The concept of mass in general relativity (GR) is more complex than the concept of mass in special relativity. In fact, general relativity does not offer a single definition for the term mass, but offers several different definitions which are applicable under different circumstances. Under some circumstances, the mass of a system in general relativity may not even be defined.
Generalizing this definition to general relativity, however, is problematic; in fact, it turns out to be impossible to find a general definition for a system's total mass (or energy). The main reason for this is that "gravitational field energy" is not a part of the energy–momentum tensor; instead, what might be identified as the contribution of the gravitational field to a total energy is part of the Einstein tensor on the other side of Einstein's equation (and, as such, a consequence of these equations' non-linearity). While in certain situation it is possible to rewrite the equations so that part of the "gravitational energy" now stands alongside the other source terms in the form of the stress–energy–momentum pseudotensor, this separation is not true for all observers, and there is no general definition for obtaining it
The source of gravity in GR is the stress energy tensor. For ordinary gravitating objects, like planets and stars, the dominant term in the stress energy tensor is energy density, and the dominant portion of energy density is mass.Dr Cadaver said:In some videos and books, they state that it is the mass of an object that generates gravity. However, others say that it's not so much as mass, but the density of energy/mass in a given volume of space.
And the dominant portion of mass in ordinary objects comes from energy density in hadrons not associated to elementary particle masses.DaleSpam said:The source of gravity in GR is the stress energy tensor. For ordinary gravitating objects, like planets and stars, the dominant term in the stress energy tensor is energy density, and the dominant portion of energy density is mass.
The origin of gravity is a fundamental question in physics that is still being studied and debated. It is currently believed that gravity is a force that results from the curvature of space and time caused by the presence of mass and energy.
The answer to this question is that gravity is caused by both mass and energy density. Mass is the amount of matter in an object, while energy density is the amount of energy per unit volume. Both of these contribute to the curvature of spacetime and therefore the force of gravity.
The amount of mass or energy in an object directly affects the strength of its gravitational pull. The more mass or energy an object has, the stronger its gravitational force will be. This is why larger and more massive objects like planets have a stronger gravitational pull than smaller objects like rocks.
No, gravity cannot be created or destroyed. It is a fundamental force of nature that exists everywhere in the universe. However, its strength can be weakened or strengthened depending on the amount of mass and energy present in a given area.
Einstein's theory of general relativity explains the origin of gravity by describing it as the result of the curvature of spacetime caused by the presence of mass and energy. This theory has been extensively tested and is currently the most widely accepted explanation for the origin of gravity.