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In mathematics, a real differential one-form ω 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 $\scriptstyle \omega \,=\,A\,{\text{d}}x\,+\,B\,{\text{d}}y$ , and formally define the conjugate one-form to be $\scriptstyle \omega ^{*}\,=\,A\,{\text{d}}y\,-\,B\,{\text{d}}x$ .

Motivation

There is a clear connection with complex analysis. Let us write a complex number $\scriptstyle z$ in terms of its real and imaginary parts, say $\scriptstyle x$ and $\scriptstyle y$ respectively, i.e. $\scriptstyle z\,=\,x\,+\,iy$ . Since $\scriptstyle \omega \,+\,i\omega ^{*}\,=\,(A\,-\,iB)({\text{d}}x\,+\,i{\text{d}}y)$ , from the point of view of complex analysis, the quotient $\scriptstyle (\omega \,+\,i\omega ^{*})/{\text{d}}z$ tends to a limit as $\scriptstyle {\text{d}}x$ tends to 0. In other words, the definition of $\scriptstyle \omega ^{*}$ was chosen for its connection with the concept of a derivative (analyticity). Another connection with the complex unit is that $\scriptstyle (\omega ^{*})^{*}\,=\,-\omega$ (just as $\scriptstyle i^{2}\,=\,-1$ ).

For a given function $\scriptstyle f$ , let us write $\scriptstyle \omega \,=\,{\text{d}}\!f$ , i.e. $\scriptstyle \omega \,=\,(\partial \!f/\partial x)\,{\text{d}}x\,+\,(\partial \!f/\partial y)\,{\text{d}}y$ where $\scriptstyle \partial$ denotes the partial derivative. Then $\scriptstyle ({\text{d}}\!f)^{*}\,=\,(\partial \!f/\partial x)\,{\text{d}}y\,-\,(\partial \!f/\partial y)\,{\text{d}}x.$ Now $\scriptstyle {\text{d}}({\text{d}}\!f)^{*}$ is not always zero, indeed $\scriptstyle {\text{d}}({\text{d}}\!f)^{*}\,=\,\Delta \,{\text{d}}x\,{\text{d}}y,$ where $\scriptstyle \Delta f\,=\,\partial ^{2}\!f/\partial x^{2}\,+\,\partial ^{2}\!f/\partial y^{2}$

Cauchy–Riemann 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

A harmonic differential (one-form) is precisely the real part of an (analytic) complex differential.^[1] To prove this one shows that u + iv satisfies the Cauchy–Riemann equations exactly when u + iv is locally an analytic function of x + iy. Of course an analytic function w(z) = u + iv is the local derivative of something (namely ∫w(z) dz)

The harmonic differentials ω are (locally) precisely the differentials dƒ of solutions ƒ to Laplace's equation Δƒ = 0.^[1]

If ω is a harmonic differential, so is ω*.^[1]

References

^ ^a ^b ^c Cohn, Harvey (1967), Conformal Mapping on Riemann Surfaces, McGraw-Hill Book Company

[CMRS-1] Cohn, Harvey (1967), Conformal Mapping on Riemann Surfaces, McGraw-Hill Book Company

[1]

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 There is a clear connection with [[complex analysis]]. Let us write a [[complex number]] <math>\scriptstyle z</math> in terms of its [[real part|real]] and [[imaginary part|imaginary]] parts, say <math>\scriptstyle x</math> and <math>\scriptstyle y</math> respectively, i.e. <math>\scriptstyle z \, = \, x \, + \, iy</math>. Since <math>\scriptstyle \omega \, + \, i\omega^* \, = \, (A \, - \, iB)(\text{d}x \, + \, i\text{d}y)</math>, from the point of view of [[complex analysis]], the [[quotient]] <math>\scriptstyle (\omega \, + \, i\omega^*)/\text{d}z</math> tends to a [[limit (mathematics)|limit]] as <math>\scriptstyle \text{d}x</math> tends to 0. In other words, the definition of <math>\scriptstyle \omega^*</math> was chosen for its connection with the concept of a derivative ([[Analytic function|analyticity]]). Another connection with the [[Imaginary unit|complex unit]] is that <math>\scriptstyle (\omega^*)^* \, = \, -\omega</math> (just as <math>\scriptstyle i^2 \, = \, -1</math>).
-For a given [[function (mathematics)|function]] <math>\scriptstyle f</math>, let us write <math>\scriptstyle \omega \, = \, \text{d}f</math>, i.e. <math>\scriptstyle \omega \, = \, (\partial\! f/ \partial x)\,\text{d}x \, + \, (\partial\! f/\partial y)\,\text{d}y</math> where <math>\scriptstyle \partial</math> denotes the [[partial derivative]]. Then <math>\scriptstyle (\text{d}f)^* \,=\, (\partial\! f/\partial x)\,\text{d}y \,-\, (\partial\!f/\partial y)\,\text{d}x.</math> Now <math>\scriptstyle \text{d}(\text{d}f)^*</math> is not always zero, indeed <math>\scriptstyle \text{d}(\text{d}f)^* \, = \, \Delta\,\text{d}x\,\text{d}y,</math> where <math>\scriptstyle \Delta f \, = \, \partial^2\!f/\partial x^2 \,+\, \partial^2\! f/\partial y^2</math>
+For a given [[function (mathematics)|function]] <math>\scriptstyle f</math>, let us write <math>\scriptstyle \omega \, = \, \text{d}\!f</math>, i.e. <math>\scriptstyle \omega \, = \, (\partial\! f/ \partial x)\,\text{d}x \, + \, (\partial\! f/\partial y)\,\text{d}y</math> where <math>\scriptstyle \partial</math> denotes the [[partial derivative]]. Then <math>\scriptstyle (\text{d}\!f)^* \,=\, (\partial\! f/\partial x)\,\text{d}y \,-\, (\partial\!f/\partial y)\,\text{d}x.</math> Now <math>\scriptstyle \text{d}(\text{d}\!f)^*</math> is not always zero, indeed <math>\scriptstyle \text{d}(\text{d}\!f)^* \, = \, \Delta\,\text{d}x\,\text{d}y,</math> where <math>\scriptstyle \Delta f \, = \, \partial^2\!f/\partial x^2 \,+\, \partial^2\! f/\partial y^2</math>
 == Cauchy&ndash;Riemann equations ==