As per Newton's first law of motion, if the applied force remains the same, an increase in mass will result in a decrease in acceleration. In contrast, if the acceleration were to remain the same when the mass increases, there must be a greater force applied.
Newton's Second Law: Force = mass x acceleration. Solving for acceleration: acceleration = force / mass.
Therefore, if you increase the mass, the same force will produce less acceleration.
Newton's Second Law: Force = mass x acceleration. Solving for acceleration: acceleration = force / mass.
Therefore, if you increase the mass, the same force will produce less acceleration.
Newton's Second Law: Force = mass x acceleration. Solving for acceleration: acceleration = force / mass.
Therefore, if you increase the mass, the same force will produce less acceleration.
Newton's Second Law: Force = mass x acceleration. Solving for acceleration: acceleration = force / mass.
Therefore, if you increase the mass, the same force will produce less acceleration.
Newton's Second Law: Force = mass x acceleration. Solving for acceleration: acceleration = force / mass.
Therefore, if you increase the mass, the same force will produce less acceleration.
f=ma Force equals mass times acceleration. Increasing the mass reduces the acceleration.
Acceleration depends on the mass: a=F/m. Unless it is acceleration due to gravity, where it would be constant no matter the mass.
Look at Newton's Second Law. Solving for acceleration, you get: a = F/m. That is, if the force DOESN'T change, then more mass means less acceleration.
The force also increases.
the mass will increase
It depends on what the acceleration is due to. In the case of a falling object the acceleration is due to gravitational pull and remains the same regardless of the mass. In the case of a projectile being propelled by an explosive and increase in mass would mean a decrease in velocity given the amount of propellant remains static.
By F = ma, if the force remains constant, and the mass decreases, this would mean that the acceleration has increased by exactly the same factor as the decrease in mass. That is, if the mass of a substance was halved, its acceleration would have doubled exactly.
Force is mass x acceleration so in order to increase the acceleration without increasing the force, you must decrease the mass.
The force also increases.
If you increase the force on an object acceleration increases . As F = m*a, where F = Force , m = mass of the object & a = acceleration
If you increase the force on an object acceleration increases . As F = m*a, where F = Force , m = mass of the object & a = acceleration
If the mass of an object increases, what happens to the acceleration?
If the mass of an object increases, what happens to the acceleration?
To achieve more acceleration, you need more force.
the mass will increase
By looking at the equation F=ma we have two ways to increase acceleration. If we keep the mass constant and increase the force applied then the acceleration of the object will increase. If we keep the force constant and use a smaller mass then the mass will experience a greater acceleration than a greater mass.
It depends on what the acceleration is due to. In the case of a falling object the acceleration is due to gravitational pull and remains the same regardless of the mass. In the case of a projectile being propelled by an explosive and increase in mass would mean a decrease in velocity given the amount of propellant remains static.
F=ma, or force equals the product of mass and acceleration. Assuming that the mass of the object does not change, then acceleration increases as force increases.
By F = ma, if the force remains constant, and the mass decreases, this would mean that the acceleration has increased by exactly the same factor as the decrease in mass. That is, if the mass of a substance was halved, its acceleration would have doubled exactly.
its acceleration will be increased