To arrive at the desired landing point, the woman should head the boat in a direction that compensates for the effect of the river's flow.

Let's assume that the direction the boat should head in to offset the river's flow is θ degrees south of east.

The velocity of the boat relative to the ground can be represented by a vector addition of the velocity of the boat relative to the water and the velocity of the water current.

The velocity of the boat relative to the ground is equal to the vector sum of the velocity of the boat relative to the water and the velocity of the river current.
VBG = VBW + VRC

The magnitude of VBW can be found using the boat's speed relative to the water, which is given as 12 mi/h.
|VBW| = 12 mi/h

The magnitude of VRC can be found using the river's flow rate, which is given as 6 mi/h.
|VRC| = 6 mi/h

Since the boat needs to arrive directly across the river, the y-component of VBG should be zero.
VBGy = 0

Based on these considerations, the following equation can be set up:

VBW*sinθ + VRC*sin90 = 0

VBW*sinθ = -VRC

Simplifying:
12*sinθ = -6
sinθ = -6/12

sinθ = -0.5

Since the sin of an angle is negative in the third and fourth quadrants, θ must be in the third quadrant.

Using the inverse sine function to find the angle:
θ = invsin(-0.5)
θ ≈ -30.96 degrees

Therefore, the woman should head the boat in a direction approximately 30.96 degrees south of east to arrive at the desired landing point.