I'm pretty sure this question cannot be answered without referring to the function $\ln x$ for real $x$; see below. On the other land, the intricacies of the complex logarithm $\ln z$ may be avoided via the Euler formula
$e^{i\theta} = \cos \theta + i \sin \theta, \; \theta \in \Bbb R, \tag 0$
which implies
$e^{i\theta} = 1 \Longleftrightarrow \theta = 2\pi n, \; n \in \Bbb Z; \tag{0.5}$
see (11)-(12) below.
Now with
$z = x + iy, \; x, y \in \Bbb R;, \tag 1$
we have
$6z = 6x + 6iy = 6x + 6yi, \tag 2$
whence
$e^{6z} = e^{6x + 6yi} = e^{6x}e^{6yi}; \tag 3$
with $\theta = \pi / 2$, (0) implies
$i = e^{\pi i/2}, \tag 4$
and so we proceed as follows:
$e^{6z} = 2i \Longrightarrow e^{6x + 6yi} = 2i \Longrightarrow e^{6x}e^{6yi} = 2e^{ \pi i/2}; \tag 5$
since
$0 < e^{6x} \in \Bbb R, \tag{5.5}$
$e^{6x} = \vert e^{6x} \vert = \vert e^{6x} \vert \vert e^{6yi} \vert = \vert e^{6x}e^{6yi} \vert $
$= \vert 2e^{\pi i/2} \vert = 2\vert e^{\pi i / 2} \vert = 2; \tag 6$
with $x$ real this yields
$6x = \ln 2, \tag 8$
or
$x = \dfrac{\ln 2}{6}. \tag 9$
By virtue of (5) and (6),
$e^{6yi} = e^{\pi i/ 2}, \tag{10}$
that is,
$e^{(6y - \pi/2)i} = e^{6yi - \pi i/2} = 1, \tag{11}$
$\left (6y - \dfrac{\pi }{2}\right)i = 2\pi i n, \; n \in \Bbb Z, \tag{12}$
$6y = \dfrac{\pi}{2} + 2\pi n, \; n \in \Bbb Z, \tag{13}$
$y = \dfrac{\pi}{12} + \dfrac{n \pi}{3}, \; n \in \Bbb Z; \tag{14}$
finally,
$z = x + iy = \dfrac{\ln 2}{6} + \left ( \dfrac{\pi}{12} + \dfrac{n \pi}{3} \right ), \; n \in \Bbb Z. \tag{15}$
Back-tracking through (15) to (4) provides the steps necessary to check this result.
$e^{z_1}$comes out as $e^{z_1}$. – saulspatz Feb 21 '20 at 19:04