The mass of the Sun, M☉, is 743 times the total mass of all the planets in the solar system and 330,000 times that of Earth. All the interesting planetary and interplanetary gravitational phenomena are negligible effects in comparison to the force exerted by the Sun. Under the force of gravity, the great mass of the Sun presses inward, and to keep the star from collapsing, the central pressure outward must be great enough to support its weight. The density at the Sun’s core is about 100 times that of water (roughly six times that at the centre of Earth), but the temperature is at least 15,000,000 K, so the central pressure is at least 10,000 times greater than that at the centre of Earth, which is 3,500 kilobars. The nuclei of atoms are completely stripped of their electrons, and at this high temperature they collide to produce the nuclear reactions that are responsible for generating the energy vital to life on Earth.
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While the temperature of the Sun drops from 15,000,000 K at the centre to 5,800 K at the photosphere, a surprising reversal occurs above that point; the temperature drops to a minimum of 4,000 K, then begins to rise in the chromosphere, a layer about 7,000 kilometres high at a temperature of 8,000 K. During a total eclipse the chromosphere appears as a pink ring. Above the chromosphere is a dim, extended halo called the corona, which has a temperature of 1,000,000 K and reaches far past the planets. Beyond a distance of 5R☉ from the Sun, the corona flows outward at a speed (near Earth) of 400 kilometres per second (km/s); this flow of charged particles is called the solar wind.
The Sun is a very stable source of energy; its radiative output, called the solar constant, is 1.366 kilowatts per square metre at Earth and varies by no more than 0.1 percent. Superposed on this stable star, however, is an interesting 11-year cycle of magnetic activity manifested by regions of transient strong magnetic fields called sunspots.The energy radiated by the Sun is produced during the conversion of hydrogen (H) atoms to helium (He). The Sun is at least 90 percent hydrogen by number of atoms, so the fuel is readily available. Since one hydrogen atom weighs 1.0078 atomic mass units and a single helium atom weighs 4.0026, the conversion of four hydrogen atoms to one helium atom yields 0.0294 mass unit, which are all converted to energy, 6.8 million electron volts (MeV, 1 MeV = 1.6 × 10−6 erg), in the form of gamma (γ) rays or the kinetic energy of the products. If all the hydrogen is converted, 0.7 percent of the mass becomes energy.The structure of a star is uniquely determined by its mass and chemical composition. Unique models are constructed by varying the assumed composition with the known mass until the observed radius, luminosity, and surface temperature are matched. The process also requires assumptions about the convective zone. Such models can now be tested by the new science known as helioseismology.
Helioseismology is analogous to geoseismology: frequencies and wavelengths of various waves at the Sun’s surface are measured to map the internal structure. On Earth the waves are observed only after earthquakes, while on the Sun they are continuously excited, probably by the currents in the convective zone. While a wide range of frequencies are observed, the intensity of the oscillation patterns, or modes, peaks strongly at a mode having a period of five minutes. The surface amplitudes range from a few centimetres per second to several metres per second. The modes where the entire Sun expands and contracts or where sound waves travel deeply through the Sun, only touching the surface in a few nodes (i.e., points of no vibration), make it possible to map the deep Sun. Modes with many nodes are, by contrast, limited to the outer regions. Every mode has a definite frequency determined by the structure of the Sun. From a compilation of thousands of mode frequencies, one can develop an independent solar model, which reproduces the observed oscillations quite well. The frequencies of the modes vary slightly with the sunspot cycle.