The Edge of Sunshine

Solar energy is an abundant source of power for spacecraft navigating the inner solar system. But how far away from our star can photovoltaics work?

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January 8, 2002:  Try this: Close your eyes for a moment and imagine the International Space Station (ISS), sunlit and gleaming as it circles our planet.

What did it look like? The lingering image in your mind is probably dominated by broad, beautiful wings -- the station's awesome solar arrays.

It's no accident that solar panels dominate the station's profile. On the ISS (as on the earth below) solar energy ultimately powers everything that happens. Our Sun, a star named Sol, radiates enormous power: a constant output of 4 x 10²³ kilowatts (kW), which is a 4 followed by 23 zeros! Photovoltaic cells, which convert sunlight to electricity, need only intercept a tiny fraction of that total to energize the station.

Above: The International Space Station in December, 2001. Credit: the crew of STS-108.

But not all spacecraft linger near Earth where sunlight is plentiful. Many NASA probes travel far beyond our planet's orbit. And as they do, the Sun grows more distant and dim. Somewhere out there, solar power ceases to be a useful source of energy for spacecraft. But where?

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That's what NASA spacecraft builders want to know: Where is the edge of sunshine?

The Space Station's solar cells, developed decades ago, convert 14% of the Sun's energy that hits them into electricity, and modern multibandgap cells, which convert light in multiple parts of the spectrum into electric power, reach efficiencies of 30% or so. Such devices work well enough in the brightly-lit inner solar system, but more efficient cells and larger arrays will be needed as spacecraft travel to places where solar photons are scarce. In the outer reaches of the solar system, for instance, the ability to convert even single photons into electricity would be important.

"Sunlight decreases in intensity over distance by a factor of 1/r², where r is the distance from the Sun," explains Geoff Landis, a scientist at NASA's Glenn Research Center. "This means a 1-meter-square solar array producing 400 watts at a distance of 1 AU would have to be 25 square meters in size out at Jupiter -- and almost 2,000 square meters at Pluto to yield the same power." (Note: An astronomical unit or "AU" is the mean distance between Earth and the Sun. 1 AU equals 150 million kilometers.)

Left: The Sun as viewed from distant Pluto is just another star in the night sky, albeit the brightest one. Space artist (and space physicist) Dan Durda painted this view from the 9th planet.

Landis and his colleagues at Glenn's Photovoltaics and Space Environment Branch are exploring new ways to harness the Sun's power -- including more efficient solar cells, laser-beaming energy to distant spacecraft, and solar power systems for the Moon and Mars. "The use of solar power is a complex field of study," says Landis. "Finding solutions requires that we balance such factors as distance, weight, the energy of different light bands, and the actual materials available to us."

"Using today's technologies," he says, "the 'edge' of sunshine we can use is about four astronomical units away from the Sun, where the sunlight is about one-sixteenth as bright as it is near the Earth." That's beyond the orbit of Mars (1.5 AU), but closer to the Sun than Jupiter (5.2 AU).

"With tomorrow's technologies we hope to push that edge further out into the solar system," he says. "Future solar collectors, for example, might use advanced thin films -- almost like Saran Wrap -- and very lightweight solar cells, which can roll out to an acre or more in size. Instead of a spacecraft that carries a solar array with it, you would have a solar array that carries a spacecraft."

Such expansive sails would also be targets for fast-moving space-dust, so they would need to be crafted from puncture-resistant or self-sealing materials. Yet another challenge for spacecraft builders!

Above: A solar sail concept, from the 1999 Science@NASA story "Setting Sail for the Stars."

To date, the farthest any solar-powered spacecraft has ventured from the Sun is 2.35 AU -- a record set last October by NASA's Stardust probe. Stardust will extend its own record every day until April, 2002, when it will reach a maximum distance from the Sun of 2.72 AU en route to Comet Wild 2. Stardust's solar arrays are actually producing more energy than expected, perhaps because its photovoltaic cells operate more efficiently in the cold of deep space than in Earth labs. No one is certain; this is unexplored territory.

Above: (left) An artist's impression of Stardust as it encounters Comet Wild 2 in 2004. The craft's solar panels are prominent in this illustration. (right) The spacecraft's orbit, courtesy of JPL's web site "Where is Stardust Right Now?".

Not quite as far from the Sun as Stardust, NASA's experimental spacecraft Deep Space 1 recently tested a "solar concentrator" -- 720 lenses that focused sunlight onto 3600 solar cells. Deep Space 1 was the first solar-powered probe to rely entirely on triple-junction multibandgap cells. The small but innovative system generated 2500 watts: enough to energize three microwave ovens and more than enough to power the craft's ion engine.

Such advances will eventually propel solar power into deep space -- perhaps out of the solar system altogether.

"In the long term, solar arrays won't have to rely on the Sun," Landis said. "We're investigating the concept of using lasers to beam photons to solar arrays. If you make a powerful-enough laser and can aim the beam, there really isn't any edge of sunshine-- with a big enough lens, we could beam light to a space-probe halfway to alpha-Centauri!"

Right: This artist's concept shows a ground station beaming power to a distant spacecraft. [more]

Beaming light power to targets on Earth, in orbit, on the Moon or on Mars and other planets -- or to distant spacecraft -- is the stuff of science fiction. That's right up Geoff Landis' alley. He's also a Hugo and Nebula award-winning science fiction writer! As a scientist he and his NASA cohorts are in the business of reaching out to the edge of sunshine every day, seeing fiction very rapidly and certainly turning into fact.

The Power and Propulsion Office at NASA Glenn Research Center (GRC) manages the development of power technologies to meet the needs of all NASA Enterprises.

Multi-junction solar cells use more of the Sun's energy than older single-junction models. (DOE)

Solar energy on Mars -- (GRC) rovers and landers on the Red Planet can use solar power, too.

Solar power on the Moon -- (GRC) an article by Geoff Landis.

Geoffrey A. Landis -- a research scientist and member of the Photovoltaics and Space Environment Branch, NASA John Glenn Research Center

Right: A self-deploying photovoltaic array on the Moon. Artist's concept by Les Bossinas, NASA Lewis Research Center.

Power to The ISS -- (Science@NASA) Electric power is the Space Stations most important resource.

How Do Photovoltaic Cells Work? -- (Science@NASA)<

Deep Space 1 used solar concentrators to make the most of its photovoltaic arrays.

NASA's Stardust probe is en route to Comet Wild 2. It is the most distant spacecraft powered by the Sun.

Stardust Status Reports:

• Oct 05, 2001 - Stardust sets solar-power distance record.
• Nov 02, 2001 - Spacecraft is not using its battery yet.
• Nov 16, 2001 - Solar arrays generating more than expected power.

Thermophotovoltaics -- The conversion of electromagnetic radiation from thermal (non-solar) sources to electricity is known as thermophotovoltaic power generation.

A New Star In The Sky -- (Science@NASA) Solar wings help make the ISS among the brightest objects in the night sky

Powering the Future -- (GRC) a fact sheet about ISS power systems

What is an Astronomical Unit?