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The origin of rhyolitic spherulites at Rockhound State Park. Nelia W. Dunbar Virginia T. McLemore New Mexico Bureau of Geology and Mineral Resources New Mexico Tech. Diameter = 14 cm. Schematic cross section of a Rockhound Spherulite. Questions. What are the spherulites made of?
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The origin of rhyolitic spherulites at Rockhound State Park Nelia W. Dunbar Virginia T. McLemore New Mexico Bureau of Geology and Mineral Resources New Mexico Tech
Questions • What are the spherulites made of? • What does the visible structure represent? • How do spherulites form? • Why are some hollow?
Electron microprobe used to produce: -Backscattered electron images (map of mean atomic number) -X-ray maps to show element distribution -Quantitative chemical analyses of spots as small as 1 micron
Minerals found in spherulites • Quartz (SiO2) • Two alkali feldspars (K, Na)[AlSi3O8] • Magnetite (Fe3O4)
Composition of rhyolitic magma • SiO2 76.6 wt.% • Al2O3 12.8 wt.% • K2O 4.9 wt.% • Na2O 3.8 wt.% • FeO 1.2 wt.% • CaO 0.5 wt.% • TiO2 0.1 wt.% • H2O 0.1 wt.%
Backscattered Electron image of spherulite core (field of view 1.2 mm)
BSE image of interior spherulite and medial “rapid-growth” crystals FOV 2.5 mm
BSE image of transition between “rapid-growth” and banded zone FOV 2.5 mm
Backscattered Electron image of spherulite (field of view 1.2 mm)
200 microns Silica X-ray map Backscattered electron image
200 microns Potassium X-ray map Backscattered electron image
200 microns Sodium X-ray map Backscattered electron image
20 microns Backscattered electron image Potassium X-ray map
20 microns Backscattered electron image Sodium X-ray map
Compositions of morphologically-different feldspar in RHP spherulite May represent crystallization in 2-feldspar field (T<~660oC)
Schematic cross section of a Rockhound Spherulite Outer layered part. Rhythmic intergrowth of quartz and two feldspars Core composed of many small, fine-grained spherulites (quartz and Na-rich alkali feldspar) Intermediate part. Feathery quench crystals of quartz and alkali, K-rich feldspar
Why are some spherulite hollow?Observations: • Within a single lava flow, some spherulites may be hollow whereas others are solid. In some cases, there appears to be some stratigraphic control on location of hollow vs. solid spherulites • In some hollow spherulites, the original solid form appears to have been expanded from within to form the void space. • Some “solid” spherulites contain many small, finely dispersed void spaces, which appear to be small bubbles.
Why are some spherulite hollow?Speculation: • Rhyolite magma contains 0.1 wt% H2O at atmospheric pressure, whereas quartz and feldspar are anhydrous. Crystallization would cause water to come out of solution and form bubbles. • From a simple ideal gas law calculation, at atmospheric pressure, 0.1 wt.% H2O would generate void space equal to 10 times the initial volume of crystallizing melt, ample to create the void space found in spherulites. • Creation of a void space requires coalescence of this H2O-dominated vapor phase. This may depend on some critical combination of crystal growth rate and pressure at which the spherulite forms.
Conclusions • Spherulites are composed of quartz, feldspar and magnetite • Spherulites grew at high temperatures from a rhyolitic magma, and the internal structure is controlled by crystallization dynamics. • Crystals near the core of the spherulite show texture typical of rapid crystal growth • Diffusion of elements at the crystal-melt interface may be responsible for banding • By analogy to experimental systems, spherulites may have grown in periods of days to weeks • The cavities could have been formed by H2O vapor generated during crystallization