Essential singularity explained

In complex analysis, an essential singularity of a function is a "severe" singularity near which the function exhibits striking behavior.

The category essential singularity is a "left-over" or default group of isolated singularities that are especially unmanageable: by definition they fit into neither of the other two categories of singularity that may be dealt with in some manner - removable singularities and poles. In practice some include non-isolated singularities too; those do not have a residue.

Formal description

of the complex plane

. Let

be an element of

, and

f\colonU\setminus\{a\}\toC

a holomorphic function. The point

is called an essential singularity of the function

if the singularity is neither a pole nor a removable singularity.

For example, the function

f(z)=e^1/z

has an essential singularity at

z=0

Alternative descriptions

Let

be a complex number, and assume that

f(z)

is not defined at

but is analytic in some region

of the complex plane, and that every open neighbourhood of

has non-empty intersection with

If both

\lim_zf(z)

and

\lim_z

	1
	f(z)

exist, then

is a removable singularity of both

and

	1
	f

\lim_zf(z)

exists but

\lim_z

	1
	f(z)

does not exist (in fact

\lim_z\to|1/f(z)|=infty

), then

is a zero of

and a pole of

	1
	f

Similarly, if

\lim_zf(z)

does not exist (in fact

\lim_z\to|f(z)|=infty

) but

\lim_z

	1
	f(z)

exists, then

is a pole of

and a zero of

	1
	f

If neither

\lim_zf(z)

nor

\lim_z

	1
	f(z)

exists, then

is an essential singularity of both

and

	1
	f

Another way to characterize an essential singularity is that the Laurent series of

at the point

has infinitely many negative degree terms (i.e., the principal part of the Laurent series is an infinite sum). A related definition is that if there is a point

for which no derivative of

f(z)(z-a)ⁿ

converges to a limit as

tends to

, then

is an essential singularity of

.^[1]

On a Riemann sphere with a point at infinity,

infty_C

, the function

{f(z)}

has an essential singularity at that point if and only if the

{f(1/z)}

has an essential singularity at 0: i.e. neither

\lim_z{f(1/z)}

nor

\lim_z

	1
	f(1/z)

exists.^[2] The Riemann zeta function on the Riemann sphere has only one essential singularity, at

infty_C

.^[3] Indeed, every meromorphic function aside that is not a rational function has a unique essential singularity at

infty_C

The behavior of holomorphic functions near their essential singularities is described by the Casorati–Weierstrass theorem and by the considerably stronger Picard's great theorem. The latter says that in every neighborhood of an essential singularity

, the function

takes on every complex value, except possibly one, infinitely many times. (The exception is necessary; for example, the function

\exp(1/z)

never takes on the value 0.)

References

Lars V. Ahlfors; Complex Analysis, McGraw-Hill, 1979
Rajendra Kumar Jain, S. R. K. Iyengar; Advanced Engineering Mathematics. Page 920. Alpha Science International, Limited, 2004.

External links

Notes and References

Web site: Weisstein . Eric W. . Essential Singularity . MathWorld . Wolfram . 11 February 2014.
Web site: Infinity as an Isolated Singularity. 2022-01-06.
Steuding . Jörn . Suriajaya . Ade Irma . 2020-11-01 . Value-Distribution of the Riemann Zeta-Function Along Its Julia Lines . Computational Methods and Function Theory . en . 20 . 3 . 389–401 . 10.1007/s40315-020-00316-x . 2195-3724. free . 2324/4483207 . free .