Yes, a force can set a motionless object in motion by overcoming the object's inertia. Once the force applied exceeds the object's resistance to motion, it will start to move.
The opposite of motionless is moving or in motion.
No, "motionless" is an adjective that describes something as not moving or without motion.
The word "motionless" is an adjective. It describes something that is not moving or lacking in motion.
Yes, a force is needed to set an object into motion according to Newton's first law of motion. An object at rest will remain at rest unless acted upon by a force.
Yes, a force can set a motionless object in motion by overcoming the object's inertia. Once the force applied exceeds the object's resistance to motion, it will start to move.
NO
The opposite of motionless is moving or in motion.
No, "motionless" is an adjective that describes something as not moving or without motion.
"Motionless" means it doesn't move. If an object moves, it can be said to be in motion; if it doesn't move, it is motionless.
The word "motionless" is an adjective. It describes something that is not moving or lacking in motion.
Yes, a force is needed to set an object into motion according to Newton's first law of motion. An object at rest will remain at rest unless acted upon by a force.
Without motion; being at rest.
The three factors that set convection currents in motion are: the heating and cooling of fluid, change in its density, and the force of gravity combine to set it in motion.
Use the force young pad-wan! An external force is required to start an object in motion from rest.
You are using your muscles to apply an upward force to the book equal to its weight. That force is equal in magnitude to the downward force on the book due to the gravitational attraction of the earth, and opposite in direction. Since equal and opposite forces are applied to the book, the net force on it is zero, and its acceleration is zero ===> if it began motionless, it remains motionless.
The net force on the motionless weight is zero since it is in equilibrium. The gravitational force pulling it downward is balanced by the tension force in the string pulling it upward.