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Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET PDF Download

Complex Numbers and Complex Functions

A complex number z can be written as

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET

for purposes of proofs or illustrations. The behavior of the (real) functions u(x, y) and v(x, y) are critical for classifying complex functions, as seen when we consider taking derivatives.

 

Dierentiation and Analyticity

We de ne the derivative f'(z) = df =dz of a complex function f (z) in the same was as we do for the derivatives of real functions. That is, for  Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET

However, there is clearly an ambiguity, depending on whether we approach z0 along the line y = y0 or along x = x0. (Of course, we could also say the ambiguity is along any line of constant Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET but it is sucient to consider just two orthogonal directions.) That is,

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET

Therefore, in order to remove the ambiguity and have a consistent de nition of the derivative,

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET          (2)

These are called the Cauchy-Riemann conditions. A function f (z) which satis es these rather restrictive conditions is called analytic. Indeed, analytic functions have very many applications in physics, and we will merely scratch the surface here.

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET

so the Cauchy-Riemann conditions (2) are satised.

It is simple to show that f (z ) = az is analytic, where a is a complex constant. It is also not hard to show that the product of two analytic functions is analytic, so any function of the form  Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET  where n is a non-negative integer, is also analytic. Of course, any sum of analytic functions is analytic, so we see that any polynomial in z is analytic in the entire complex plane.

These examples beg the question: If a function f (z) can be written explicitly in terms of z , is it analytic? The answer is \Yes." To see this, realize that instead of x and y, we could always write a complex function in terms of z and z* using  Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET  Now consider

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET

so long as the Cauchy-Riemann conditions (2) are satis ed. That is, if the expression for f (z ) contains only z (and not z*) then the function is analytic.

There is some common terminology. A function f (z) need not be analytic in the entire complex plane. (If it is, we called the function \entire.") If it is analytic at a point z0 then we call that a \regular point." Otherwise, z0 is called a \singular point." Much of our discussion of complex integration will focus on the notion of singular points.

 

Integration and Series Expansion

Similarly to dierentiation, we approach integration of complex functions the same way as with real functions, but we need to be aware that there is now an arbitrariness of the "path" of integration. With dz = dx + idy and using using (1), we have

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET

where Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET So, we can now think of the two integrals on the right as real integrals of vector functions over curves in the xy plane. However, if we invoke Stokes' Theorem, these become integrals of the curls, and using (2), we nd

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET

and each of the two integrals on the right in (3) are path-independent. Hence, the integral of an analytic complex function f (z) is path-independent and can be unambiguously de ned.

From here on, we assume all functions to be analytic unless explicitly noted otherwise. It is obvious from (3) that, when integrating around a closed path C ,

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET

which is known as the Cauchy-Goursat Theorem. We will be exploring circumstances where the integrand is explicitly singular at one or more points.

For the rst example, we prove the Cauchy Integral Formula, namely

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET          (5)

where C is a closed contour in the complex plane that contains the point z0 and traversed in the counterclockwise direction. We can break up a contour C into something that looks like

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET

where C0 is a tiny circular contour around the singular point, but in the clockwise direction.

That is, we replace C with Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET the new contour C does not include the singular point, so by (4) we write (5) as

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET        (6)

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET

proving the Cauchy Integral Formula (5). A trivial, but suggestive, rewriting of (5) gives

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET            (7)

which leads to a convenient way to write the derivatives of a complex function, namely

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET               (8)

Now consider the series expansion of an analytic function f (z). We would naturally write

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET

Such a Taylor Series expansion works out as expected, but the curve C speci es regions in which the series converges.

This idea can be expanded to includeCauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET still using the right side of (10) to de ne an, and with modi ed regions of convergence. Such an expansion is called a Laurent Series. It clearly is not, in general, an analytic function because of poles that appear for n < 0. These, however, lead us to one of the most important theorems of complex analysis, so far as mathematical physics is concerned.


The Cauchy Residue Theorem

Let g(z) have an isolated singularity at z = z0. If the Laurent expansion can be written as

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET (11)

then we say that g(z) has a \simple pole" at z = z0. Higher order poles are possible, but we're not going to consider them here.

Consider a contour C within the radius of convergence of g(z). Separate the integral of g(z) around this contour into two terms, one for each of the two terms on the right in (11).
The second term is a polynomial in z ; therefore it is analytic and the integral is zero. Recall that we reduced the contour to a small circle around the pole in order to prove the Cauchy Integral Formula. We can do the same thing here, and

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET            (12)

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET

for a simple pole at z0.

If there are more than one simple pole within the contour C , this result is easy to generalize. Instead of redrawing the contour with a small loop about the single pole, do it for all N poles within the contour. The result is clearly

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET        (13)

We refer to this as the Cauchy Residue Theorem. It is widely used in mathematical physics.

The usefulness of the Residue Theorem can be illustrated in many ways, but here is one important example. It is a warm-up to evaluating the integral (6.2.9) in Modern Quantum Mechanics, 2nd Ed. The exercise is to evaluate the integral

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET           (14)

where k, a, q, and ε > 0 are all real variables. We use the second version above because this moves the singularities at Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET  off the real axis. To be sure, we could have moved off the real axis by using -iε instead of +iε, and in fact, this would give us a dierent answer. A physical rationale is needed to justify one sign or the other. Leave that for a physics course.

We can evaluate (14) using contour integration by rst allowing k to be complex and then noting thatCauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NETTherefore (14) can be rewritten as an integral over a semicircular contour C that runs (counter clockwise) along the Re(k) axis and closes as a semicircle in the Im(k) > 0 plane. Then for ε → 0, the integrand in (14) has poles at

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET

where we rede ne ε  (with q > 0) so that it is still small and has the same sign.

The pole at Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET does not matter to us, since it is outside the integration contour. However, the pole at  Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET  is inside, so we use the Residue Theorem to write

Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics | Physics for IIT JAM, UGC - NET, CSIR NET

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FAQs on Cauchy Residue Theorem - Mathematical Methods of Physics, UGC - NET Physics - Physics for IIT JAM, UGC - NET, CSIR NET

1. What is the Cauchy Residue Theorem?
Ans. The Cauchy Residue Theorem is a powerful result in complex analysis that allows us to compute contour integrals of functions with isolated singularities. It states that if f(z) is a function that is analytic everywhere inside and on a simple closed contour C, except for a finite number of isolated singularities, then the contour integral of f(z) around C can be computed by summing the residues of f(z) at these singularities.
2. How can the Cauchy Residue Theorem be applied in physics?
Ans. The Cauchy Residue Theorem finds applications in various areas of physics, particularly in quantum mechanics and electromagnetic theory. In quantum mechanics, it is used to evaluate integrals in the calculation of wavefunctions and expectation values. In electromagnetic theory, it is used to calculate the electromagnetic fields produced by charged particles or currents.
3. What are isolated singularities in the context of the Cauchy Residue Theorem?
Ans. In the context of the Cauchy Residue Theorem, isolated singularities refer to points within the contour where the function f(z) is not analytic. These singularities can be classified into three types: removable singularities, poles, and essential singularities. Removable singularities are those where the function can be analytically extended to make it continuous at that point. Poles are singularities where the function has a non-zero residue, and essential singularities are those where the function has an infinite number of terms in its Laurent series expansion.
4. How can the residues of a function be calculated using the Cauchy Residue Theorem?
Ans. The residues of a function at its isolated singularities can be calculated by finding the Laurent series expansion of the function around each singularity. The residue is then obtained by extracting the coefficient of the term with a power of (z-z0)^-1, where z0 is the singularity. Alternatively, if the function has a simple pole at z0, the residue can be calculated by evaluating the limit of (z-z0)f(z) as z approaches z0.
5. Are there any limitations or conditions for the application of the Cauchy Residue Theorem?
Ans. Yes, there are certain limitations and conditions for the application of the Cauchy Residue Theorem. The contour C must be a simple closed curve, and the function f(z) must be analytic everywhere inside and on C, except for a finite number of isolated singularities. The contour should also be traversed in a counterclockwise direction to ensure the correct signs of the residues. Additionally, the contour should not pass through any other singularities of the function. These conditions ensure the validity of the theorem and accurate computation of contour integrals.
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