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Astronomy enthusiasts around the world are gearing up for Tuesday’s celestial show: the transit of Venus across the face of the Sun. The small black dot of Venus, silhouetted against the bright Sun, will be visible with safe solar telescopes and, to those with especially good vision, with the naked eye when protected by eclipse glasses. If the weather permits, visitors can watch the first two hours of the transit at the National Air and Space Museum.

Some people may have witnessed the last transit, in 2004, but the next transit won’t be until 2117. So it’s a rare astronomical event, occurring in eight-year pairs spaced more than a century apart. But what’s the big deal about a dot crossing the Sun?

The transit of Venus is more than a good show. The transits of the 18^th century provided the “yardstick” upon which much of modern astronomy is based.

The German astronomer Johannes Kepler had worked out the relative positions of the planets in 1619 – for instance, that Venus’s orbit is about 70% of the size of Earth’s – but no one had made an accurate measurement of the absolute distance between the Earth and the Sun. Without understanding this fundamental distance, astronomers could not grasp the enormous size of the Sun, nor start to measure the distance to the nearest stars.

Parallax is a technique of using widely spaced observing sites to estimate distance using trigonometry. It is a critical part of human vision, called depth perception. Test it out for yourself by holding up a finger in front of you, and closing alternate eyes. The finger appears to jump back and forth against the more distant background. Parallax is only useful for distances which aren’t enormously larger than the distance between the observing sites (the baseline, which is the distance between the eyes for human depth perception). It may help you estimate the distances to objects in a room, but it won’t help you figure out which of two mountains is closer. Similarly, astronomers need a large baseline to have any hope of measuring stupendous astronomical distances.

The first scientific determination of the distance between the Earth and the Sun was done in 1671-1673 by the astronomer Giovanni Cassini, who used parallax to measure the distance to Mars. He measured the position of Mars against the background stars from Paris while a colleague, Jean Richer, simultaneously measured its slightly different position from French Guiana. He knew the baseline – the distance between their observing sites – and therefore he could calculate the distance to Mars. Using Kepler’s orbits, Cassini calculated the distance to the Sun. He found a distance of 140 million kilometers, which was within 7% of the true value.

Observers at different locations on the Earth see Venus take different paths across the Sun. Image © The Exploratorium, www.exploratorium.edu.

The English astronomer Edmund Halley suggested using the transit of Venus as a more precise cosmic yardstick, though he did not live to see it work. For the transits of 1761 and 1769, astronomers traveled all over the world, getting as long a baseline as possible, to implement his idea. It was the first major international collaboration of scientists for astronomy. They carefully timed how long it took for Venus to cross the Sun’s disk, which helped fix Venus’s path across the Sun. Observers in far-flung locations recorded slightly different paths taken by Venus across the Sun (see figure). They used parallax to find the distance between the Earth and the Sun. Their measurements were accurate within about 2%: they found a distance of about 153 million km (95 million miles), while modern radar observations, again using Venus, pin the distance down at 150 million km (93 million miles). These distance measurements set the groundwork for much of future astronomy.

Point Venus in Tahiti, where James Cook observed the Transit of Venus in 1769. William Hodges, oil on canvas. Photo credit: National Library of Australia.

Join us at the National Air and Space Museum on Tuesday, June 5 for a presentation of the importance of the transit of Venus. From 5:45 – 6:30 pm, Museum experts will discuss the science and the history of Venus transits while the transit itself, beginning just after 6 pm, will be streamed onto the gallery’s large screens. Afterward, if weather permits, look through our safe solar telescopes to see the transit with your own eyes, attend a lecture on how we use transits to find planets around other stars, and finish up the evening with stargazing at the Public Observatory. Admission to all events is free, but tickets are required for the lecture.

Geneviève de Messieres is an astronomy educator at the National Air and Space Museum.

If you visit the Public Observatory during its daytime hours in May (1–3pm on Wednesday through Saturday, weather permitting), you can use the 16” telescope to observe an object which looks a lot like the Moon. Hanging in a blue sky, it shines with yellowish reflected sunlight. We can currently only see part of its illuminated side, giving it a crescent shape. You won’t spot any craters, though, and it looks a little fuzzy. It’s not the Moon, but the Earth’s twin, Venus — the planet which is most similar in orbit and size to the Earth. All eyes are on Venus now as it prepares for the show of the century: a transit across the face of the Sun.

Venus as seen through telescopes at the Public Observatory on April 25, 2012.

Venus and Mercury, the only two planets which orbit closer to the Sun than the Earth, can be seen in crescent phase when they start to pass between the Sun and the Earth. The only source of illumination is the Sun, so when Venus is between the Sun and the Earth, we see mostly the dark night side and only a sliver of the daylit side.

Phases of Venus. Image Credit: NASA

When Venus passes between the Earth and the Sun (its new phase), it is invisible because we are looking at its nighttime side. Venus is no more than a few degrees away from the Sun at this point, so anyone attempting to observe Venus when it is new or a slim crescent should be careful to not point their telescope at the Sun, even for an instant. Permanent eye damage could result from such an accident.

Does Venus go directly between the Earth and the Sun and cast its shadow on the Earth? Usually not. The orbit of Venus is tipped 3.3° with respect to Earth’s, so when Venus passes through its new phase, it usually goes above or below the Sun. Sometimes, however, the orbits line up. When Venus crosses directly between the Sun and the Earth, it blocks only 0.1% of the Sun’s light. The drop in overall sunlight is not noticeable, but when viewed through a telescope (safely!), the silhouette of Venus appears as a dark dot in front of the bright Sun. This event is called a transit.

The 2004 transit of Venus, observed by NASA's TRACE satellite. The faint halo on the lower left edge of Venus is sunlight shining through its atmosphere.

Transits of Venus occur at regular intervals, but they are rare. They come in pairs eight years apart, and more than a century passes between pairs of transits. There was a transit in 2004, and the second one in that pair occurs on June 5-6, 2012. The next transit will not happen until 2117. For nearly all of us, this is our last chance to see this event.

The transit can only be viewed by safely observing the Sun. During the 6-hour transit, Venus will be silhouetted against the disk of the Sun. Looking at the Sun with the naked eye can hurt the eyes, and pointing a telescope without a safe solar filter at the Sun will cause immediate telescope damage or permanent eye damage.

Here at the Public Observatory in Washington, DC, the transit will start shortly after 6 pm on June 5, 2012. The dome of the Observatory will already be in the shadow of the National Air and Space Museum building, so if the weather is clear, we will set up safe solar telescopes just outside the Museum’s entrance facing the National Mall. We will follow the transit until the Sun gets too low in the sky to observe. Sunset is at 8:31 PM that day, and we will see less than half of the transit from Washington, DC. We will also stream a live image to the Web, and tweet updates at @SIObservatory. The event is paired with a free presentation by Museum staff about the history and science of transits of Venus, a free lecture inside the Museum on detecting the transits of planets in front of other stars and, later, nighttime observing in and around the Observatory.

Visitors using a safe solar telescope outside the Museum in Washington, DC.

Check with your local observatory or astronomy club for a public transit viewing event near you (whether it is visible depends on your location in the world), or check the Solar Dynamics Observatory’s map. There are ways to observe the Sun safely at home if using proper equipment. You can use eclipse glasses to safely observe the Sun, though the dot of Venus against the unmagnified Sun is at the limit of the eye’s resolution. Finally, NASA is planning to stream the event live from the summit of Mauna Kea in Hawai’i, which is very likely to have good weather. The entire transit will be visible from that location.

On June 5, 2012, solar telescopes around the world and in space will point to the Sun, marking another beat in the centuries-long dance of the planets. Wherever you are in the world, whether your skies are clear or cloudy, it’s not an event to miss!

Geneviève de Messieres is an astronomy educator at the National Air and Space Museum.

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Why should you care about the Transit of Venus?

Transit of Venus on June 5th, 2012