Photon emission Photons given off by a body in thermal equilibrium have a
black-body spectrum with an energy density proportional to the fourth power of the temperature, as described by the
Stefan–Boltzmann law.
Wien's law states that the wavelength of maximum emission from a black body is inversely proportional to its temperature. Equivalently, the frequency, and the energy, of the peak emission is directly proportional to the temperature.
Photon pressure in stars In very massive, hot stars with interior temperatures above about (), photons produced in the
stellar core are primarily in the form of very high-energy
gamma rays. The pressure from these gamma rays fleeing outward from the core helps to hold up the upper layers of the star against the inward pull of
gravity. If the
emission of gamma rays (the
energy density) is reduced, then the outer layers of the star will begin to collapse inwards. Gamma rays with sufficiently high energy can interact with nuclei, electrons, or one another. One possible interaction is to form pairs of particles, such as
electron-positron pairs, these pairs can then meet and
annihilate each other to create additional gamma rays, in accordance with
Albert Einstein's
mass-energy equivalence equation At the very high density of a large stellar core, pair production and annihilation occur rapidly. Gamma rays, electrons, and positrons are overall held in
thermal equilibrium, ensuring the star's core remains stable. By random fluctuation, the sudden heating and compression of the core can generate gamma rays energetic enough to be converted into an avalanche of electron-positron pairs. This reduces the pressure. When the collapse stops, the positrons find electrons and the pressure from gamma rays is driven up, again. The population of positrons provides a brief reservoir of new gamma rays as the expanding supernova's core pressure drops.
Pair-instability As temperatures and gamma ray energies increase, more and more gamma ray energy is absorbed in creating electron–positron pairs. This reduction in gamma ray energy density reduces the radiation pressure that resists gravitational collapse and supports the outer layers of the star. The star contracts, compressing and heating the core, thereby increasing the rate of energy production. This increases the energy of the gamma rays that are produced, making them more likely to interact, and so increases the rate at which energy is absorbed in further pair production. As a result, the stellar core loses its support in a runaway process, in which gamma rays are created at an increasing rate; but more and more of the gamma rays are absorbed to produce electron–positron pairs, and the
annihilation of the electron–positron pairs is insufficient to halt further contraction of the core. Finally, the
thermal runaway ignites detonation fusion of oxygen and heavier elements. When the temperature reaches the level when electrons and positrons carry the same energy fraction as gamma-rays, pair production cannot increase any further; it is balanced by annihilation. Contraction no longer accelerates, but the core now produces much more energy than prior to collapse, and this results in a supernova: the outer layers of the star are blown away by sudden large increase of power production in the core. Calculations suggest that so much of the outer layers are lost that the very hot core itself is no longer under sufficient pressure to keep it intact, and it is completely disrupted too. ==Stellar susceptibility==