Well according to the equation Force = Mass x Acceleration. A bowling ball has more mass than a feather but it all depends on how much acceleration each is undergoing. Potentially a feather can have more force (if the bowling ball has an acceleration of zero, then there is no force being produced, and if the feather is accelerating at any speed greater than zero, thentechnicallyit has more force)
a bowling ball
The bowling ball has more momentum because momentum is directly proportional to an object's mass and velocity. Since the two balls are moving at the same speed, the greater mass of the bowling ball results in it having more momentum.
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.
The feather and tennis ball will fall at the same rate, hitting the ground at the same time due to gravity's influence on all objects regardless of their mass. However, the feather will experience more air resistance as it falls, which may slow it down slightly compared to the tennis ball.
A bowling ball has more inertia than a basketball because inertia is directly proportional to an object's mass. The larger mass of the bowling ball means that it will be more resistant to changes in its state of motion compared to the basketball.
This can be a tricky question; before answering one like this ask for the frame of reference.If you are in a closet with a floating feather, and a ball on a shelf, and measure momentum relative to the closet, the feather will have more momentum than the bowling ball.However, if you look at the larger picture, you will find thatthe earth is rotatingthe earth is orbiting the sunthe sun is moving relative to other stars near usthe sun is orbiting our galaxyour galaxy is moving relative to other galaxies.Every one of these motions involves momentum, and the total momentum is shared out among everything on or in this planet in proportion to its mass. The bowling ball is enormously massive compared to the feather, and has vastly more momentum in the universal frame of reference.The answer is correct, but the last sentence is wrong. There is no universal frame of reference.
Yes, the mass of a typical bowling ball is greater than the mass of a soccer ball. A regulation bowling ball usually weighs around 6-16 pounds, while a standard soccer ball weighs about 0.4-0.5 pounds.
Nope! Galileo proved that when he dropped a bowling ball and a small ball at the same time and they both landed at the bottom at the same time, but when you're thinking about like a feather and a bowling ball, the feather has more air pockets for air to go through, so the feather falls slower.
A bowling ball has more inertia than a beach ball. Inertia is the resistance of an object to change its state of motion, and it is directly related to an object's mass. Since a bowling ball is heavier and has more mass than a beach ball, it has more inertia.
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 bowling ball has the greatest amount of kinetic energy because it has more mass compared to the ping-pong ball, even though they are traveling at the same speed. Kinetic energy is directly proportional to an object's mass, so the object with higher mass will have more kinetic energy.