Stellar oscillations are primarily caused by convection, which is the process of heat transfer through the movement of heated material. In stars, convection occurs in the outer layers where the temperature gradient is steep.

Non-radial oscillations involve changes in the star's shape, leading to variations in its luminosity. These oscillations are often observed in massive stars and can provide insights into the star's internal structure and rotation.

Studying stellar oscillations allows astronomers to determine the star's mass and radius, measure its rotation rate, and detect the presence of exoplanets orbiting the star.

Radial oscillations involve the expansion and contraction of the entire star, resulting in variations in its radius and luminosity. These oscillations are commonly observed in pulsating stars, such as Cepheid variables.

The frequency of stellar oscillations depends on both the star's mass and radius. More massive stars tend to have higher oscillation frequencies, while larger stars have lower oscillation frequencies.

Tidal oscillations are caused by the gravitational interaction between the star and its orbiting planets. These oscillations can provide information about the planet's mass and orbital parameters.

Viscosity is the primary mechanism responsible for damping stellar oscillations. It is the resistance to the flow of material within the star, which causes the oscillations to gradually lose energy and amplitude.

Mixed oscillations involve a combination of radial and non-radial oscillations, resulting in variations in both the star's radius and surface temperature. These oscillations are often observed in evolved stars and can provide insights into the star's internal structure and evolution.

Studying stellar oscillations can help determine the star's age by analyzing the oscillation frequencies and comparing them to theoretical models of stellar evolution.

Non-radial oscillations can be influenced by the star's rotation, leading to the formation of rotational modes. These modes can provide information about the star's internal rotation profile and its differential rotation.

The amplitude of stellar oscillations depends on both the star's luminosity and mass. More luminous stars tend to have higher oscillation amplitudes, while more massive stars have lower oscillation amplitudes.

Magnetic oscillations are caused by the interaction between the star's magnetic field and its plasma. These oscillations can provide information about the star's magnetic field strength and structure.

Studying stellar oscillations can help detect exoplanets directly, measure their masses, and determine their orbital parameters by analyzing the variations in the star's oscillations caused by the gravitational influence of the exoplanets.

Magnetic oscillations are associated with the star's magnetic activity and can provide information about the star's magnetic field strength and structure.

The period of stellar oscillations depends on both the star's mass and radius. More massive stars tend to have shorter oscillation periods, while larger stars have longer oscillation periods.