NASA has launched its most ambitious scientific balloon ever. On December 28 at 21:16 London time, technicians inflated and released a 532,000-cubic-metre aerostatic balloon from near McMurdo Station in Antarctica. It is the biggest test yet of a 'super-pressure' design that enables a balloon to stay aloft much longer than a conventional scientific balloon.

If all continues smoothly, experts expect the flight to last for 100 days or longer. The current record for the longest NASA scientific ballooning flight is 55 days, using a traditional balloon. The record for a super-pressure balloon is just a day shorter, at 54 days.

More time aloft equals more science. The new super-pressure balloon is carrying a γ-ray telescope to hunt for high-energy photons streaming from the cosmos. Known as the Compton Spectrometer and Imager (COSI), it can detect where in the sky these γ rays are coming from, and thus begin to unravel various astronomical mysteries.

COSI is the first science payload designed from scratch to take advantage of NASA’s super-pressure technology, says team leader Steven Boggs, an astrophysicist at the University of California, Berkeley. Its predecessors used liquid nitrogen to cool themselves, meaning that the nitrogen ran out in less than 10 days. COSI carries a mechanical cooler that contains nothing to run out of.

The imager stares upward and gathers data through the body of the balloon above it, which is transparent at the γ-ray energies it studies. It can scan about 50% of the sky overhead during the course of a day.

One of its main goals is to measure polarization in γ rays streaming from γ-ray bursts, black holes, pulsars and other cosmic phenomena. The longer it flies, the more data it will be able to gather. “The long flight time is key for this study,” says Boggs.

NASA has been pushing to expand its balloon programme as a way to get payloads above most of Earth’s atmosphere without the expense of a satellite launch.

Conventional helium balloons shrink at night, because the pressure of the gas inside them decreases when the temperature cools. The reduced volume makes the balloons lose buoyancy, and therefore altitude. They regain some of that altitude during the heat of the day, but the constant fluctuations up and down make it harder to gather clean data. Actively adjusting for the fluctuations requires releasing gas and dropping of ballast, both of which limit the duration of the flight.

In contrast, super-pressure balloons have embedded ropes that keep their volume roughly constant, helping them to keep a roughly constant altitude in a passive manner. “It gives you a stable altitude when the Sun goes away,” says Debora Fairbrother, head of NASA’s balloon programme office at the Wallops Flight Facility on Wallops Island, Virginia.

NASA tested its 532,000-cubic-metre super-pressure balloon in Kiruna, Sweden, in 2012, but the new launch is the first to carry major science. It is carrying a payload of 2,300 kilograms to an altitude of about 33.5 kilometres.

Because the flight may last for 100 days or more, the agency had to get permission from countries such as New Zealand in case the balloon drifts into their airspace, Fairbrother says. Conventional balloon flights that last only a few weeks generally make a circuit or two around Antarctica, blown by the circumpolar winds. If COSI goes as long as expected, it could leave the continent and move northward.

From there, it’s a matter of watching and waiting and bringing the balloon and its payload down on a landmass where NASA can recover the telescope. “If we have to terminate over water, it’s lost,” Fairbrother says. (The 54-day record for a super-pressure balloon flight could have gone longer except for the fact that NASA had to bring it down over land because it did not have permission to leave the continent.)

The COSI team has already seen its share of ballooning heartbreak. In 2010, during a conventional balloon launch in Alice Springs, Australia, the instrument that was the COSI predecessor was lost when the balloon wouldn’t release from the deployment mechanism. The December 28 launch was also delayed a year because of the US government shutdown in October 2013, which cancelled much of the Antarctic research season.

This article is reproduced with permission and was first published on December 29, 2014.