Plessner theorem

One of the basic results in the theory of boundary properties of analytic functions. Let $ f( z) $ be a meromorphic function in the unit disc $ D = \{ {z \in \mathbf C } : {| z | < 1 } \} $ and let $ \Delta = \Delta ( e ^ {i \theta } ) $ be the open angle with vertex $ e ^ {i \theta } $ on the circle $ \Gamma = \{ {z \in \mathbf C } : {| z | = 1 } \} $ formed by two chords of $ D $ passing through $ e ^ {i \theta } $. The point $ e ^ {i \theta } $ is called a Plessner point (or it is said that $ e ^ {i \theta } $ has the Plessner property) if in every arbitrarily small angle $ \Delta $ there exists a sequence $ \{ z _ {k} \} \subset \Delta $ such that

$$ \lim\limits _ {k \rightarrow \infty } z _ {k} = e ^ {i \theta } ,\ \ \lim\limits _ {k \rightarrow \infty } f( z _ {k} ) = w $$

for every value $ w $ in the extended complex plane $ \overline{\mathbf C}\; $. The point $ e ^ {i \theta } $ is called a Fatou point for $ f( z) $ if there exists a single unique limit

$$ \lim\limits f( z) = A $$

as $ z $ tends to $ e ^ {i \theta } $ within any angle $ \Delta $. Plessner's theorem [1]: Almost-all points on $ \Gamma $ with respect to the Lebesgue measure on $ \Gamma $ are either Fatou points or Plessner points.

It is also known that the set $ P( f ) $ of all Plessner points has type $ G _ \delta $ on $ \Gamma $. Examples have been constructed of analytic functions in $ D $ for which $ P( f ) $ is dense on $ \Gamma $ and has arbitrary given Lebesgue measure $ \mathop{\rm mes} P( f ) = m $, $ 0 \leq m < 2 \pi $[3]. Plessner's theorem applies to any meromorphic function $ f( z) $ in any simply-connected domain $ D $ with a rectifiable boundary $ \Gamma $. In that case, $ \zeta \in \Gamma $ is a Fatou point if the following limit exists (cf. also Cluster set):

$$ \lim\limits f( z) = A,\ \ z \in D, $$

as $ z \rightarrow \zeta $ along any non-tangential path; the definition of a Plessner point $ \zeta \in \Gamma $ must be altered in such a way that one considers angles $ \Delta $ with vertex $ \zeta $ and sides forming angles less than $ \pi /2 $ with the normal to $ \Gamma $ at $ \zeta $[2].

Meier's theorem is an analogue of Plessner's theorem in terms of categories of sets (cf. Meier theorem).

References

Comments

Angles of the form $ \Delta $ are called Stolz angles.

A good reference is [a3], to which [3] is a Russian sequel.

Plessner's theorem has a complete analogue for the unit ball in $ \mathbf C ^ {n} $, cf. [a1]: Every holomorphic function on the unit ball decomposes the boundary into three measurable sets, as in the classical case.

References

[a1]	W. Rudin, "Function theory in the unit ball in " , Springer (1981)
[a2]	M. Tsuji, "Potential theory in modern function theory" , Chelsea, reprint (1975)
[a3]	E.F. Collingwood, A.J. Lohwater, "The theory of cluster sets" , Cambridge Univ. Press (1966) pp. Chapt. 9
[a4]	K. Noshiro, "Cluster sets" , Springer (1960)