Basketball
This is an example of inertia, specifically the difference in inertia between the two objects due to their mass. The bowling ball has more mass, so it has more inertia and requires more force to stop its motion compared to the ping pong ball.
Most likely the bowling ball. According to the laws of physics, an object with more inertia accelerates slower but is harder to stop. The bowling ball accelerates slowly but has a high mass. The beach ball accelerates quickly but has a low mass. So the bowling ball has more inertia.
Inertia is the resistance of an object to change its state of motion. A bowling ball has more mass compared to a softball, so it has greater inertia. This means it would be more difficult to accelerate, decelerate, or change its direction when playing softball, making it harder to control compared to a lighter and less massive softball.
Any amount of force can stop either kind of ball. But a greater force is required to stop a bowling ball than to stop a soccer ball IN THE SAME TIME, because the bowling ball has more mass, and therefore more momentum and more kinetic energy.
The basketball has more inertia because it has more mass than a penny. Inertia is directly related to an object's mass - the larger the mass, the greater the inertia.
No, the inertia of a bowling ball is greater than the inertia of a basketball due to the bowling ball's larger mass. Inertia is the resistance of an object to changes in its state of motion, and a heavier object like the bowling ball requires more force to accelerate or decelerate compared to the basketball.
Since the lightest tenpin bowling ball is currently 6 pounds and a table tennis ball is not even an ounce, the tenpin bowling ball is heavier.
A basketball is lighter than a bowling ball.
Most likely the bowling ball. According to the laws of physics, an object with more inertia accelerates slower but is harder to stop. The bowling ball accelerates ...
a bowling ball
Inertia is the property of an object to resist changes in its state of motion, and it depends on the object's mass rather than its speed. Therefore, if the fast bowling ball and the slow bowling ball have the same mass, they have the same inertia regardless of their speeds. However, the fast bowling ball may have more momentum due to its higher velocity, but inertia itself is solely a function of mass.
This is an example of inertia, specifically the difference in inertia between the two objects due to their mass. The bowling ball has more mass, so it has more inertia and requires more force to stop its motion compared to the ping pong ball.
Most likely the bowling ball. According to the laws of physics, an object with more inertia accelerates slower but is harder to stop. The bowling ball accelerates slowly but has a high mass. The beach ball accelerates quickly but has a low mass. So the bowling ball has more inertia.
Among a bowling ball, a planet, a car, and a train, the planet has the greatest inertia. Inertia depends on an object's mass, and planets have significantly more mass than the other items listed, meaning they resist changes to their motion more than the others do. While a bowling ball is heavy, it pales in comparison to the mass of a planet.
I think the golf ball has more inertia than ping pong ball, becuase of its weight. It is much heavy which result that it could stay at rest more, than a very lightweight ping pong ball.
No, a bowling ball (or any other object) has exactly the same inertial mass no matter where it is (its actual inertia will, of course, depend upon its velocity as well as its inertial mass). Weight changes on the moon, but inertia doesn't.
Inertia is the resistance of motion of an object. The more inertia, the harder it is to move something. The less inertia, the easier it is to move. Take a bowling ball and a marble. The marble can be flicked by the finger, because it has less inertia. The bowling ball takes the entire hand because it has more inertia than the marble. According to Newton's laws, an object that is moving tends to continue in motion. A moving object has inertia as it has Mass and Velocity. An object that is not moving requires a Force exerted on the Mass to start it moving.