Bôcher's theorem

In mathematics, Bôcher's theorem is either of two theorems named after the American mathematician Maxime Bôcher.

Bôcher's theorem in complex analysis[edit]

In complex analysis, the theorem states that the finite zeros of the derivative $r'(z)$ of a non-constant rational function $r(z)$ that are not multiple zeros are also the positions of equilibrium in the field of force due to particles of positive mass at the zeros of $r(z)$ and particles of negative mass at the poles of $r(z)$ , with masses numerically equal to the respective multiplicities, where each particle repels with a force equal to the mass times the inverse distance.

Furthermore, if C₁ and C₂ are two disjoint circular regions which contain respectively all the zeros and all the poles of $r(z)$ , then C₁ and C₂ also contain all the critical points of $r(z)$ .

Bôcher's theorem for harmonic functions[edit]

In the theory of harmonic functions, Bôcher's theorem states that a positive harmonic function in a punctured domain (an open domain minus one point in the interior) is a linear combination of a harmonic function in the unpunctured domain with a scaled fundamental solution for the Laplacian in that domain.

External links[edit]

Marden, Morris (1951-05-01). "Book Review: The location of critical points of analytic and harmonic functions". Bulletin of the American Mathematical Society. 57 (3): 194–205. doi:10.1090/s0002-9904-1951-09490-2. MR 1565303. (Review of Joseph L. Walsh's book.)

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Bôcher's theorem in complex analysis[edit]

Bôcher's theorem for harmonic functions[edit]

See also[edit]

External links[edit]