An artist's concept shows the TRAPPIST-1 planets as they might be seen from Earth using an extremely powerful – and fictional – telescope. NASA/JPL-Caltech
Our star, the Sun, on occasion
joins forces with the Moon to offer us Earthlings a spectacular solar eclipse –
like the one that will be visible to parts of the United States, Mexico, and
Canada on April 8.
But out there, among the other
stars, how often can we see similar eclipses? The answer depends on your point
of view. Literally.
On Earth, a total solar eclipse
occurs when the Moon blocks the Sun’s disk as seen from part of Earth’s
surface. In this case, the “path of totality” will be a strip cutting across
the country, from Texas to Maine.
We also can see “eclipses”
involving Mercury and Venus, the two planets in our solar system that orbit the
Sun more closely than Earth, as they pass between our telescopes and the Sun
(though only by using telescopes with protective filters to avoid eye damage).
In these rare events, the planets are tiny dots crossing the Sun’s much larger
disk.
A composite of images of the Venus transit taken by NASA’s Solar Dynamics Observatory on June 5, 2012. The image shows a timelapse of Venus’ path across the Sun. NASA/Goddard/SDO
And astronomers can, in a sense,
“see” eclipses among other systems of planets orbiting their parent stars. In
this case, the eclipse is a tiny drop in starlight as a planet, from our point
of view, crosses the face of its star. That crossing, called a transit, can
register on sensitive light sensors attached to telescopes on Earth and those
in space, such as NASA’s Hubble Space Telescope, James Webb Space Telescope, or
TESS (the Transiting Exoplanet Survey Satellite). It’s how the bulk of the more
than 5,500 confirmed exoplanets – planets around other stars – have been
detected so far, although other methods also are used to detect exoplanets.
“A solar eclipse is a huge
transit,” said Allison Youngblood, the deputy project scientist for TESS at
NASA’s Goddard Space Flight Center in Greenbelt, Maryland.
And both types of “transits” –
whether they involve solar eclipses or exoplanets – can yield world-changing
science. Solar eclipse observations in 1919 helped prove Einstein’s theory of
general relativity, when the bending of a star’s light by the Sun’s gravity
caused the star’s apparent position to shift – showing that gravity causes
space and time to curve around it.
Exoplanet transits also provide far
more than just detections of distant planets, Youngblood said.
“The planet passes in front of the
star, and blocks a certain amount of the star’s light,” she said. “The dip [in
starlight] tells us about the size of the planet. It gives us a measurement of
the radius of the planet.”
Careful measurements of multiple
transits also can reveal how long a year is on an exoplanet, and provide
insights into its formation and history. Careful measurements of multiple
transits also can provide insights into exoplanet formation and history.
And the starlight shining through
the exoplanet’s atmosphere during its transit, if measured using an instrument
called a spectrograph, can reveal deeper characteristics of the planet itself.
The light is split into a rainbow-like spectrum, and slices missing from the
spectrum can indicate gases in the planet’s atmosphere that absorbed that
“color” – or wavelength.
“Measuring the planet at many
wavelengths tells us what chemicals and what molecules are in that planet’s
atmosphere,” Youngblood said.
Eclipses are such a handy way to
capture information about distant worlds that scientists have learned how to
create their own. Instead of waiting for eclipses to occur in nature, they can
engineer them right inside their telescopes. Instruments called coronagraphs,
first used on Earth to study the Sun’s outer atmosphere (the corona), are now
carried aboard several space telescopes. And when NASA’s next flagship space
telescope, the Nancy Grace Roman Space Telescope, launches by May 2027, it will
demonstrate new coronagraph technologies that have never been flown in space
before. Coronagraphs use a system of masks and filters to block the light from
a central star, revealing the far fainter light of planets in orbit around it.
Of course, that isn’t quite as easy
as it sounds. Whether searching for transits, or for direct images of
exoplanets using a coronagraph, astronomers must contend with the overwhelming
light from stars – an immense technological challenge.
“An Earth-like transit in front of
stars is equivalent to a mosquito walking in front of a headlight,” said David
Ciardi, chief scientist at the NASA Exoplanet Science Institute at Caltech.
“That’s how little light is blocked.”
We don’t have this problem when
viewing solar eclipses – “our very first coronagraphs,” Ciardi says. By pure
happenstance, the Moon covers the Sun completely during an eclipse.
“A solar eclipse is like a human
walking in front of a headlight,” he said.
We would have no such luck on other
planets in our solar system.
Mars’ oddly shaped moons are too
small to fully block the Sun during their transits; and while eclipses might be
spectacular among the outer planets – for instance, Jupiter and its many moons
– they wouldn’t match the total coverage of a solar eclipse.
We happen to be living at a
fortunate time for eclipse viewing. Billions of years ago, the Moon was far
closer to Earth, and would have appeared to dwarf the Sun during an eclipse.
And in about 700 million years, the Moon will be so much farther away that it
will no longer be able to make total solar eclipses.
“A solar eclipse is the pinnacle of
being lucky,” Tripathi said. “The Moon’s size and distance allow it to
completely block out the Sun’s light. We’re at this perfect time and place in
the universe to be able to witness such a perfect phenomenon.”
Source: That Starry Night Sky? It’s Full of Eclipses (nasa.gov)
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