A horizontal force of 750 N is needed to overcome the force of static friction between a level floor and a 250-kg crate. What is the acceleration of the crate if the 750-N force is maintained after the crate begins to move and the coefficient of kinetic friction is 0.16?

First, we need to find the force of static friction that was initially acting on the crate to keep it from moving:

\( f_s = \mu_s \cdot N \),
where:
\( f_s \) = force of static friction
\( \mu_s \) = coefficient of static friction
\( N \) = normal force

The normal force is equal to the weight of the crate, which can be found using:
\( N = m \cdot g \),
where:
\( m \) = mass of the crate
\( g \) = acceleration due to gravity (9.8 m/s^2)

\( N = 250 \, kg \cdot 9.8 \, m/s^2 = 2450 \, N \)

Now we can calculate the force of static friction:
\( f_s = 0.16 \cdot 2450 \, N = 392 \, N \)

Since the crate is now moving, the force of kinetic friction comes into play:
\( f_k = \mu_k \cdot N \),
where:
\( f_k \) = force of kinetic friction
\( \mu_k \) = coefficient of kinetic friction

\( f_k = 0.16 \cdot 2450 \, N = 392 \, N \)

Since the applied force is greater than the force of kinetic friction:
\( F_{\text{net}} = F_{\text{applied}} - f_k \),
\( F_{\text{net}} = 750 \, N - 392 \, N = 358 \, N \)

Now we can find the acceleration of the crate:
\( F_{\text{net}} = m \cdot a \),
\( 358 \, N = 250 \, kg \cdot a \),
\( a = \frac{358}{250} = 1.43 \, m/s^2 \)

Therefore, the acceleration of the crate is \( 1.43 \, m/s^2 \) when the 750-N force is maintained after the crate begins to move.