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Observational study: microgravity testing of a phase-change reference on the International Space Station

2015; Nature Portfolio; Volume: 1; Issue: 1 Linguagem: Inglês

10.1038/npjmgrav.2015.9

2373-8065

Tony Topham, Gail E. Bingham, Harri Latvakoski, Igor Podolski, Vladimir S Sychev, A. Burdakin,

Magnetic and Electromagnetic Effects

Orbital sensors to monitor global climate change during the next decade require low-drift rates for onboard thermometry, which is currently unattainable without on-orbit recalibration. Phase-change materials (PCMs), such as those that make up the ITS-90 standard, are seen as the most reliable references on the ground and could be good candidates for orbital recalibration. Space Dynamics Lab (SDL) has been developing miniaturized phase-change references capable of deployment on an orbital blackbody for nearly a decade.Improvement of orbital temperature measurements for long duration earth observing and remote sensing.To determine whether and how microgravity will affect the phase transitions, SDL conducted experiments with ITS-90 standard material (gallium, Ga) on the International Space Station (ISS) and compared the phase-change temperature with earth-based measurements. The miniature on-orbit thermal reference (MOTR) experiment launched to the ISS in November 2013 on Soyuz TMA-11M with the Expedition 38 crew and returned to Kazakhstan in March 2014 on the Soyuz TMA-10 spacecraft.MOTR tested melts and freezes of Ga using repeated 6-h cycles. Melt cycles obtained on the ground before and after launch were compared with those obtained on the ISS.To within a few mK uncertainty, no significant difference between the melt temperature of Ga at 1 g and in microgravity was observed.