8. A speeding car is traveling at a constant speed of +30.0 m/s when it

To determine how fast the police car will be going when it catches up with the speeding car, we can use the equation of motion:

v^2 = u^2 + 2as

Where:
v = final velocity of the police car
u = initial velocity of the police car
a = acceleration of the police car
s = displacement

In this scenario, the initial velocity of the police car (u) is 0 m/s (since it is stopped), the acceleration (a) is +7.0 m/s^2, and the displacement (s) will be the same for both vehicles since they will meet at some point.

To find the displacement, we can use the equation:

s = ut + (1/2)at^2

Where:
t = time taken for the police car to catch up with the speeding car

Since the speeding car is traveling at a constant speed, the displacement s will be equal to the product of the constant speed and the time taken (t) for the police car to catch up.

Therefore, s = 30.0 m/s * t

Now we can substitute this value of s into the first equation to find the final velocity (v) of the police car:

v^2 = 0^2 + 2 * 7.0 m/s^2 * (30.0 m/s * t)

Simplifying,

v^2 = 2 * 7.0 m/s^2 * (30.0 m/s * t)

v^2 = 420 m/s * t

Taking the square root of both sides,

v = √(420 m/s * t)

Since this equation gives the final velocity (v) of the police car in terms of time (t), we need to know the time it takes for the police car to catch up with the speeding car in order to find the final velocity.

Unfortunately, this information is not provided, so we cannot calculate the exact final velocity of the police car.