Harmonic differential

In mathematics, a real differential one-form ω on a surface is called a harmonic differential if ω and its conjugate one-form, written as ω*, are both closed.

Explanation

Consider the case of real one-forms defined on a two dimensional real manifold. Moreover, consider real one-forms which are the real parts of complex differentials. Let ω = Adx + Bdy, and formally define the conjugate one-form to be ω* = Ady Bdx.

Motivation

There is a clear connection with complex analysis. Let us write a complex number z in terms of its real and imaginary parts, say x and y respectively, i.e. z = x + iy. Since ω + iω* = (A iB)(dx + idy), from the point of view of complex analysis, the quotient (ω + iω*)/dz tends to a limit as dz tends to 0. In other words, the definition of ω* was chosen for its connection with the concept of a derivative (analyticity). Another connection with the complex unit is that (ω*)* = ω (just as i2 = 1).

For a given function f, let us write ω = df, i.e. ω = (∂f/∂x)dx + (∂f/∂y)dy where ∂ denotes the partial derivative. Then (df)* = (∂f/∂x)dy (∂f/∂y)dx. Now d(df)* is not always zero, indeed d(df)* = Δfdxdy, where Δf = ∂2f/∂x2 + ∂2f/∂y2.

CauchyRiemann equations

As we have seen above: we call the one-form ω harmonic if both ω and ω* are closed. This means that A/∂y = ∂B/∂x (ω is closed) and B/∂y = A/∂x (ω* is closed). These are called the Cauchy–Riemann equations on A iB. Usually they are expressed in terms of u(x, y) + iv(x, y) as u/∂x = ∂v/∂y and v/∂x = u/∂y.

Notable results

See also

References

  1. 1 2 3 Cohn, Harvey (1967), Conformal Mapping on Riemann Surfaces, McGraw-Hill Book Company
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