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Can someone explain why complex analytic functions should be open mappings. A complex analytic function $f:D \to \mathbb{C}$ on some open domain $D$ can be thought of as $f:D \to \mathbb{R}^2$, $f(x,y)= (f_1(x,y),f_2(x,y))$. The Cauchy Riemann equations then tell us that the total derivative of $f$ is

$\begin{pmatrix} \partial_x f_1 & -\partial_x f_2 \\ \partial_x f_2 & \partial_x f_1 \end{pmatrix}$

whose determinant is nonzero whenever f'(z) \neq 0. Thus the inverse function theorem tells us that $f$ is an open mapping if we knew that f'(z) was never zero.

Can someone explain conceptually why open mapping should hold around a point $z$ where f'(z)=0 where the inverse function theorem itself is not enough to show openness?

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Conceptually... without loss of generality, take $f(0) = 0, \; f'(0)=0.$ There is a power series, and since the function is not constant, not all terms are $0.$ There is a first nonvanishing derivative, and the power series begins $ a_n z^n + a_{n+1} z^{n+1} + \cdots, $ with $a_n \neq 0.$ Near the origin, $ f(z) = a_n z^n \left( 1 + \frac{a_{n+1}}{a_n} z + \frac{a_{n+2}}{a_n} z^2 + \cdots \right)=a_n z^ng(z)$ Now, the quotient $ g(z) = 1 + \frac{a_{n+1}}{a_n} z + \frac{a_{n+2}}{a_n} z^2 + \cdots$ is nonzero near the origin. So, for some target $b \neq 0$ near the origin, solving $ f(z) = b$ is the same as solving $ z^n = \frac{b}{a_n g(z)} $ where the right hand side is nearly constant. The result turns out to be that there are exactly $n$ solutions to $ f(z) = b,$ and the ratio of any two of these solutions is very close to an $n$th root of unity.

This is Theorem 11 on page 131 of Ahlfohrs, section 3.3 on The Local Mapping.

I could summarize this by saying that, around a zero of order $n,$ the mapping stops being $1$ to $1$ and becomes $n$ to $1.$

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    @AntonioVargas, thank you. From your MSE profile, you might enjoy looking at http://math.stackexchange.com/questions/122945/complex-functions-bounded-in-the-upper-half-plane. I have requested two library books by http://en.wikipedia.org/wiki/Christian_Pommerenke as I now believe a bounded holomorphic function on the open upper half plane need not extend continuously to the real line, but examples appear to be very difficult.2012-03-27