Friction between the desk and the floor acts as an unbalanced force to stop the desk from sliding. As the desk moves, the force of friction opposes the direction of its motion, eventually bringing it to a stop.
An unbalanced force acting on the chair could overcome the static friction between the chair and the floor, causing the chair to start moving. Once the force is stronger than the static friction, the chair will slide across the room due to the unbalanced force propelling it forward.
well it dipends because if its a balanced force there wouldn't be change in movement and if its unbalanced force there would be some types of change of movement. i hope this made you realize the answer
i wish i knew how
The force that slows you down as you slide across the floor is primarily kinetic friction. This force arises due to the interactions between the surfaces of the sliding object and the floor, leading to resistance that opposes the motion.
The force of friction acting on a crate sliding across the floor is equal in magnitude but opposite in direction to the force applied to move the crate. It depends on the coefficient of friction between the crate and the floor, as well as the weight of the crate.
An unbalance force is one that is not opposed by an equal and opposite force operating directly against the force. Examples of unbalanced force are when you kick a ball, or slide furniture across the floor.
An unbalanced force acting on the chair could overcome the static friction between the chair and the floor, causing the chair to start moving. Once the force is stronger than the static friction, the chair will slide across the room due to the unbalanced force propelling it forward.
well it dipends because if its a balanced force there wouldn't be change in movement and if its unbalanced force there would be some types of change of movement. i hope this made you realize the answer
i wish i knew how
The force that slows you down as you slide across the floor is primarily kinetic friction. This force arises due to the interactions between the surfaces of the sliding object and the floor, leading to resistance that opposes the motion.
The force of friction acting on a crate sliding across the floor is equal in magnitude but opposite in direction to the force applied to move the crate. It depends on the coefficient of friction between the crate and the floor, as well as the weight of the crate.
To calculate the force of the box being slid across the floor, the person needs to know the mass of the box and the acceleration of the box. Using the equation F = ma (force equals mass times acceleration), the person can determine the force required to slide the box across the floor.
This is an example of Newton's third law of motion, which states that for every action, there is an equal and opposite reaction. The baby exerts a force on the toy (action), and in response, the toy exerts an equal force back on the baby (reaction), causing the toy to move across the floor.
An example of sliding kinetic friction is pushing a box across the floor. As the box moves, there is friction between the box and the floor opposing its motion. This friction force must be overcome by applying a force in the direction of motion.
Friction
Unbalanced forces
friction