Abstract
Context. Laboratory analogues can provide physical constraints to the interpretation of astronomical observations of cosmic dust but clearly do not experience the same formation conditions. To distinguish between properties intrinsic to the material and properties imprinted by their means of formation requires extensive characterisation.Aims. Sol–gel methods can produce amorphous silicates with potentially high reproducibility, but often require long drying times (24+ h) at elevated temperatures in air, controlled atmosphere, or vacuum. We investigate the possibility that microwave drying can be used to form amorphous silicate on a timescale of ∼10 min and characterise their structural and spectroscopic properties relative to silicates produced by other drying methods.Methods. Microwave-dried amorphous MgSiO3, Fe0.1Mg0.9SiO3and Mg2SiO4are characterised using X-ray powder diffraction, total X-ray scattering, small angle X-ray scattering and mid-IR FTIR spectroscopy, and compared to samples produced from the same gels but dried in-air and under vacuum. The development of crystalline structure in the microwave-dried silicates via thermal annealing up to 999°C is also investigated using in situ X-ray powder diffraction.Results. At the inter-atomic level the silicate structures are largely independent of drying method, however larger-scale structured domains, ranging from a ∼few × 10 Å to ∼100’s Å in size, are observed. These are ordered as mass fractals with discernible variation caused by the drying processes. The mid-IR 10μm band profile is also found to be influenced by the drying process, likely due to the way removal of water and bonded OH influences the distribution of tetrahedral species. However, microwave drying also allows Fe to be easily incorporated into the silicate structure. In situ annealing shows that for amorphous MgSiO3crystalline forsterite, enstatite and cristobalite are high temperature phases, while for Mg2SiO4forsterite crystallises at lower temperatures followed by cristobalite at high temperature. For Fe0.1Mg0.9SiO3the crystallisation temperature is significantly increased and only forsterite is observed. Crystalline SiO2may be diagnostic of Mg-rich, Fe-poor grain mineralogies. The results are discussed in relation to the different thermal conditions required for dust to crystallise within protoplanetary disk lifetimes.Conclusions. Sol–gel microwave drying provides a fast and easy method of producing amorphous Mg- and Fe,Mg-silicates of both pyroxene and olivine compositions. Their structure and spectroscopic characteristics although similar to silicates produced using other drying methods, exhibit subtle variations which are particularly manifest spectroscopically in the mid-IR, and structurally over medium- and long-range length scales.
Highlights
Grains of cosmic dust play a significant role in the evolution of the material universe and information on their composition and physical state can be derived through a combination of astronomical observations, analysis of recovered materials and laboratory experimentation using analogue materials
In situ annealing shows that for amorphous MgSiO3 crystalline forsterite, enstatite and cristobalite are high temperature phases, while for Mg2 SiO4 forsterite crystallises at lower temperatures followed by cristobalite at high temperature
The results are discussed in relation to the different thermal conditions required for dust to crystallise within protoplanetary disk lifetimes
Summary
Grains of cosmic dust play a significant role in the evolution of the material universe and information on their composition and physical state can be derived through a combination of astronomical observations, analysis of recovered materials and laboratory experimentation using analogue materials. The use of analogues requires extensive laboratory characterisations to differentiate between physical properties intrinsic to the material, and of likely application to cosmic matter, and those properties imparted by the specific method of preparation which, in all likelihood, is quite removed from the means by which cosmic grains form It should be self-evident that no single analogue can simulate all of the dust in all of the environments accessible to observation. Simulating cosmic dust by analogues is as much about understanding the analogues
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