Image:Helioseismology_pmode1.png '''Helioseismology''' is the study of the propagation of Pressure_waves in the Sun.Unlike seismic waves on earth, solar waves have practically no shear component (s-waves). Solar pressure waves are generated by the turbulence in the convection zone, near the surface of the sun, and certain frequencies are amplified by constructive interference. In other words, the turbulence "rings" the sun like a bell. The acoustic waves are transmitted to the outer photosphere of the sun, which is where the light emitted by the sun is generated. The acoustic oscillations are detectable on almost any time series of solar images, but are best observed by measuring the Doppler_shift of photospheric emission lines. Changes in the propagation of pressure waves through the Sun reveal inner structures and allows Astrophysicists to develop extremely detailed profiles of the interior conditions of the Sun. Helioseismology was able to rule out the possibility that the Solar_neutrino_problem was due to incorrect models of the interior of the Sun. Features revealed by helioseismology include that the outer convective zone and the inner radiative zone rotate at different speeds to generate the main magnetic field of the Sun, and that the convective zone has "Jet_streams" of plasma thousands of kilometers below the surface. These jet streams form broad fronts at the equator, breaking into smaller cyclonic storms at high latitudes. Helioseismology can also be used to detect Sunspots on the far side of the Sun from Earth. Keep in mind that despite the name, helioseismology is the study of solar pressure waves and not solar seismic activity - there is no such thing. The name is derived from the similar practice of studying terrestrial seismic waves to determine the composition of the Earth's interior. The science can be compared to Astroseismology, which considers the propagation of sound waves in extrasolar stars.
== Types of solar oscillations == Image:Helioseismology_GOLFpmode.png Solar oscillations are essentially divided up into three categories, based on the restoring force that drives them: acoustic, gravity, and surface-gravity wave modes. * '''p-mode''' or '''acoustic''' waves have pressure as their restoring force, hence the name "p-mode". Their dynamics are determined by the variation of the speed of sound inside the sun. p-mode oscillations have frequencies > 1 mHz and are very strong in the 2-4 mHz range, where they are often referred to as "5-minute oscillations". (Note: 5 minutes per cycle is 1/300 cycles per second = 3.33 mHz.) P-modes at the solar surface have amplitudes of hundreds of Kilometers and are readily detectable with Doppler imaging or sensitive Spectral_line Intensity imaging. * '''g-mode''' or '''gravity''' waves are density waves which have gravity (negative buoyancy of displaced material) as their restoring force, hence the name "g-mode". The g-mode oscillations are low frequency waves (0-0.4 mHz). They are confined to the interior of the sun below the convection zone (which extends from 0.7-1.0 solar radii), and are practically inobservable at the surface. The restoring force is caused by Adiabatic_expansion: in the deep interior of the Sun, the Temperature Gradient is weak, and a small packet of gas that moves (for example) upward will be cooler and denser than the surrounding gas, and will therefore be pulled back to its original position; this restoring force drives g-modes. In the solar convection zone, the temperature gradient is slightly greater than the Adiabatic_lapse_rate, so that there is an anti-restoring force (that drives Convection) and g-modes cannot propagate. The g-modes are evanescent through the entire convection zone, and are thought to have residual amplitudes of only Millimeters at the photosphere. As of 2006, no internal g-modes have been conclusively detected. * '''f-mode''' or '''surface gravity''' waves are also gravity waves, but occur at or near the photosphere, where the temperature gradient again drops below the adiabatic lapse rate. === Helioseismic verification of the age of meteorites === The radiometric age of Meteorites can be verified with studies of the sun. The sun can be dated using ''helioseismic'' methods which strongly agree with the radiometric dates found for the oldest meteorites. Bonanno 2006 ==References== * Bonanno, A., H. Schlattl and L. Paterno, (2006) ''The age of the sun and relativistic corrections in the EOS,'' Astronomy and Astrophysics http://arxiv.org/PS_cache/astro-ph/pdf/0204/0204331.pdf * Lecture Notes on Stellar Oscillations by Jørgen Christensen-Dalsgaard * Laurent Gizon and Aaron C. Birch, "Local Helioseismology", Living Rev. Solar Phys. 2 (2005) 6 online article * Scientists Issue Unprecedented Forecast of Next Sunspot Cycle National Science Foundation press release, March 6, 2006 == External links == ===Satellite instruments=== *GOLF *VIRGO *SOI/MDI *TRACE ===Ground instruments=== *BiSON *Mark-1 *GONG *HiDHN ==See also== * Asteroseismology * List_of_ologies * Magneto-gravity * Proton-proton_chain * Solar_neutrino_problem * Solar_tower Category:Seismology Category:Astrophysics Category:Sun Category:Stellar_phenomena De:Helioseismologie Es:Heliosismología Fr:Héliosismologie Is:Sólskjálftafræði It:Eliosismologia Uk:Геліосейсмологія