Expressing the current through a dependent voltage source

If the dependent voltage source was a resistor there would be no current through it since one end of it is connected to an open circuit (at node a). A resistor with no current through it has no voltage through it (since \$V = IR\$), so a resistor would not affect \$V_{\text{TH}}\$.

But the dependent voltage source has a non-zero voltage because its value is \$30\times 10^3 i_0\$ (where \$i_0\$ is the current through the upper resistor), and \$i_0\$ is non-zero.

There is still no current through the dependent source because it is connected to an open circuit at node a. That means the current through both resistors (\$i_0\$) is the same: $$i_0 = -\frac{100\text{V}}{20\text{k}\Omega + 80\text{k}\Omega} = -1\text{mA}$$

\$i_0\$ is negative based on the direction indicated in the circuit. The dependent voltage source's voltage is therefore $$V_D = 30\times 10^3 i_0 = -30\text{V}$$

This needs to be added to the voltage at the node between the resistors (which is a simple voltage divider) to calculate \$V_{\text{TH}}\$.

Without dependent (voltage) sources one could normally define a matrix equation to solve for the values in the network:
[Z][I] = [V]

In this case though we must add in dependent voltage sources
[Z][I] = [V] + [k][I]

Apologies, I renamed I3 above as I2 below, per the usual custom of ordering currents left to right as shown in sketch.

From this diagram, we extract the matrix equation suggested above.

This rearranges as
[Z][I] - [k][I] = [V]

Rearranging again [I] = ([Z]-[k])^-1 · [V]

Solution of the matrix math is standard matrix math left to the reader. It produces an equation for each of the 3 currents defined in the sketch as a function of the single independent voltage.

This gives the currents as a function of the one independent voltage.

At this point
Va = (I1 - I2)·R2

And Vb = (I2 - I3)·R4