A dockworker applies a constant horizontal force of 80.0 N to a block

Step 1) To find the mass of the block of ice, we can use Newton's second law of motion:
$\text{Force}=\text{mass}\times \text{acceleration}$
Since the block moves with a constant velocity, its acceleration is zero. Therefore, the applied force is equal to the force of inertia:
$\text{Force}=\text{mass}\times \text{acceleration}=\text{mass}\times 0=0$
Since the force applied by the dockworker is the only horizontal force acting on the block, the mass of the block of ice is 0 kg.
Step 2) If the worker stops pushing at the end of 5.00 s, the block will continue to move with its current velocity due to its inertia. Since there are no horizontal forces acting on the block, it will move with a constant velocity in the next 5.00 s.
Therefore, the block will move the same distance as it did in the first 5.00 s, which is 11.0 m.
Hence, the block will move 11.0 m in the next 5.00 s.

Answer:
1) The mass of the block of ice is approximately 90.9 kg.
2) If the worker stops pushing at the end of 5.00 s, the block will move approximately 11.0 m in the next 5.00 s.
Explanation:
To solve the given problem, let's use the following equations of motion:
1) $v=u+at$
2) $s=ut+\frac{1}{2}a{t}^2$
3) $v^2=u^2+2as$
Where:
- $s$ represents the displacement (distance traveled)
- $u$ represents the initial velocity
- $v$ represents the final velocity
- $a$ represents the acceleration
- $t$ represents the time
Given:
The horizontal force applied, $F=80.0$ N
The displacement, $s=11.0$ m
The time, $t=5.00$ s
1) To find the mass of the block of ice, we'll use Newton's second law of motion, $F=ma$, where $m$ is the mass and $a$ is the acceleration. Since the frictional force is negligible, the only force acting on the block is the applied force. Therefore, $F=ma$.
We can rearrange the equation to solve for mass:
$m=\frac{F}{a}$
Now, let's calculate the acceleration using the given displacement and time.
Using equation 2, $s=ut+\frac{1}{2}a{t}^2$, we can rearrange it to solve for acceleration:
$a=\frac{2(s-ut)}{t^2}$
Substituting the given values into the equation, we get:
$a=\frac{2(11.0-0·5.00)}{(5.00{)}^2}$
Simplifying the equation:
$a=\frac{22.0}{25.0}$
Now, we can substitute the acceleration into the equation for mass:
$m=\frac{80.0}{\frac{22.0}{25.0}}$
Simplifying the equation:
$m=\frac{80.0·25.0}{22.0}$
$m\approx 90.9$ kg
Therefore, the mass of the block of ice is approximately 90.9 kg.
2) If the worker stops pushing at the end of 5.00 s, the block will continue to move with the initial velocity it acquired during the first 5.00 s. So, the final velocity, $v$, remains the same.
To find the distance traveled in the next 5.00 s, we'll use equation 2:
$s=ut+\frac{1}{2}a{t}^2$
Since the block starts from rest, the initial velocity, $u$, is 0. The time, $t$, is 5.00 s, and we already know the acceleration, $a$, from the previous calculation.
Substituting the values into the equation:
$s=0·5.00+\frac{1}{2}·\frac{22.0}{25.0}·(5.00{)}^2$
Simplifying the equation:
$s=\frac{22.0}{25.0}·12.5$
$s\approx 11.0$ m
Therefore, the block will move approximately 11.0 m in the next 5.00 s.