When discussing functions of a complex variable it is often convenient to think of a
cut in the complex plane. This idea arises naturally in several different contexts.
Multi-valued relationships and branch points Consider the simple two-valued relationship w = f(z) = \pm\sqrt{z} = z^{1/2}. Before we can treat this relationship as a single-valued
function, the range of the resulting value must be restricted somehow. When dealing with the square roots of non-negative real numbers this is easily done. For instance, we can just define y = g(x) = \sqrt{x} = x^{1/2} to be the non-negative real number such that . This idea doesn't work so well in the two-dimensional complex plane. To see why, let's think about the way the value of varies as the point moves around the unit circle. We can write z = re^{i\theta} and take \begin{align} w &= z^{1/2} \\ &= \sqrt{r}\,e^{i\theta/2}, \quad 0\leq\theta\leq 2\pi. \end{align} Evidently, as moves all the way around the circle, only traces out one-half of the circle. So one continuous motion in the complex plane has transformed the positive square root into the negative square root . This problem arises because the point has just one square root, while every other complex number has exactly two square roots. On the real number line we could circumvent this problem by erecting a "barrier" at the single point . A bigger barrier is needed in the complex plane, to prevent any closed contour from completely encircling the
branch point . This is commonly done by introducing a
branch cut; in this case the "cut" might extend from the point along the positive real axis to the point at infinity, so that the argument of the variable in the cut plane is restricted to the range . We can now give a complete description of . To do so we need two copies of the -plane, each of them cut along the real axis. On one copy we define the square root of 1 to be , and on the other we define the square root of 1 to be . We call these two copies of the complete cut plane ''''. By making a continuity argument we see that the (now single-valued) function maps the first sheet into the upper half of the -plane, where , while mapping the second sheet into the lower half of the -plane (where ). The branch cut in this example does not have to lie along the real axis; it does not even have to be a straight line. Any continuous curve connecting the origin with the point at infinity would work. In some cases the branch cut doesn't even have to pass through the point at infinity. For example, consider the relationship w = g(z) = \left(z^2 - 1\right)^{1/2}. Here the polynomial vanishes when , so evidently has two branch points. We can "cut" the plane along the real axis, from to , and obtain a sheet on which is a single-valued function. Alternatively, the cut can run from along the positive real axis through the point at infinity, then continue "up" the negative real axis to the other branch point, . This situation is most easily visualized by using the
stereographic projection described above. On the sphere one of these cuts runs longitudinally through the southern hemisphere, connecting a point on the equator () with another point on the equator (), and passing through the south pole (the origin, ) on the way. The second version of the cut runs longitudinally through the northern hemisphere and connects the same two equatorial points by passing through the north pole (that is, the point at infinity).
Restricting the domain of meromorphic functions A
meromorphic function is a complex function that is
holomorphic and therefore
analytic everywhere in its domain except at a finite, or
countably infinite, number of points. The points at which such a function cannot be defined are called the
poles of the meromorphic function. Sometimes all of these poles lie in a straight line. In that case mathematicians may say that the function is "holomorphic on the cut plane". By example: The
gamma function, defined by \Gamma (z) = \frac{e^{-\gamma z}}{z} \prod_{n=1}^\infty \left[\left(1+\frac{z}{n}\right)^{-1}e^{z/n}\right] where is the
Euler–Mascheroni constant, and has simple poles at because exactly one denominator in the
infinite product vanishes when , or a negative integer. Since all its poles lie on the negative real axis, from to the point at infinity, this function might be described as "holomorphic on the cut plane, the cut extending along the negative real axis, from 0 (inclusive) to the point at infinity." Alternatively, might be described as "holomorphic in the cut plane with and excluding the point ." This cut is slightly different from the '''''' we've already encountered, because it actually the negative real axis from the cut plane. The branch cut left the real axis connected with the cut plane on one side , but severed it from the cut plane along the other side . Of course, it's not actually necessary to exclude the entire line segment from to to construct a domain in which is holomorphic. All we really have to do is
puncture the plane at a countably infinite set of points . But a closed contour in the punctured plane might encircle one or more of the poles of , giving a
contour integral that is not necessarily zero, by the
residue theorem. Cutting the complex plane ensures not only that is holomorphic in this restricted domain – but also that the contour integral of the gamma function over any closed curve lying in the cut plane is identically equal to zero.
Specifying convergence regions Many complex functions are defined by
infinite series, or by
continued fractions. A fundamental consideration in the analysis of these infinitely long expressions is identifying the portion of the complex plane in which they converge to a finite value. A cut in the plane may facilitate this process, as the following examples show. Consider the function defined by the infinite series f(z) = \sum_{n=1}^\infty \left(z^2 + n\right)^{-2}. Because for every complex number , it's clear that is an
even function of , so the analysis can be restricted to one half of the complex plane. And since the series is undefined when z^2 + n = 0 \quad \iff \quad z = \pm i\sqrt{n}, it makes sense to cut the plane along the entire imaginary axis and establish the convergence of this series where the real part of is not zero before undertaking the more arduous task of examining when is a pure imaginary number. In this example the cut is a mere convenience, because the points at which the infinite sum is undefined are isolated, and the plane can be replaced with a suitably plane. In some contexts the cut is necessary, and not just convenient. Consider the infinite periodic continued fraction f(z) = 1 + \cfrac{z}{1 + \cfrac{z}{1 + \cfrac{z}{1 + \cfrac{z}{\ddots}}}}. It
can be shown that converges to a finite value if is not a negative real number such that . In other words, the convergence region for this continued fraction is the cut plane, where the cut runs along the negative real axis, from − to the point at infinity. ==Gluing the cut plane back together==