet “My Data” in the Excel template Discrimination.xlt. Examine the various plots that are automatically produced on the other sheets. What conclusions can you draw about the tectonic environment that your rock formed in?Discrimination.xlt Replace the values in cells B2:B16 in the sheet “Normed REE data” in the template REEPlot.xlt with the REE concentrations in your rock in ppm. Describe the shape of the REE pattern. Is your rock enriched or depleted in the LREE? Explain why. Is there a Ce or Eu anomaly? Why or why not? REEPlot.xlt Replace the values in cells B2:B29 in the sheet “Normalized T.E. data” in the template SpiderPlot.xlt with the trace element concentrations in your rock in ppm. What are the characteristic features? What conclusions can you draw about the environment that your rock formed in?SpiderPlot.xltTRANSCRIPT
Geochemistry Lab Exercise:Crystallization of Magmas
John C. AyersVanderbilt University
Objectives
• Use three methods to explore the crystallization behavior of a rock of known composition at 1 atmosphere pressure:– Experimental method: Melt your rock at 1300°C and then cool it to 1000°C
using a programmable glass melting furnace. Make grain mounts of your run products and identify the phases. We may also use the SEM to image and analyze your run products.
– Phase diagram method: Calculate the normative composition of your rock and plot it on the Fo-An-Si diagram; predict the crystallization sequence.
– Numerical method: Use the computer program MELTS to predict the crystallization sequence. Also explore differences in crystallized assemblages and evolution of liquid compositions between batch and fractional crystallization.
• Use the chemical composition of the rock to classify it and to make up REE, tectonic discrimination and spider diagrams and interpret them.
Skill: Creating plots in Excel and Interpreting
• What rock did your group work on? ______________________• Use the Excel template NormCalc.xlt to calculate the normative mineralogy of your rock. What
are the normative minerals in your rock, and their percentages? • Enter major element concentrations into cells C2:E2 on sheet “My Data” in the Excel template
Alkalinity.xlt. Is your rock alkaline or subalkaline? What rock type is it classified as in the TAS (Total Alkalis vs. Silica) diagram?
• For samples QLO-1 and GSP-2 only: Enter the normative composition of your rock into cells B17:D17 on sheet “Ternplot” in the Excel template TTGternaryplot.xlt. What is the classification of your rock?
• Enter trace element concentrations into cells B3:B10 on sheet “My Data” in the Excel template Discrimination.xlt. Examine the various plots that are automatically produced on the other sheets. What conclusions can you draw about the tectonic environment that your rock formed in?
• Replace the values in cells B2:B16 in the sheet “Normed REE data” in the template REEPlot.xlt with the REE concentrations in your rock in ppm. Describe the shape of the REE pattern. Is your rock enriched or depleted in the LREE? Explain why. Is there a Ce or Eu anomaly? Why or why not?
• Replace the values in cells B2:B29 in the sheet “Normalized T.E. data” in the template SpiderPlot.xlt with the trace element concentrations in your rock in ppm. What are the characteristic features? What conclusions can you draw about the environment that your rock formed in?
AlkalinityTAS Diagram
GSP-2
Si02 (%)
Na2
O +
K2O
(%) Foidite
Picro-basalt
Basalt
Trachy-basalt
Basaltic An-
desite
Andesite Dacite
Phonotephrite
Tephriphonolite
Phonolite
Trachyte (Q<20%)
Trachydacite (Q>20%)
Rhyolite
Basaltic Tra-chyandesite
Trachy-andesite
Tephrite (Ol<10%)Basanite (Ol>10%)
TAS Diagram With Alkaline/Subalkaline Divisions for Selected NDC Samples
GSP-2
Irvine and Baragar (1971)
Kuno (1966)
MacDonald (1968)
MacDonald and Katsura (1964)
Si02 (%)
Na2O
+ K
2O (%
)
Subalkaline (Tholei-itic) Series
Alkaline Series
f(x) = NaN x + NaNR² = 0f(x) = NaN x + NaNR² = 0 K20 vs SiO2 for Selected Samples
GSP-2
SiO2 (%)
K20
(%)
Low K
Medium K
High K
Ternplot
GSP-2
Ab
An
OrTrondhjemite Granite
Tonalite
Grano-diorite
QuartzMonzonite
Sr/Yb vs. Yb
GSP-2
Yb (ppm)
Sr/Y
b (p
pm)
Adakites
ClassicalIsland Arc
Sr/Y vs. Y
GSP-2
Y (ppm)
Sr/Y
(ppm
)
Adakites
ClassicalIsland Arc
La/Yb vs. Yb (Chondrite Normalized)
GSP-2
YbCN
La/Y
bCN
Adakites ClassicalIsland Arc
Nb vs. Y
GSP-2
Y (ppm)
Nb
(ppm
)
ORG
WPG
VAG + syn-COLG
Rb vs. Y + Nb
GSP-2
Y + Nb (ppm)
Rb
(ppm
)
ORG
WPG
syn-COLG
VAG
Skill: Performing Experiments• In this exercise you will grow your own volcanic rock! First read
about Experimental Petrology at: http://serc.carleton.edu/research_education/equilibria/experimentalpetrology.html
• Make a grain mount of your rock powder using immersion oil with an index of fraction of 1.54.
• Use the optical microscope to identify the minerals in your rock.
• Create your volcanic rock, powder it, make a grain mount, describe and interpret the textures, and identify the minerals.– List the minerals and their approximate percentages. How do they
compare with the rock powder?– Are the minerals you identified consistent with the rock type?
Skill: Interpreting Phase Diagrams• Use the normative Fo (or
En), An and Si contents to plot your rock composition on the Fo-An-Si diagram.
• List the minerals in order of crystallization, and estimate the temperature at which they start to crystallize. Estimate the proportions of each phase in the rock when it solidifies.
Skill: Numerical Modeling• Read about MELTS at: http://
serc.carleton.edu/research_education/equilibria/melts.html• Use Melts to identify the equilibrium phases and their
compositions at the same conditions as your experiment.• Questions:
– How do the proportions of each phase compare with those observed in your run products? Try to explain any discrepancies.
– Explain the change in liquid viscosity with temperature (I believe this is just for liquid and not liquid + crystals).
– Does the Harker diagram you made look like ones in your text that we discussed in class (e.g., Crater Lake) for series of cogenetic rocks? Explain.
Liquid Viscosity Vs. Temperature
-2.65
-2.6
-2.55
-2.5
-2.45
-2.4
-2.35
-2.31125 1100 1075 1050 1025 1000
Temperature
log1
0 po
ise
wt% Oxides Vs. wt% SiO2
0
2
4
6
8
10
12
14
16
18
66.8053 67.8961 69.5224 70.9921 72.3089 73.4951wt% SiO2
wt%
oxi
des
wt% Al2O3wt% FeO +Fe2O3wt% MgOwt% CaOwt% Na2Owt% K2O
Wt% vs. T
0
20
40
60
80
100
120
1125 1100 1075 1050 1025 1000Temperatue Celsius
Wt%
LiquidSpinelFeldspar
Summary Questions
1. Compare the crystallization sequences predicted by the Numerical and Phase Diagram methods and observed using the Experimental Method. Try to explain any discrepancies.
2. How do you know the crystals in your run product grew during the experiment and were not retained from the starting material? How could you test this experimentally?
3. Which method is the most generally useful? Explain.4. Which method is likely to be most accurate? Explain.
Other Options
• Have students image and analyze phases in run products using SEM and EDS
• Have students use X-ray diffraction to identify phases in run products