60 kg m/s
An object stays at rest unless a force acts on it.
Yes. If it is at rest to start with, it will remain at rest until an external force acts on it. Likewise, an object starting in motion will remain in that same motion until an external force acts on it.
If there is no net force, the object will stay at rest if it was at rest, or continue moving - at constant velocity - if it was already moving.
Newton's law of inertia: An object at rest remains at rest unless an unbalanced force acts upon it.
A force. This leads to the equation; force = mass x acceleration Unbalanced(:
An object stays at rest unless a force acts on it.
Yes. If it is at rest to start with, it will remain at rest until an external force acts on it. Likewise, an object starting in motion will remain in that same motion until an external force acts on it.
Nothing changes. When no force acts on an object moving with constant velocity, the body continues its motion with uniform velocity, or if the object is at rest, it will remain at rest.
Yes, that is correct.
The object must be in equilibrium to be at rest or a constant speed.
An object at rest will remain at rest unless acted on by an unbalanced force. This is part of Newton's third law of motion.
If there is no net force, the object will stay at rest if it was at rest, or continue moving - at constant velocity - if it was already moving.
An object at rest will stay at rest unless an external resultant force acts on it.Also an object will continue to move at constant velocity unless an external resultant force acts on it.Newton's first Law of Motion states that an object will remain at rest unless an unbalanced force acts upon it. An object that is moving will remain at constant speed in the same direction forever unless an unbalanced force acts upon it.
gravity and normal force (assuming presence of a gravitational field)
Newton's law of inertia: An object at rest remains at rest unless an unbalanced force acts upon it.
Yes, it is true.
A force. This leads to the equation; force = mass x acceleration Unbalanced(: