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Rovers Will Unroll a Telescope on the Moon鈥檚 Far Side

The far side of the moon offers a unique opportunity to radio astronomers: an observatory built there could peer into the early universe, shielded from electromagnetic interference from Earth. Illustration Peter Sanitra

From IEEE Spectrum: For decades, astronomers have gazed up at the moon and dreamed about what they would do with its most unusual real estate. Because the moon is gravitationally locked to our planet, the same side of the moon always faces us. That means the lunar far side is the one place in the solar system where you can never see Earth鈥攐r, from a radio astronomer鈥檚 point of view, the one place where you can鈥檛 hear Earth. It may therefore be the ideal location for a radio telescope, as the receiver would be shielded by the bulk of the moon from both human-made electromagnetic noise and emissions from natural occurrences like Earth鈥檚 auroras.

Early plans for far-side radio observatories included telescopes that would use a wide range of frequencies and study many different phenomena. But as the years rolled by, ground- and satellite-based telescopes improved, and the scientific rationale for such lunar observatories weakened. With one exception: A far-side telescope would still be best for observing phenomena that can be detected only at low frequencies, which in the radio astronomy game means below 100 megahertz. Existing telescopes run into trouble below that threshold, when Earth鈥檚 ionosphere, radio interference, and ground effects begin to play havoc with observations; by 30 MHz, ground-based observations are precluded.

In recent years, scientific interest in those low frequencies has exploded. Understanding the very early universe could be the 鈥渒iller app鈥 for a far-side radio observatory, says Jack Burns, an astrophysics professor at the University of Colorado and the director of the NASA-funded Network for Exploration and Space Science. After the initial glow of the big bang faded, no new light came into the universe until the first stars formed. Studying this 鈥渃osmic dawn [PDF],鈥 when the first stars, galaxies, and black holes formed, means looking at frequencies between 10 and 50 MHz, Burns says; this is where signature emissions from hydrogen are to be found, redshifted to low frequencies by the expansion of the universe.