(Redirected from 21 cm line)
The 'hydrogen line' refers to the spectral line created by changes in the energy state of neutral
hydrogen and occurs at 1420.40575
MHz, or a wavelength of around 21
cm. Also known as '21
centimetre radiation', the line is used extensively in astronomy, particularly
radio astronomy, as the line falls well within the radio spectrum.
Cause of the hydrogen line
Neutral
hydrogen consists of a single
proton orbited by a single
electron. As well as their orbital motion, the
proton and
electron also have
spin. Classically, this is analogous to rotational motion (like the
Earth rotating as it orbits the
Sun), but as they are
quantum particles the concept has a slightly different meaning. The spin of the
electron and
proton can be in either direction - in the classical analogy they are rotating clockwise or anticlockwise around a given axis. They may both have their spin oriented in the same direction or in opposite directions. Because of
magnetic interactions between the particles, a
hydrogen atom that has the spins of the
electron and
proton aligned in the same direction (parallel) has slightly more energy than one where the spins of the
electron and
proton are in opposite directions (anti-parallel). The lowest orbital energy state of atomic hydrogen has
hyperfine splitting arising from the
spins of the
proton and
electron changing from a
parallel to antiparallel configuration. This transition is highly
forbidden with an extremely small probability of 2.9×10
−15 s
−1. This means that the time for a single isolated atom of neutral hydrogen to undergo this transition is around 10 million (10
7) years and so is unlikely to be seen in a laboratory on Earth. However, as the total number of atoms of neutral hydrogen in the
interstellar medium is very large, this emission line is easily observed by
radio telescopes. Also, the lifetime can be considerably shortened by collisions with other hydrogen atoms and interaction with the
cosmic microwave background.
The line has an extremely small natural width because of its long lifetime, so most broadening is due to
doppler shifts caused by the motion of the emitting regions relative to the observer.
Discovery
During the 1930s, it was noticed that there was a radio 'hiss' that varied on a daily cycle and appeared to be extraterrestrial in origin. After initial suggestions that this was due to the
Sun, it was observed that the radio waves seemed to be coming from the centre of
the Galaxy. These discoveries were published in 1940 and were seen by Professor
J.H. Oort who knew that significant advances could be made in astronomy if there were
emission lines in the radio part of the spectrum. He referred this to
Dr Hendrik van de Hulst who, in 1944, discovered that
neutral hydrogen could produce radiation at a
frequency of 1420.4058 MHz due to two closely spaced energy levels in the
ground state of the
hydrogen atom.
The 21cm line (1420.4 MHz) was first detected in 1951 by
Ewen and
Purcell at
Harvard University. This discovery was quickly confirmed by Muller and Oort in the Netherlands, and by Christiansen and Hindman in Australia. After 1952 the first maps of the neutral hydrogen in the Galaxy were made and revealed, for the first time, the spiral structure of the
Milky Way.
Uses in radio astronomy
Luckily, the spectral line appears within the
radio spectrum (in the
microwave window to be exact). Electromagnetic energy in this range can easily pass through the Earth's atmosphere and be observed from the Earth with little interference.
Assuming that the hydrogen atoms are uniformly distributed throughout the galaxy, each line of sight through the galaxy will reveal a hydrogen line. The only difference between each of these lines is the
doppler shift that each of these lines has. Hence, one can calculate the relative speed of each arm of our
galaxy. The
rotation curve of our
galaxy has also been calculated using the 21-cm hydrogen line. It is then possible to use the plot of the
rotation curve and the
velocity to determine the distance to a certain point within the galaxy.
Hydrogen line observations have also been used indirectly to calculate the mass of galaxies, to put limits on any changes over time of the universal
gravitational constant and to study dynamics of individual galaxies.
Uses in cosmology
The line is of great interest in
big bang cosmology because it is the only known way to probe the "dark ages" from
recombination to
reionization. Including the
redshift, this line will be observed at frequencies from 200
MHz to about 9 MHz on Earth. It potentially has two applications. First, by mapping redshifted 21 centimeter radiation it can, in principle, provide a very precise picture of the
matter power spectrum in the period after recombination. Second, it can provide a picture of how the universe was reionized, as neutral hydrogen which has been ionized by radiation from stars or quasars will appear as holes in the 21 centimeter background.
However, 21 centimeter experiments are very difficult. Ground based experiments to observe the faint signal are plagued by interference from television transmitters and the
ionosphere, so they must be very secluded and careful about eliminating interference if they are to succeed. Space based experiments, even on the far side of the moon (which should not receive interference from terrestrial radio signals), have been proposed to compensate for this. Little is known about other effects, such as
synchrotron emission and free-free emission on the galaxy. Despite these problems, 21 centimeter observations, along with space-based gravity wave observations, are generally viewed as the next great frontier in observational cosmology, after the cosmic microwave background polarization.
Other uses
The
Pioneer plaque, attached to the
Pioneer 10 and
Pioneer 11 spacecraft, portrays the hyperfine transition of neutral hydrogen and used the wavelength as a standard scale of measurement. For example the height of the man and woman in the image are displayed as having a height eight times 21 cm, or 168 cm. Similarly the frequency of the hydrogen spin-flip transition was used for a unit of time. The position of the Sun is portrayed relative to 14
pulsars, with the rotation period of these objects being listed as a multiple of this frequency. It is theorized by the plaque's creators that an advanced civilization would then be able to use the locations of these pulsars to locate the
Solar System at the time the spacecraft were launched.
The 21 cm Hydrogen line is considered a favorable frequency to search for signals from another civilization, as part of the
SETI program. The original paper by Giuseppe Cocconi and Philip Morrison proposed just such a search in their paper, ''Search for Extra-Terrestrial Intelligence''.
[1]
References
Cosmology
★ P. Madau, A. Meiksin and M. J. Rees, "21-cm Tomography of the Intergalactic Medium at High Redshift", ''Astrophysical Journal'' '475', 429 (1997) .
★ B. Ciardi, P. Madau, "Probing Beyond the Epoch of Hydrogen Reionization with 21 Centimeter Radiation", ''Astrophysical Journal'' '596', 1 (2003) .
★ M. Zaldarriaga, S. Furlanetto and L. Hernquist, "21 Centimeter Fluctuations from Cosmic Gas at High Redshifts", ''Astrophysical Journal'' '608', (2004) 608 .
★ X. Chen and J. Miralda-Escudé, "Observing the Reionization Epoch Through 21 Centimeter Radiation", ''Mon. Not. Roy. Astron. Soc.'' '347', 187 (2004) .
★ A. Loeb and M. Zaldarriaga, "Measuring the Small-Scale Power Spectrum of Cosmic Density Fluctuations Through 21 cm Tomography Prior to the Epoch of Structure Formation", ''Phys. Rev. Lett.'' '92', 211301 (2004) .
★ M. G. Santos, A. Cooray and L. Knox, "Multifrequency analysis of 21 cm fluctuations from the Era of Reionization", ''Astrophysical Journal'' '625', 575 (2005) .
★ R. Barkana and A. Loeb, "Detecting the Earliest Galaxies Through Two New Sources of 21cm Fluctuations", ''Astrophysical Journal'' '626', 1 (2005) .
External Links
★
The story of Ewen and Purcell's discovery of the 21 cm line
★
Ewen and Purcell's original paper in Nature
★ PAST experiment, .
★
LOFAR experiment
★
Mileura Widefield Array experiment
★
Square Kilometer Array experiment
See also
★
Hydrogen
★
Radio astronomy
★
Rydberg formula
★
Spectral line
العربية
中国
Français
Deutsch
Ελληνική
हिन्दी
Italiano
日本語
Português
Русский
Español
