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Space Topics: Extrasolar Planets

Transit Photometry: A Method for Finding Earths

This method seeks to detect distant planets by measuring the minute dimming of a star as an orbiting planet passes between it and the Earth. The passage of a planet between a star and the Earth is called a "transit." If such a dimming is detected at regular intervals and lasts a fixed length of time, then it is very probable that a planet is orbiting the star and passing in front of it once every orbital period.

The dimming of a star during transit directly reflects the size ratio between the star and the planet: A small planet transiting a large star will create only a slight dimming, while a large planet transiting a small star will have a more noticeable effect. The size of the host star can be known with considerable accuracy based on its spectrum, and photometry therefore gives astronomers a good estimate of the orbiting planet's size, though not its mass. This makes photometry an excellent complement to the spectroscopic method, which provides an estimate of a planet's mass, but not its size. Using both methods, scientists can calculate the planet's density, and hence its composition.

Advantages

Disadvantages

Another problem is that a planet's transit lasts only a tiny fraction of its total orbital period. A planet might take months or years to complete its orbit, but the transit would probably last only hours or days. As a result, even when astronomers observe a star with a transiting planet, they are extremely unlikely to observe a transit in progress. The problem is further compounded because in order to establish the presence of a planet, astronomers need to observe not one, but repeated transits occurring at regular intervals.

Search Strategies

Obviously, no planet hunter can accomplish such observations on his own, even if he or she is equipped with the most sensitive equipment for measuring starlight. Only an automated telescope that records its observations over long stretches of time can effectively detect planets using this method. Several such projects are underway across the world.

Selected Photometry Projects

The chances of any one fo these stars undergoing a transit is very small, but because of the huge number of stars being tracked, scientists hope to observe hundres if not thousands of transits. Kepler's sensitivity is such, that astronomers expect to detect several dozen planets of Earth-like mass, orbiting at an Earth-like distance from their star. But of course, no one will really knows until the spacecraft is launched.

Once in space Kepler will follow the Earth around the Sun, completing one revolution in each year for at least four years. This time-span will enable Kepler to track at least four transits of planets orbiting at Earth-like distances from their stars - quite engh to establish their presence with a high degree of certainty.

Most photometry searches, however, are Earth based, and make use of existing telescopes combined with state of the arts photometers of the highest sensitivity. One of these receives extensive support from The Planetary Society. Under the direction of Dr. Steven Howell, a team from the Planetary Science Institute (PSI), in consortium with three other institutions, is refurbishing the 50 inch telescope at Kitt Peak, and turning it into an RCT - a remote control telescope. Once completed, the PSI team, under the direction of Steven Howell, will be able to use the telescope for large stretches of time in its photometric search for extrasolar planets.

Photometry and Amateur Astronomers

In May 2001, for example, thousands of amateur astronomers around the world turned their telescopes towards a nearby red dwarf known as Gliese 876. This star was known to be orbited by two planets, both of which were discovered using the spectroscopic method. Since the star is small, and the planets orbiting it are large, the transit of the larger of the two dimmed the star substantially. This made it possible for amateurs the world over to observe the telltale signs of the presence of an extrasolar planet.

--Amir Alexander