Gravity is pushing the rock down toward the Earth and your hand is pushing upward in opposite direction but equal to gravity.
The three types of forces that cause folding in rocks are compressional forces (pushing together), shear forces (side-by-side movement in opposite directions), and tensional forces (pulling apart). These forces can act on rocks over long periods of time, leading to the deformation and folding of the rock layers.
Two - forces act in pairs. If object "A" acts on object "B", the object "B" will also act on object "A". In many practical situations, there may be additional forces involved. For example, if an object is at rest despite the fact that a force acts on it, then it is obvious that an additional force acts on the same object, and in the opposite direction. In such cases, there are at least four forces involved, since according to Newton's Third Law, there must be an opposite force for each of these two forces. (Note that in Newton's Third Law, the two forces act on DIFFERENT objects, so the two forces that hold an object in balance do not quality as a pair of forces according to Newton's Third Law.)
The primary forces that act on rocks in Earth's crust are compression and tension. Compression occurs when rocks are squeezed together, often leading to folding and faulting. Tension is when rocks are pulled apart, creating fractures and rifts. These forces are generated by tectonic plate movements and can result in various geological features.
The two forces are of the same magnitude, act in opposite directions, and act on different objects.
London dispersion forces
The forces that act on the rock
A body can stay at rest even though forces act on it when the forces acting on the body are balanced, meaning they cancel each other out. This balance of forces results in no net force acting on the body, allowing it to remain at rest.
If no unbalanced forces act on an object at rest, it will remain at rest due to Newton's first law of motion, which states that an object will stay at rest or in motion with a constant velocity unless acted upon by an unbalanced force.
Balanced forces cannot bring a body to rest. Balanced forces can act on a body which is already at rest or in motion but equal forces cannot change a bodies acceleration, kinetic energy or momentum.
Intertia is the tendency of an object to maintain its velocity: if an object is at rest, it has the tendency to remain at rest; if it is moving, the tendency is to keep moving with the same velocity. That is what happens if no forces act on the object; if forces act on the object, including gravitation, friction, and others, its velocity will change.
An object at rest will remain at rest if no unbalanced forces act on it, according to Newton's first law of motion. This is known as the law of inertia, which states that an object will maintain its state of rest or uniform motion unless acted upon by a net external force.
When an object is subjected to balanced forces, it will continue to maintain its state in motion or at rest. By balanced forces we mean forces that are equal in magnitude but opposite in direction so they cancel each other out. Understanding the concept of speed, velocity, displacement, vector diagram is very important to able to figure out the effect of balance/unbalanced forces on an object.
If no forces are applied to the rock, it would remain in a state of rest, potentially being subject to other natural forces like wind or erosion. Over time, it may undergo changes due to weathering and geological processes, but it would generally stay in place as long as no external forces act upon it.
gravity and normal force (assuming presence of a gravitational field)
it means like...... take a pen and put it in your hand you might not feel this but your hand is pushing against the pen if you keep the pen in the same place the forces are balanced but if you raise the pen the forces are unbalanced
In physics, tangential forces act parallel to the surface of an object, causing it to rotate. Radial forces, on the other hand, act perpendicular to the surface, causing the object to move in a circular path.
No, balanced forces do not change an object's motion. When balanced forces act on an object, the object will either remain at rest or continue moving at a constant velocity.