Hostname: page-component-586b7cd67f-dlnhk Total loading time: 0 Render date: 2024-11-22T23:40:33.397Z Has data issue: false hasContentIssue false

The Dependence of Capacities on moving Branch points

Published online by Cambridge University Press:  11 January 2016

Mitsuru Nakai*
Affiliation:
Department of Mathematics Nagoya Institute of Technology Gokiso, Showa Nagoya, 466-8555Japan
*
52 Eguchi, Hinaga, Chita, 478-0041, Japan, [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

We are concerned with the question how the capacity of the ideal boundary of a subsurface of a covering Riemann surface over a Riemann surface varies according to the variation of its branch points. In the present paper we treat the most primitive but fundamental situation that the covering surface is a two sheeted sphere with two branch points one of which is fixed and the other is moving and the subsurface is given as the complement of two disjoint continua each in different sheets of the covering surface whose projections are two disjoint continua in the base plane given in advance not touching the projections of branch points. We will derive a variational formula for the capacity and as one of its many useful consequences expected we will show that the capacity changes smoothly as one branch point moves in the subsurface.

Keywords

Type
Research Article
Copyright
Copyright © Editorial Board of Nagoya Mathematical Journal 2007

References

[1] Axler, S., Bourdon, P. and Ramey, W., Harmonic Function Theory, Second Edition, Springer, 2001.Google Scholar
[2] Heinonen, J., Kilpeläinen, T. and Martio, O., Nonlinear Potential Theory of Degenerate Elliptic Equations, Oxford Univ. Press, 1993.Google Scholar
[3] Levenberg, N. and Yamaguchi, H., The metric induced by the Robin function, Memoirs of the Amer. Math. Soc., 92#448 (1991), 1156.Google Scholar
[4] Levenberg, N. and Yamaguchi, H., Robin functions for complex manifolds and applications, CR geometry and isolated singularities, Report of RIMS of Kyoto Univ., 1037 (1998), 138142.Google Scholar
[5] Levenberg, N. and Yamaguchi, H., Robin functions for complex manifolds and applications, Abstracts for lectures in Function Theory Symposium, 47 (2004), 2647.Google Scholar
[6] Nakai, M., Types of complete infinitely sheeted planes, Nagoya Math. Jour., 176 (2004), 181195.Google Scholar
[7] Nakai, M., Types of pasting arcs in two sheeted spheres, Potential Theory in Matsue, Advanced Studies in Pure Mathematics, 44 (2006), 291304.Google Scholar
[8] Nakai, M., The role of compactification theory in the type problem, Hokkaido Math. Jour., to appear.Google Scholar
[9] Nakai, M. and Segawa, S., Parabolicity of Riemann surfaces, Hokkaido Univ. Tech. Rep., Ser. in Math., 73 (2003), 111116.Google Scholar
[10] Nakai, M. and Segawa, S., A role of the completeness in the type problem for infinitely sheeted planes, Complex Variables, 49 (2004), 229240.Google Scholar
[11] Nakai, M. and Segawa, S., The role of symmetry for pasting arcs in the type problem, Complex Variables and Elliptic Equations, to appear.Google Scholar
[12] Nevannlina, R., Analytic Functions, Springer, 1970.Google Scholar
[13] Rauch, H. E., Weierstrass points, branch points, and the moduli of Riemann surfaces, Comm. Pure Appl. Math., 12 (1959), 543560.CrossRefGoogle Scholar
[14] Rodin, B. and Sario, L., Principal Functions, Van Nostrand, 1970.Google Scholar
[15] Sario, L. and Nakai, M., Classification Theory of Riemann Surfaces, Springer, 1970.Google Scholar
[16] Schiff, J. L., Normal Families, Springer, 1993.Google Scholar
[17] Tsuji, M., Potential Theory in Modern Function Theory, Maruzen, 1959.Google Scholar
[18] Yamaguchi, H., Sur le mouvement des constantes de Robin, J. Math. Kyoto Univ., 15 (1975), 5371.Google Scholar
[19] Yamaguchi, H., Variations of pseudoconvex domains over Cn , Michigan Math. Jour., 36 (1989), 415457.Google Scholar