A = F/M = 50/10 = 5 meters per second2
The mass of the hockey puck cannot be determined from the information provided. Acceleration depends on the force applied and the mass of the object, but without knowing the force, we cannot calculate the mass.
When a hockey puck is frozen, it becomes harder and less elastic, which reduces its ability to compress upon impact. This lack of compression results in less energy being absorbed from the impact, causing the puck to bounce less.
The force that the puck exerts on the hockey stick depends on various factors, such as the speed of the puck, the angle at which it hits the stick, and the mass of the puck. This force can be calculated using the principles of classical mechanics and is typically measured in Newtons.
Newton's first law states that an object will remain at rest or in uniform motion unless acted upon by an external force. In hockey, a puck at rest will not move until a player applies force to it by hitting it with a stick. Additionally, a player will continue to move at a constant velocity unless checked by an opposing player or stops due to friction with the ice.
It becomes a lever. One hand serves as the fulcrum and the other applies the force.
It accelerates
F = ma. The math could not be more straightforward. You have F and you have a, so just solve for m.
It accelerates
Metres squared
The mass of the hockey puck cannot be determined from the information provided. Acceleration depends on the force applied and the mass of the object, but without knowing the force, we cannot calculate the mass.
your mom squared
If a net force of 5 N acts on a hockey puck, it will accelerate according to Newton's second law (F=ma), where F is the force, m is the mass of the puck, and a is the acceleration. The puck will move in the direction of the force, increasing its velocity over time as long as the force continues to act on it.
All the three Newtons laws of motion is applicable in the game of hockey. The ball stays where it is unless it is hit and given a force. The acceleration in the ball is proportional to the force given to it through the stick by the player. The ball when rebounds on the goal post is as per the third law of motion. As the stick, the ball and the post are rigid materials there is not much loss due to absorption.
When a hockey puck is frozen, it becomes harder and less elastic, which reduces its ability to compress upon impact. This lack of compression results in less energy being absorbed from the impact, causing the puck to bounce less.
Numbers are important.F = ma. So multiply the acceleration in meters per second (per second, which you appear to have left out) by the mass in kilograms and that will give you the force in newtons.
a puck
Hockey Just hockey Hockey on ice is called ice hockey