I do believe that it is either kinetic or potential energy.
From jellyfish
A mass is hanging from a spring experiences the force of gravity.
The spring.
A mass is hanging from a spring experiences the force of gravity.
Gravity, Friction and Mass
Yes true
An unbalanced group of forces on an object causes the object to accelerate.Its acceleration is (the vector sum of all the forces)/(the object's mass) .
Unbalanced forces are also known as "net forces" and are expressed as a vector of the total forces acting on the object. This will be directly proportional to the acceleration of the object (the other factor being mass).
A mass is hanging from a spring experiences the force of gravity.
Gravity, Friction and Mass
Yes true
There is the apple's weight (mass * gravity) but there is also the air resistance acting against the object's weight.
An unbalanced group of forces on an object causes the object to accelerate.Its acceleration is (the vector sum of all the forces)/(the object's mass) .
The combined force (net force) are the two forces added together.
Unbalanced forces are also known as "net forces" and are expressed as a vector of the total forces acting on the object. This will be directly proportional to the acceleration of the object (the other factor being mass).
yes, since the forces are acting on just one body, the mass (m) in the equation F=ma is not changing, which would mean that the two accelerations (a) would have to be different. If the two accelerations are different then there is total acceleration in one direction (the resultant acceleration).
gravitational force, which is always attractive (unlike the other three forces)
see me as earth
3 cm for every 1 pound 15 cm for 5 pounds
The motion of a mass is the result of all the forces acting on it, and how their strengths and directions combine. If gravity is one of the forces, then it just participates in the group, exactly like any of the other forces does. Its effect on the motion of the mass is the same as the effect of any other force that has the same strength and direction as the gravitational force.