On the Nature of Nonthermal Radiation from Cosmological Γ-ray Bursters

Relativistic electron-positron winds with strong magnetic fields are considered as a source of radiation for cosmological γ-ray bursters. Such a wind is generated by a millisecond pulsar with a very strong magnetic field. An electronpositron plasma near the pulsar is optically thick and in quasi-thermodynamic equilibrium. It is shown that the main part of radiation from the pulsar wind is nonthermal and generates in the following way. Kinetic energy which is released in the process of deceleration of the neutron star rotation transforms mainly to the magnetic field energy. The magnetic field is frozen in the outflowing plasma if the distance to the pulsar is smaller than ∼ 10 cm. This field transfers the energy from the pulsar environment to the region outside the γ-ray photosphere of the electron-positron wind. At a distance of more than ∼ 10 cm the magnetohydrodynamic approximation for the pulsar wind is broken, and intense electromagnetic waves are generated. The frequency of these waves is equal to the frequency of the pulsar rotation. Outflowing particles are accelerated in the field of intense electromagnetic waves to Lorentz factors of the order of 10 and generate nonthermal synchro-Compton radiation. The typical energy of nonthermal photons is ∼ 1 MeV. A high-energy tail of the γ-ray spectrum may be up to ∼ 10 MeV. Baryonic matter is ejected occasionally from the pulsar magnetosphere. The baryonic matter ejection and subsequent suppression of the γ-ray emission may be responsible for the time structure of γ-ray bursts.