h2. Part A
Suppose a 10 kg cubic box is at rest on a horizontal surface. There is friction between the box and the surface characterized by a coefficient of static friction equal to 0.50. If one person pushes on the box with a force _F_~1~ of 25 N directed due north and a second person pushes on the box with a force _F_~2~ = 25 N directed due south, what is the magnitude and direction of the force of static friction acting on the box?
System: Box as [point particle] subject to external influences from the earth (gravity) the surface (normal force and friction) and the two people (applied forces).
Model: [Point Particle Dynamics].
Approach: To determine the force of static friction, we first find the net force _in the absence of friction_. We first draw the situation. A top view (physical representation) and a side view (free body diagram) of the box _ignoring any contribution from friction_ are shown here.
!basicstatic1.png!
The net force parallel to the surface in the absence of friction is then:
{latex}\begin{large}\[ \sum_{F \ne F_{f}} F_{x} = 0 \]
\[\sum_{F \ne F_{f}} F_{y} = F_{1} - F_{2} = 0 \]\end{large}{latex}
Thus, the net force along the surface is zero _without_ the influence of static friction, and so the static friction force will also be 0.
h2. Part B
Suppose a 10 kg cubic box is at rest on a horizontal surface. There is friction between the box and the surface characterized by a coefficient of static friction equal to 0.50. If one person pushes on the box with a force _F_~1~ of 25 N directed due north and a second person pushes on the box with a force _F_~2~ = 25 N directed due east, what is the magnitude and direction of the force of static friction acting on the box?
System: Box as [point particle] subject to external influences from the earth (gravity) the surface (normal force and friction) and the two people (applied forces).
Model: [Point Particle Dynamics].
Approach: To determine the force of static friction, we first find the net force _in the absence of friction_. We first draw the situation. A top view (physical representation) and a side view (free body diagram) of the box _ignoring any contribution from friction_ are shown here.
!basicstatic2.png!
The net force parallel to the surface in the absence of friction is then:
{latex}\begin{large}\[ \sum_{F \ne F_{f}} F_{x} = F_{2} = \mbox{25 N} \]
\[\sum_{F \ne F_{f}} F_{y} = F_{1} = \mbox{25 N} \]\end{large}{latex}
In order to prevent the box from moving, then, static friction would have to satisfy:
{latex}\begin{large}\[ F_{s} = - \mbox{25 N }\hat{x} - \mbox{25 N }\hat{y} = \mbox{35.4 N at 45}^{\circ}\mbox{ S of W}.\]\end{large}{latex}
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