Several of the icy moons of the outer solar system probably have subsurface oceans. Particularly interesting examples are Europa (a moon of Jupiter), and Enceladus and Titan (moons of Saturn). Thermodynamic models of the interiors of icy moons can benefit from an improved understanding of how the presence of various impurities will change the temperature and pressure-dependent properties of water and ice in any such subsurface ocean.
This project focuses on phase equilibria in aqueous solutions at pressures ranging from from 0.1 to 400 MPa.
"The Liquidus Temperature for Methanol-Water Mixtures at High Pressure and Low Temperature, With Application to Titan" Journal of Geophysical Research--Planets, with Lafayette co-authors Z.T. Bartholet, R.J. Chumsky, K.C. Delano, X. Huang, and D.K. Morris.
The apparatus consists of 3 main parts: a central high-pressure fitting containing the sample fluid, an optical system for imaging the sample, and a pressure system that includes both pressure and volume sensors
Diagrams of the pressure system (left) and imaging system (right). The imaged portion of the sample is confined to a 1~mm-wide gap between the two windows at the center of the cross. This system allows simultaneous measurements of pressure, temperature, and volume changes, along with optical images of the sample.
Exploded view of the pressure cell. Sapphire windows in steel plugs are mounted inside a steel cross. The image shows the relative positions of the plugs with windows and the plug containing the thermometer. The window separation is approximately 1 mm.
The imaging system consists of a lamp that shines light through an infrared filter and optical fiber that directs the beam horizontally through the sample cell. The infrared filter is used to minimize heating of the sample by the light source. After passing through the cell, the beam is reflected by 45o mirror upward through a matched pair of lenses to a long working distance optical microscope objective coupled to a Pulnix digital camera. The camera obtains images of a vertical cross-section of the sample, with 1392 \times 1040 pixels and an overall resolution of about 1.7 μm/pixel. The gap between the sapphire windows is approximately 1~mm. Although the camera's field of view does not cover the entire system, we typically observed dissolving or growing crystals corresponding to changes in temperature, pressure, and volume, indicating that the crystal images reflect the phase transitions within the sample. We have studied a variety of solutions likely to be relevant for the icy moons of the outer solar system, including aqueous mixtures of magnesium sulfate, sodium sulfate, methanol, and water.
Example screenshot from a run at 50 MPa. The transducer voltage (which varies linearly with volume) is plotted on the vertical scale, and the temperature is plotted on the horizontal scale. The red diamond shows the conditions corresponding to this specific image. Across the bottom are shown the date (YY/MM/DD) and time (HH:MM::SS), as well as the temperature, pressure, voltage, and rate of change of temperature. The image filename at the top of the screen includes the date, time, temperature and voltage, as well as the imaging lamp voltage, which varies from 0 to 12.0 Volts.
Here is David Hogenboom on Miranda, a moon of Uranus, taking a sample for analysis in the high pressure apparatus.