# What is the acceleration of a 6.4 kilogram bowling ball?

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## What is the acceleration of a 6.4 kilogram bowling ball?

1 Answer. The acceleration of the bowling ball is 1.875 ms2 .

## What is the momentum of a 6.0 kg bowling ball with a velocity?

p=6×2.2=13.2kg m/s. Q.

## What force would a 10 kg bowling ball require to accelerate?

Answer and Explanation: Hence, the calculated force needed to accelerate the bowling ball is 30 Newton. Thus, the first option is correct.

## What is the impulse needed to stop a 10 kg bowling ball moving at 6m s?

Answer and Explanation: Therefore, the impulse needed to stop the bowling ball is − 60 k g m / s .

## What is the momentum of a 6.0 kg ball?

Expert-Verified Answer Mass of the ball = 6 kg. Velocity = 2.2 m/s. ∴ p = 13.2 kgms⁻¹. Hence, the momentum of the ball is 13.2 kgms⁻¹.

## What is the acceleration of a 6 kg object?

A 6-kg object experiences an acceleration of 2 m/s/s. 2. A net force of 15 N is exerted on an encyclopedia to cause it to accelerate at a rate of 5 m/s2.

## What is the momentum of a 4 kg ball?

A 4 kg ball has a momentum of 12 kg m/s.

## What is the formula for momentum velocity?

p = m v . You can see from the equation that momentum is directly proportional to the object’s mass (m) and velocity (v). Therefore, the greater an object’s mass or the greater its velocity, the greater its momentum.

## What is the acceleration of a 5 kg bowling ball when a 10 N force is applied?

Here the force is 10N and the mass is 5 kg. Dividing both sides by 5kg, we get a = 2 m/s^2.

## How to find acceleration?

Acceleration (a) is the change in velocity (Δv) over the change in time (Δt), represented by the equation a = Δv/Δt. This allows you to measure how fast velocity changes in meters per second squared (m/s^2). Acceleration is also a vector quantity, so it includes both magnitude and direction.

## What Newton’s law of motion is a bowling ball?

Newton’s third law states that when a force is exerted on an object, it exerts an equal and opposite force on the object exerting the force. So in our case, when the bowling ball exerts a force on the bowling pin, the bowling pin exerts an equal force in the opposite direction on the bowling ball.

## Can force slow down a ball?

The grass the ball rolls over and the air it moves through both exert forces that push the ball in the opposite direction of the kick, causing the ball to slow down and eventually stop. 3. All objects slow down and eventually stop. If no forces are acting on a moving object, its motion will never change or stop.

## What is the impulse rule in physics?

The impulse of a force is I=Ft I = F t – when a constant force F acts for a time t . The units are Ns . The Impulse-Momentum Principle says I=mv−mu I = m v − m u which is final momentum – initial momentum so Impulse is the change in momentum.

## How do you solve impulse problems in physics?

## What is the formula for impulsive motion?

Dimensional Formula of Impulse This dimension is measured in Newtons and has a formula of [M1L1T-1]. Δt is measured in seconds and has the dimensional formula [M0L0T1]. The following dimensional formula is obtained by solving the above equation: The required dimension for the impulse formula is [M1L1T-1].

## Does a bowling ball have acceleration?

The acceleration of the bowling ball equals its friction coefficient multiplied by gravity. Using basic calculus, we know that the derivative of velocity with respect to time equals acceleration, or the friction coefficient times gravity.

## What is the acceleration of a 0.30 kilogram ball?

The acceleration of the ball is 83.333ms2[forward] . Now that may seem like a lot, and that’s because you are applying a lot of force to a relatively small (and lightweight) object.

## What is the formula for the acceleration of a ball?

According to Newton’s second law of motion, the acceleration of an object equals the net force acting on it divided by its mass, or a = F m . This equation for acceleration can be used to calculate the acceleration of an object when its mass and the net force acting on it are known.