1. Microgravity Phase Separation Near the Critical Point in Attractive Colloids
- Author
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Salvatore Anzalone, Edward M. Fincke, William V. Meyer, Maria Havenhill, Henry Yee, Richard B. Rogers, Jay Owens, Michael Foale, Amber S. Krauss, Peter J. Lu, Jeffrey N. Williams, Monica I. Hoffmann, William S. Mcarthur, Leroy Chiao, Catherine A. Frey, Ronald J. Sicker, Gregory Funk, and David A. Weitz
- Subjects
Convection ,business.industry ,Photography ,Observable ,Mars Exploration Program ,Spaceflight ,law.invention ,law ,Critical point (thermodynamics) ,Phase (matter) ,Physics::Space Physics ,International Space Station ,Environmental science ,Aerospace engineering ,business - Abstract
We investigate the phase behavior of mixtures of colloids and polymers near their critical point in a microgravity environment. Astronauts onboard the International Space Station (ISS) are using photography to record the rate of phase separation of six samples near the liquid-gas critical point. These photographs are taken both by an automated photography system (based on EarthKAM hardware and software) and manually by the astronauts who have setup the experiment. We have obtained high-quality photographs of processes that are not observable on Earth, since both sedimentation and convection are negligible onboard the International Space Station. Interestingly, we observe that gravity does not affect the onset of phase separation in colloid-polymer mixtures near the liquid-gas critical point: samples which phase separate on earth also do so onboard the ISS. However, the rates at which this phase separation occurs is affected by several orders of magnitude by gravity, suggesting future avenues for exploration. The understanding of this system is important for both practical earth-bound applications, as well as the development of products and materials that are stable and functional over long periods of time in a lowgravity environment. Thus, our results may assist the long-term spaceflight required for proposed exploration missions to the moon and to Mars.
- Published
- 2007
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