TSS-1R/USMP-3 Public Affairs Status Report #13
6:00 a.m. CST, Feb. 29, 1996
6/15:42 MET
Spacelab Mission Operations Control
Marshall Space Flight Center


The third United States Microgravity Payload (USMP-3) 
completed another night of successful operations aboard the 
Space Shuttle Columbia, with the four experiments that make 
up the payload processing good data in the microgravity 
environment of Earth's orbit.  The smooth ride aboard 
Columbia, in free fall around Earth, was made even smoother 
yesterday as crew members restricted their movements in 
"quiescent" periods.  This allowed USMP-3 researchers with 
the MEPHISTO experiment to gather baseline data about the 
effects of movement on their delicate semiconductor material 
samples by comparing them to times of no activity.

The scientific activities of the MEPHISTO experiment, led by 
Dr. Jean-Jacques Favier of the French Atomic Energy 
Commission, included a study of "g-jitter," or microgravity 
disturbance effects such as those caused by crew activities 
and orbiter thruster firings.  As expected, the first 25-
second thruster firing, or "burn," produced accelerations of 
more than 10,000 micro-g's, a force equal to one- hundredth 
of Earth's gravity, and provided a significant response in 
the experiment's real-time data transmission.  Another 15-
second firing also produced a marked change in this signal.  
The science team observed that the measurements continued to 
increase for a few minutes after each of these burns before 
slowly decreasing.  Before and after each thruster firing, 
the crew remained in a relatively still mode to allow 
scientists to perform real-time correlations of MEPHISTO's 
data with information collected from the Space Acceleration 
Measurement System (SAMS) aboard the Shuttle.

The understanding gained from the MEPHISTO experiment may 
ultimately lead to improvements in materials preparation and 
processing on Earth.  MEPHISTO uses very selective methods to 
study the role of gravity-driven fluid flows in the 
solidification of materials.  Microgravity reduces fluid 
flows caused by sinking and rising, allowing researchers to 
explore effects normally hidden by gravity.

This morning, the Marshall Space Flight Center's Advanced 
Automated Directional Solidification Furnace (AADSF) began 
its first experiment operations, melting a lead-tin-telluride 
sample to test theories about gravity's effects on growing 
semiconductor materials.  Today, the instrument's science 
team, led by Principal Investigator Dr. Archie Fripp, will 
continue melting and positioning all three samples, then 
actually start growing crystals by seeding and re-solidifying 
the lead-tin-telluride alloy.

Yesterday afternoon, Pilot Scott Horowitz and Mission 
Specialist Claude Nicollier performed runs of the Lewis 
Research Center-managed Forced Flow Flamespreading Test 
(FFFT) experiment in the Middeck Glovebox Facility.  They 
burned flat paper samples to help the science team, led by 
Glovebox Investigator Kurt Sacksteder, study how air motion 
affects flame spreading in microgravity.

Scientists who study combustion want to know the details of 
how air motion affects flame spreading and how to better 
control fires that may occur on orbit.  On Earth, gravity 
causes hot air to rise and cool air to fall.  Because of the 
complexity of the physical and chemical processes involved, 
the theoretical understanding of flame spreading in space is 
still a relatively new science.  The microgravity environment 
available in the self-contained Glovebox aboard the Space 
Shuttle is an important tool for scientists and engineers to 
study this important phenomenon.

The Isothermal Dendritic Growth Experiment (IDGE), developed 
by the Rensselaer Polytechnic Institute, has completed 15 
dendrite growth cycles during its primary science phase.  
Images of free-floating dendrites, acquired during melting 
after a growth cycle, show no detectable motion compared with 
images of dendrites attached to the experiment's container.  
Analysis of such post-melting images help researchers define 
the mobility limits of the free-floating, pine tree-shaped 
dendrite crystals in the microgravity environment.

The Zeno Critical Fluid Light Scattering Experiment's sample 
cell temperature continues to approach the critical 
temperature and pressure at which xenon exists simultaneously 
in both the liquid and vapor phases.  Zeno uses precise 
light-scattering measurements as an unintrusive way of seeing 
changes in a xenon sample as it fluctuates rapidly between 
two states of matter.

In addition to continued sample processing by the four USMP-3 
investigations, the next 12-hours will begin with the first 
in a series of Comparative Soot Diagnostics combustion 
experiment runs in the Middeck Glovebox.

Status reports are issued from Marshall Space Flight Center's Spacelab 
Mission Operations Control at 6 a.m., and from Johnson Space Center's 
Mission Control at 8 a.m. and 5 p.m.  For additional information, see 
the USMP-3 payload Internet homepage at http://liftoff.msfc. 
nasa.gov/sts-75/usmp-3/usmp-3.html, the TSS-1R payload Internet 
homepage at http://liftoff.msfc.nasa.gov/sts-75/tss-1r/tss-
1r.html and the STS-75 Shuttle Mission Internet homepage at 
http://www.ksc.nasa.gov/ shuttle/missions/sts-75/mission-sts-
75.html or at http://shuttle.nasa.gov.