Tangent unit-vector fields: nonabelian homotopy invariants and the Dirichlet energy

Apala Majumdar, J. M. Robbins, M. Zyskin

Research output: Contribution to journalArticle

2 Citations (Scopus)

Abstract

Let O be a closed geodesic polygon in S2. Maps from O into S2 are said to satisfy tangent boundary conditions if the edges of O are mapped into the geodesics which contain them. Taking O to be an octant of S2, we compute the infimum Dirichlet energy ɛ(H) for continuous maps satisfying tangent boundary conditions of arbitrary homotopy type H. The expression for ɛ(H) involves a topological invariant – the spelling length – associated with the (non-abelian) fundamental group of the n-times punctured two-sphere, π1(S2 − {s1,…, sn}, *). The lower bound for ɛ(H) is obtained from combinatorial group theory arguments, while the upper bound is obtained by constructing explicit representatives which, on all but an arbitrarily small subset of O, are alternatively locally conformal or anticonformal. For conformal and anticonformal classes (classes containing wholly conformal and anticonformal representatives respectively), the expression for ɛ(H) reduces to a previous result involving the degrees of a set of regular values s1, …, sn in the target S2 space. These degrees may be viewed as invariants associated with the abelianization of π1(S2 - {s1,…, sn}, *). For nonconformal classes, however, ɛ(H) may be strictly greater than the abelian bound. This stems from the fact that, for nonconformal maps, the number of preimages of certain regular values may necessarily be strictly greater than the absolute value of their degrees.
Original languageUndefined/Unknown
Pages (from-to)1357-1399
Number of pages43
JournalActa Mathematica Scientia
Volume30
Issue number5
DOIs
Publication statusPublished - 1 Sep 2010

Keywords

  • harmonic maps
  • conformal maps
  • algebraic topology
  • non-abelian homotopy invariants
  • combinatorics
  • liquid crystals

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