/ 07 02 07 0 v 1 2 F eb 2 00 7 Low frequency radio astronomy from the moon : cosmic reionization and more

We discuss low frequency radio astronomy from the moon, predominantly in the context of studying the neutral intergalactic medium during cosmic reionization using the HI 21cm line of neutral hydrogen. The epoch of reionization is the next frontier in observational cosmology, and HI 21cm studies are recognized as the most direct probe of this key epoch in cosmic structure formation. Current constraints on reionization indicate that the redshifted HI 21cm signals will likely be in the range of 100 MHz to 180 MHz, with the pre-reionization signal going to as low as 10 MHz. The primary observational challenges to these studies are: • ionospheric phase fluctuations • terrestrial radio frequency interference • Galactic and extragalactic foreground radiation. Going to the far side of the moon removes the first two of these challenges. Moreover, a low frequency telescope will be relatively easy to deploy and maintain on the moon, at least compared to other, higher frequency telescopes. We discuss the potential 21cm signals from reionization, and beyond, and the telescope specifications needed to measure these signals. We then describe ground-based projects currently underway to study the HI 21cm signal from cosmic reionization. We include a brief discussion of other very low frequency science enabled by being outside the Earth's ionosphere. The near-term ground-based projects will act as path-finders for a potential future low frequency radio telescope on the moon, both in terms of initial scientific results on the HI 21cm signal from cosmic reionization, and in terms of the telescope design and observing techniques required to meet the stringent sensitivity and dynamic range requirements. If it is found that the terrestrial interference environment, or ionospheric phase fluctuations, preclude ground-based studies of reionization, then it becomes imperative to locate future telescopes on the far side of the moon. Besides pursuing these path-finder reionization telescopes, we recommend a number of near-term studies that could help pave the way for low frequency astronomy on the moon.