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Doppler spectroscopy - Wikipedia, the free encyclopedia

Doppler spectroscopy

From Wikipedia, the free encyclopedia

Diagram showing how a smaller object (such as an extrasolar planet) orbiting a larger object (such as a star) could produce changes in position and velocity of the latter as they orbit their common center of mass (red cross).
Diagram showing how a smaller object (such as an extrasolar planet) orbiting a larger object (such as a star) could produce changes in position and velocity of the latter as they orbit their common center of mass (red cross).

Doppler spectroscopy, also known as radial velocity measurement, is a spectroscopic method for finding extrasolar planets. It involves the observation of Doppler shifts in the spectrum of the star around which the planet orbits.

It is extremely difficult to observe extrasolar planets directly because they are very faint at interstellar distances, although the first claims of direct observations were made in 2004 and 2005. As a result, planets outside of our solar system are usually discovered using indirect methods, through the effect of the planet on an object that is easier to observe, such as the parent star. Successful methods include Doppler spectroscopy, astrometry, pulsar timing, transits, and Gravitational microlensing. Almost all of the known extrasolar planets have been discovered using Doppler spectroscopy.

Contents

[edit] History

Otto Struve proposed in 1952 the use of powerful spectrographs to detect distant planets. He described how a very large planet, as large as Jupiter, for example, would cause its parent star to wobble slightly as the two objects orbit around their center of mass.[1] He predicted that the small Doppler shifts to the light emitted by the star, caused by its continuously varying radial velocity, would be detectable by the most sensitive spectrographs as tiny red shifts and blue shifts in the star's emission. However, the technology of the time produced radial velocity measurements with errors of 1,000 m/s or more, making them useless for the detection of orbiting planets.[2] The expected changes in radial velocity are very small – Jupiter causes the Sun to change velocity by about 13 m/s over a period of 12 years, and the Earth's effect is only 0.1 m/s over a period of 1 year – so long-term observations by instruments with a very high resolution are required.[2][3]

Advances in spectrometer technology and observational techniques in the 1980s and 1990s produced instruments capable of detecting the first of many new extrasolar planets. 51 Pegasi b, the first extrasolar planet to be detected, was discovered in October 1995 using Doppler spectroscopy.[4] Since that date, nearly 300 exoplanet candidates have been identified, and most have been detected by Doppler search programs based at the Keck, Lick, and Anglo-Australian Observatories (respectively, the California, Carnegie and Anglo-Australian planet searches), and teams based at the Geneva Extrasolar Planet Search.[4]

[edit] Procedure

A series of observations is made of the spectrum of light emitted by a star. Periodic variations in the star's spectrum may be detected, with the wavelength of characteristic spectral lines in the spectrum increasing and decreasing regularly over a period of time. These variations may be indicative of the radial velocity of the star being altered by the presence of planet orbiting the star, causing Doppler shifts in the light emitted by the star.

If an extrasolar planet is detected, its mass can be determined from the changes in the star's radial velocity. A graph of measured radial velocity versus time will give a characteristic curve (sine curve in the case of a circular orbit), and the amplitude of the curve will allow the planet's mass to be calculated.

[edit] Example

The graph to the right illustrates the sine curve created using Doppler spectroscopy to observe the radial velocity of an imaginary star which is being orbited by a planet in a circular orbit. Observations of a real star would produce a similar graph, although eccentricity in the orbit will distort the curve and complicate the calculations below.

This theoretical star's velocity shows a periodic variance of ±1 m/s, suggesting an orbiting mass that is creating a gravitational pull on this star. Using Kepler's third law of planetary motion, the observed period of the planet's orbit around the star (equal to the period of the observed variations in the star's spectrum) can be used to determine the planet's distance from the star (r) using the following equation:

r^3=\frac{GM_{star}}{4\pi^2}P_{star}^2\,

where:

  • r is the distance of the planet from the star
  • G is the gravitational constant
  • Mstar is the mass of the star
  • Pstar is the observed period of the star

Having determined r, the velocity of the planet around the star can be calculated using Newton's law of gravitation, and the orbit equation:

V_{PL}=\sqrt{GM_{star}/r}\,

where VPL is the velocity of planet.

The mass of the planet can then be found from the calculated velocity of the planet:

M_{PL}=\frac{M_{star}V_{star}}{V_{PL}}\,

where Vstar is the observed velocity of parent star. The observed Doppler velocity, K = Vstarsin(i), where i is the inclination of the planet's orbit to the line perpendicular to the line of sight.

Thus, assuming a value for the inclination of the planet's orbit and for the mass of the star, the observed changes in the radial velocity of the star can be used to calculate the mass of the extrasolar planet.

[edit] Problems

The major problem with Doppler spectroscopy is that it can only measure movement along the line of sight, and so depends on a measurement (or estimate) of the inclination of the planet's orbit to determine the planet's mass. If the orbital plane of the planet happens to line up with the line of sight of the observer, then the measured variation in the star's radial velocity is the true value. However, if the orbital plane is tilted away from the line of sight, then the true effect of the planet on the motion of the star will be greater than the measured variation in the star's radial velocity, which is only the component along the line of sight. As a result, the planet's true mass will be higher than expected.

To correct for this effect, and so determine the true mass of an extrasolar planet, radial velocity measurements must be combined with astrometric observations, which track the movement of the star across the plane of the sky, perpendicular to the line of sight. Astrometric measurements allows researchers to check whether objects that appear to be high mass planets are more likely to be brown dwarfs.[2]

A further problem is that the gas envelope around certain types of stars can expand and contract, and some stars are variable. This method is unsuitable for finding planets around these types of stars, as changes in the stellar emission spectrum caused by the intrinsic variability of the star can swamp the small effect caused by a planet.

The method is best at detecting very massive objects close to the parent star - so-called "hot Jupiters" - which have the greatest gravitational effect on the parent star, and so caused the largest changes in its radial velocity. Observation of many separate spectral lines and many orbital periods allows the signal to noise ratio of observations to be increased, increasing the chance of observing smaller and more distant planets, but planets like the Earth remain undetectable with current instruments.

[edit] Footnotes

  1. ^ Otto Struve, "Proposal for a project of high-precision stellar radial velocity work" The Observatory 72 (1952): 199-200.
  2. ^ a b c David Darling, "radial velocity method" The Encyclopedia of Astrobiology, Astronomy, and Space Flight, April 27, 2007.
  3. ^ "Doppler spectroscopy and astrometry - Theory and practice of planetary orbit measurements", Astronomy 497: Astronomy of Extrasolar Planets, Alex Wolszczan, Department of Astronomy and Astrophysics, Penn State University, Spring 2006. (PDF)
  4. ^ a b R. P. Butler, et al. "Catalog of Nearby Exoplanets" Astrophysical Journal. Vol. 646 (2006):2-3, 25-33. (PDF)

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