A = F/M = 50/10 = 5 meters per second2
Acceleration = Force/mass: 10N/50kg = 0.2 meters per second squared.
0.2 Kg or 200 grams
Because of the Law of the Conservation of Mass, the mass of a hockey puck that accerlerates at 100mph is the same as one that is still or going any other speed.
1, when it frozen it obserbe the impact so it reduces the bounce affect. It's Newtons 3rd Law.
Newton's first law is a object at rest will stay at rest unless acted on by a outside force so when you hit the puck with the stick the stick is the outside force and the puck moves
Hockey stick
Sliding friction is shown in hockey when you hit the puck. The puck has friction against the ice (but there isn't much).
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
It accelerates
Because of the Law of the Conservation of Mass, the mass of a hockey puck that accerlerates at 100mph is the same as one that is still or going any other speed.
Metres squared
1, when it frozen it obserbe the impact so it reduces the bounce affect. It's Newtons 3rd Law.
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.
your mom squared
Newton's first law is a object at rest will stay at rest unless acted on by a outside force so when you hit the puck with the stick the stick is the outside force and the puck moves
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