Morera's theorem

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In complex analysis, a branch of mathematics, Morera's theorem, named after Giacinto Morera, gives a criterion for proving that a function is holomorphic.

Morera's theorem states that a continuous, complex-valued function f defined on an open set D in the complex plane that satisfies $${\displaystyle \oint _{\gamma }f(z)\,dz=0}$$ for every closed piecewise C¹ curve ${\displaystyle \gamma }$ in D must be holomorphic on D.

The assumption of Morera's theorem is equivalent to f having an antiderivative on D.

The converse of the theorem is not true in general. A holomorphic function need not possess an antiderivative on its domain, unless one imposes additional assumptions. The converse does hold e.g. if the domain is simply connected; this is Cauchy's integral theorem, stating that the line integral of a holomorphic function along a closed curve is zero.

The standard "counterexample" is the function f(z) = 1/z, which is holomorphic on C − {0}. On any simply connected neighborhood U in C − {0}, 1/z has an antiderivative defined by L(z) = ln(r) + iθ, where z = re^iθ. Because of the ambiguity of θ up to the addition of any integer multiple of 2π, any continuous choice of θ on U will suffice to define an antiderivative of 1/z on U. (It is the fact that θ cannot be defined continuously on a simple closed curve containing the origin in its interior that is the root of why 1/z has no antiderivative on its entire domain C − {0}.) And because the derivative of an additive constant is 0, any constant may be added to the antiderivative and the result will still be an antiderivative of 1/z.

To prove the theorem, we construct an anti-derivative for f. Since the anti-derivative is holomorphic (by construction!), and since holomorphic functions are analytic, it follows that f is holomorphic.

Without loss of generality, it can be assumed that D is connected. Fix a point z₀ in D, and for any ${\displaystyle z\in D}$, let ${\displaystyle \gamma :[0,1]\to D}$ be a piecewise C¹ curve such that ${\displaystyle \gamma (0)=z_{0}}$ and ${\displaystyle \gamma (1)=z}$. Then define the function F to be $${\displaystyle F(z)=\int _{\gamma }f(\zeta )\,d\zeta .}$$

To see that the function is well-defined, suppose ${\displaystyle \tau :[0,1]\to D}$ is another piecewise C¹ curve such that ${\displaystyle \tau (0)=z_{0}}$ and ${\displaystyle \tau (1)=z}$. The curve ${\displaystyle \gamma \tau ^{-1}}$ (i.e. the curve combining ${\displaystyle \gamma }$ with ${\displaystyle \tau }$ in reverse) is a closed piecewise C¹ curve in D. Then, $${\displaystyle \int _{\gamma }f(\zeta )\,d\zeta +\int _{\tau ^{-1}}f(\zeta )\,d\zeta =\oint _{\gamma \tau ^{-1}}f(\zeta )\,d\zeta =0.}$$

And it follows that $${\displaystyle \int _{\gamma }f(\zeta )\,d\zeta =\int _{\tau }f(\zeta )\,d\zeta .}$$

Then using the continuity of f to estimate difference quotients, we get that F′(z) = f(z). Had we chosen a different z₀ in D, F would change by a constant: namely, the result of integrating f along any piecewise regular curve between the new z₀ and the old, and this does not change the derivative.

Morera's theorem is a standard tool in complex analysis. It is used in almost any argument that involves a non-algebraic construction of a holomorphic function.

For example, suppose that f₁, f₂, ... is a sequence of holomorphic functions, converging uniformly to a continuous function f on an open disc. By Cauchy's theorem, we know that $${\displaystyle \oint _{C}f_{n}(z)\,dz=0}$$ for every n, along any closed curve C in the disc. Then the uniform convergence implies that $${\displaystyle \oint _{C}f(z)\,dz=\oint _{C}\lim _{n\to \infty }f_{n}(z)\,dz=\lim _{n\to \infty }\oint _{C}f_{n}(z)\,dz=0}$$ for every closed curve C, and therefore by Morera's theorem f must be holomorphic. This fact can be used to show that, for any open set Ω ⊆ C, the set A(Ω) of all bounded, analytic functions u : Ω → C is a Banach space with respect to the supremum norm.

Morera's theorem can also be used in conjunction with Fubini's theorem and the Weierstrass M-test to show the analyticity of functions defined by sums or integrals, such as the Riemann zeta function $${\displaystyle \zeta (s)=\sum _{n=1}^{\infty }{\frac {1}{n^{s}}}}$$ or the Gamma function $${\displaystyle \Gamma (\alpha )=\int _{0}^{\infty }x^{\alpha -1}e^{-x}\,dx.}$$

Specifically one shows that $${\displaystyle \oint _{C}\Gamma (\alpha )\,d\alpha =0}$$ for a suitable closed curve C, by writing $${\displaystyle \oint _{C}\Gamma (\alpha )\,d\alpha =\oint _{C}\int _{0}^{\infty }x^{\alpha -1}e^{-x}\,dx\,d\alpha }$$ and then using Fubini's theorem to justify changing the order of integration, getting $${\displaystyle \int _{0}^{\infty }\oint _{C}x^{\alpha -1}e^{-x}\,d\alpha \,dx=\int _{0}^{\infty }e^{-x}\oint _{C}x^{\alpha -1}\,d\alpha \,dx.}$$

Then one uses the analyticity of α ↦ x^α−1 to conclude that $${\displaystyle \oint _{C}x^{\alpha -1}\,d\alpha =0,}$$ and hence the double integral above is 0. Similarly, in the case of the zeta function, the M-test justifies interchanging the integral along the closed curve and the sum.

The hypotheses of Morera's theorem can be weakened considerably. In particular, it suffices for the integral $${\displaystyle \oint _{\partial T}f(z)\,dz}$$ to be zero for every closed (solid) triangle T contained in the region D. This in fact characterizes holomorphy, i.e. f is holomorphic on D if and only if the above conditions hold. It also implies the following generalisation of the aforementioned fact about uniform limits of holomorphic functions: if f₁, f₂, ... is a sequence of holomorphic functions defined on an open set Ω ⊆ C that converges to a function f uniformly on compact subsets of Ω, then f is holomorphic.

• Cauchy–Riemann equations
• Methods of contour integration
• Residue (complex analysis)
• Mittag-Leffler's theorem

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• "Morera theorem", Encyclopedia of Mathematics, EMS Press, 2001 [1994]
• Weisstein, Eric W. "Morera's Theorem". MathWorld.