Publications Topics:

Books

ASP Conference Series

Monograph Publications

IAU Publications

Books of Note

Purchase through the AstroShop

Journals

Publications of the ASP (PASP)

Magazines

Mercury Magazine

Archive

Guidelines for Authors

Order Mercury Issues

Mercury Advertising Rates

Newletters

The Universe in the Classroom

ASP E-mail Newsletters

Special Features

Astronomy Beat

Contact Us

Mercury, July/August 2003 Table of Contents

by William Sheehan

For more than a century, astronomers tried to measure the average Earth-Sun distance, known as the astronomical unit (AU), by observing rare transits of Venus. Unfortunately, the limbs of Venus and the Sun are not sharply defined. Because of atmospheric turbulence, the darkening of the Sun toward its limb, and optical constraints on resolution, the disks of Venus and the Sun blur together, which makes accurate transit timings impossible. Without this accuracy, astronomers cannot measure the AU to extremely high precision.

After being disappointed by results at the 1874 transit of Venus, David Gill turned to observations of Mars near opposition as a way of obtaining precise measurements of the AU. When observing Mars from opposite ends of Earth (one can do this effectively simply by observing Mars at sunrise and sunset), Mars’s position relative to the distant stars appears to shift. By measuring this displacement (parallax) and knowing the length of the baseline between the two observing sites, one can determine Mars’s distance. A value of the AU follows because Mars’s distance is related to Earth’s distance from the Sun by Kepler’s third law of planetary motion, which relates the planet’s distance from the Sun to its period of revolution.