Mass creates a curvature in spacetime, as described by Einstein's theory of general relativity. This curvature is what causes objects with mass to be attracted to each other through the force of gravity.
The weight of a black hole doesn't tear spacetime because the black hole's mass warps spacetime only around its immediate vicinity, following the curvature of general relativity. This warping allows objects to enter and exit without spacetime tearing.
Light, though it travels in a straight line in a vacuum, must follow any curves in spacetime. Recall that the volume of the universe is called spacetime, and spacetime itself is distorted or "bent" by gravity. Light, though it travels in a straight line in a vacuum, will follow any gravity-induced curves in spacetime. An example might be the deformation of spacetime around a black hole, and the resultant gravitational lensing that can occur because of it.Light particles (photons) have no rest mass. They have an equivalent mass worked out using any of several equations or combinationsm = E/c2 or E=mc2and since E = fxhm = fh/c 2m = h/Lc or L=h/mc (de Broglie wavelength for light)where m is the mass, E is the energy of the photon, c is the speed of light in a vacuum, f is the frequency, h is Plank's constant (6.626 x 10-34 joules/sec) and L is the wavelength (usually greek lambda).Under relativity theory, it's not strictly required for photons to have mass in order to be affected by a gravitational field. Space itself is bent by gravity, and light takes the straightest possible path through bent spacetime.
No, not in the sense usually thought of when the word rip is used... there are no ragged edges. But it does produce an isolated area of spacetime from which nothing can return.
In fact, galaxies have an enormous mass.In fact, galaxies have an enormous mass.In fact, galaxies have an enormous mass.In fact, galaxies have an enormous mass.
An Einstein-Rosen bridge is a hypothetical shortcut through spacetime, also called a wormhole. A wormhole is like a sort of tunnel with two ends that reach separate points in spacetime.
Look at this websitewww.spacetimemodel.com It says that mass is really just a 4d volume of spacetime displacing and therefore warping the spacetime around it and so the answer is all mass displaces and so warps spacetime.
Mass curves spacetime due to the presence of mass and energy, as described by Einstein's theory of general relativity. This curvature of spacetime is what we perceive as gravity, causing objects with mass to be attracted to each other.
Mass warps spacetime due to the presence of gravity. According to Einstein's theory of general relativity, mass causes spacetime to curve, creating what we perceive as the force of gravity. This warping of spacetime is what causes objects to be attracted to each other.
Mass tells spacetime how to curve through its gravitational pull. According to Einstein's theory of general relativity, mass causes spacetime to bend or curve around it, creating the force of gravity. The more mass an object has, the stronger its gravitational pull and the greater the curvature of spacetime around it.
According to Einstein's theory of general relativity, gravity is the result of mass warping the fabric of spacetime. Objects with mass create a gravitational field around them that causes other objects to move along curved paths. In this way, gravity is a result of the geometry of spacetime being influenced by mass.
The concept of wormhole mass refers to the amount of mass needed to create and sustain a wormhole, a hypothetical tunnel-like structure in spacetime. In theoretical physics, understanding wormhole mass is important because it can help scientists explore the possibility of faster-than-light travel and study the fundamental principles of gravity and spacetime.
Time and space are interconnected according to the theory of relativity. Time can affect space by bending it, creating what we know as gravitational effects. The presence of mass or energy can bend and warp spacetime, influencing the motion of objects within it.
Large mass (in astronomical terms) bend and distort the fabric of spacetime.
Gravity is the fundamental force that is the result of warped spacetime, as described by Einstein's general theory of relativity. The presence of mass and energy warps the fabric of spacetime, causing objects to move in curved paths due to the force of gravity.
There is no such thing as gravitational force. Mass curves spacetime and stuff moves through spacetime in straight spacetime paths. The effect of this is what we call gravity. The more the mass the greater the curvature of spacetime.
No, they don't. They "curve" around massive objects, but this is a function of the photon following the "bend" in spacetime that objects with massive gravity create. Photons have a mass equal to zero.
Spacetime, as described by Einstein's theory of general relativity, influences the movement of matter through its curvature. The presence of mass and energy in spacetime causes it to curve, affecting the paths that objects follow. Matter moves along the curved spacetime paths, following the "shortest" route, known as a geodesic. This interaction between spacetime curvature and matter dictates the movement of objects in the universe.