Original Source: NASA Goddard Space Flight Center

January 22, 2002

New flight record of the TIGER balloon experiment.

Image copyright: National Scientific Balloon Foundation

Larger than a football field and flying near the edge of space, a NASA scientific balloon has set a new flight record of almost 32 days after completing two orbits around the South Pole.

The record-breaking balloon carried the Trans-Iron Galactic Element Recorder (Tiger) experiment, designed to search for the origin of cosmic rays, atomic particles that travel through the galaxy at near light-speeds and shower the Earth constantly.

The pilotless, helium-filled scientific balloon was launched from McMurdo Station, Antarctica, at 6:30 a.m. EST on Dec. 20, 2001. The balloon traveled approximately 1,400 kilometers before landing about 31 days, 20 hours later at 3:03 a.m. EST, Jan. 21, 458 kilometers from the McMurdo Station. Payload recovery operations are in progress.

The previous endurance record for a long-duration balloon flight was set in January 2001 from McMurdo. The flight was one orbit of the South Pole that lasted 26 days. The Tiger mission was able to more than double the amount of continuous science observational time over any previous balloon mission.

"We are excited with the duration of this flight, which allowed the scientists to get ample science to perform their studies," said Steve Smith, Chief of the Balloon Program Office at NASA Goddard Space Flight Center's Wallops Flight Facility, Wallops Island, Va. "We routinely have long- duration balloons that float for up to two weeks, but to have one flight last for over 31 days is very rewarding."

Image copyright: TIGER

Scientific balloons are made of thin polyethylene material, about the same thickness as ordinary sandwich wrap. An enormous balloon was needed to hoist the two-ton Tiger experiment to about 38,100 meters. The Tiger balloon is taller than the Washington Monument, which stands just over 555 feet high. As the balloon rises, the gas it contains expands. The balloon used for this Antarctic flight expanded to a diameter of more than 129 meters and weighed 1,674 kilograms.

To complete the flight, the experiment and its parachute float to the ground after being separated from the balloon by radio command. Helium was released from the balloon for its descent near McMurdo station.

"The importance of Tiger is that it is the first experiment that has both sufficient collecting power and adequate resolution to measure abundances of all nuclei from iron through zirconium," said Tiger Principal Investigator Robert Binns, Washington University, St. Louis. "This will enable us to determine whether the cosmic-ray source is hot or cold, gas or solid. We have already seen in our quick-look analysis of flight data that Tiger's resolution is sufficient to resolve those nuclei."

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see also:

• NASA News from Jan 03, 2002

• TIGER website at the Washington University at St.Louis

• TIGER website at NASA's Goddard Space Flight Center