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The Method of Weierstraß

Fig 6. Copper plate engraving in H.A. Schwarz'
collected works from 1890 on the solution of Gergonne's problem.

The work of Robert Osserman of Stanford University
(California) in the early 1960s ushered in developments that led to the
construction of new unbounded minimal surfaces. Osserman's work revived a
method of Karl Theodor Weierstraß (18151897), who was active in Berlin.
Long before the aforementioned calculus of variations could be applied to
minimal surfaces, it had been observed that there is a close connection
between minimal surfaces and another great direction in mathematics:
complex analysis, which was already flourishing in the 19th century, and
which was concerned with the properties of complex numbers and functions.
Using complex analysis, Weierstraß discovered his "representation
formulas" which describe any minimal surface. Inserting an arbitrary pair
of two complex functions into the Weierstraß formulas provides for the
mathematical representation of a minimal surface. But, it is hard to
conclude the geometric shape of the resulting surface, e.g. whether or not
surfaces obtained in this way will intersect themselves. Hence this
approach is satisfactory only for the description of a small portion of a
surface, but it is still invaluable for mathematical theory.
A group around the German mathematician Hermann Amandus
Schwarz (18431921) succeeded in 1865 in finding, for special boundary
curves, functions (more exactly, differential forms) that  when inserted
into the representation formulas  provide the solution for the Plateau
problem for this boundary curve (cf Fig 6). However,
after Douglas and Rado had accomplished their breakthrough in 1931 with
the help of the calculus of variations, the methods of Weierstraß and
Schwarz retreated farther into the background. Their present success comes
from the fact that, based on the work of Osserman, the shape of many
minimal surfaces can be controlled out to infinity.
