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Magnetic Monopoles

Why is it interesting?

If magnetic monopoles exist, they explain why electric charge is quantized. Moreover, magnetic monopoles appear automatically in extensions of the standard model, such as grand unified theories.

Layman

Explanations in this section should contain no formulas, but instead colloquial things like you would hear them during a coffee break or at a cocktail party.

Student

Ever since Dirac has proposed the Dirac monopole generalizing the Maxwell’s theory, the monopole has become an obsession theoretically and experimentally [1]. After the Dirac monopole we have had the Wu-Yang monopole [2], the ’t Hooft-Polyakov monopole [3], the grand unification (Dokos-Tomaras) monopole [4], and the electroweak (Cho-Maison) monopole [5–9]. But none of them except for the electroweak monopole might become realistic enough to be discovered.

https://arxiv.org/pdf/1703.02188.pdf

There are two types of monopoles. One type is called Dirac monopoles and should be considered as a toy model, because there are many problems with such objects. Nevertheless, Dirac monopoles are great to get familiar with many important notions that are needed to describe more complicated topological objects. Dirac monopoles can be added to a pure $U(1)$ Yang-Mills theory, i.e. a theory with only one gauge boson present. Dirac monopoles are not topological solitons, because the electromagnetic field is singular at the location of the monopole and therefore the field energy is infinite.

The other type is called 't Hooft-Polyakov monopole. These are topological solitons and correspond to a field configuration with finite energy. They exist in gauge theories with, for example $SU(2)$ gauge symmetry, where the scalar field breaks the symmetry.

Further Details:

The Dirac Monopole
There are many good reason to not introduce magnetic monopoles in the standard $U(1)$ gauge theory of electromagnetism. However, Dirac did it anyway and realized that we don't need a globally well defined vector potential. Instead it is sufficient if $\vec A$ is a connection.

For an explicit calculation of the potential on both hemispheres, see page 243 in Topological Solitons by Manton, Sutcliffe

Because of the singularity at the location of the monopole it is not a topological soliton. Classically it has "infinite mass".

So far, no QFT of Dirac monopoles exists yet. However for monopoles that are topological solitons, like the 't Hooft-Polyakov monopole there is no such problem.

The occurrence of Gribov horizons points to a more general problem in the gauge fixing procedure. Unlike in electrodynamics, global gauge conditions may not exist in non-abelian gauge theories [52]. In other words, it may not be possible to formulate a condition which in the whole space of gauge fields selects exactly one representative. This difficulty of imposing a global gauge condition is similar to the problem of a global coordinate choice on e.g. $S^2$. In this case, one either has to resort to some patching procedure and use more than one set of coordinates (like for the Wu–Yang treatment of the Dirac Monopole [53]) or deal with singular fields arising from these gauge ambiguities (Dirac Monopole). Gauge singularities are analogous to the coordinate singularities on non-trivial manifolds (azimuthal angle on north pole).

Topological Concepts in Gauge Theories by F. Lenz

The electromagnetic potential $a_\mu$ in the presence of a monopole must be singular. Indeed, it must be singular at at least one point on every closed surface surrounding a monopole. That this is the case can be seen as follows. Let us calculate the total magnetic flux leaving - say, for simplicity - a sphere. Suppose the potential $a_\mu$ is nonsingular everywhere on the sphere. Then, using Stokes' theorem, one can write the flux from the northern hemisphere as […] Similarly, the flux from the southern hemisphere is: […] Clearly, on adding the two contributions together, one gets zero for the total magnetic flux, in contradiction with the assertion that there is a magnetic monopole inside, which should give a total flux of $e \pi \tilde e$ for a monopole of charge $\tilde e$. One concludes therefore that the supposition above was wrong, or in other words that $a_\mu$ must have a singularity somewhere on the sphere.

page 28 in Some Elementary Gauge Theory Concepts by Hong-Mo Chan, Sheung Tsun Tsou

’t Hooft–Polyakov Monopoles

Magnetic monopoles are topologically stable solutions of a non-abelian gauge theory with spontaneous symmetry breaking. […] The solution with this topological property in (3+1)-dimensional spacetime is the monopole, which has the form as |r| → ∞ that $$ \vec Φ(r) = A \frac{\vec r}{| \vec r |} \quad (| \vec r| → ∞), $$ with A a constant. The thing to notice here (as with the vortex) is the distinction between internal and real space components. The vector Φ lives in internal isospace but the radial vector r lives in real space. However, eqn 49.12 links these two together. In components we have, for example $φ^1(| \vec r| → ∞) = A \frac{x}{|\vec r|}$, that is, along the spatial 1-direction (also known as the x-direction) the field points along the internal 1- direction. Similarly along the y-direction the field points along the internal 2-direction and so on. In this sense, the field points radially outwards at infinity, which is why Polyakov called this the hedgehog solution.

page 453 in Quantum Field Theory for the gifted Amateur by T. Lancaster

The "core" structure of a ’t Hooft–Polyakov monopole is complicated, but the long range electromagnetic fields are the same as for a Dirac monopole. In this sense,we can say that ’t Hooft–Polyakov monopole are Dirac monopoles with the singularity smoothed out. They are stable, because the magnetic charge can not change through smooth deformations of the field. (Source: page 249 in Topological Solitons by Manton, Sutcliffe)

Through numerical analysis it was shown that any small deformation of the monopole solution increases the Yang-Mills energy. Therefore they correspond to local minima. However, there is no proof that they are global minima! (Source: page 259 in Topological Solitons by Manton, Sutcliffe)

A ’t Hooft–Polyakov monopole has spin $0$ because it is spherically symmetric.

The energy density of a BPS monopole depends only on the Higgs field. (Source: page 10 in http://www.itp.uni-hannover.de/~lechtenf/Events/Lectures/manton.pdf )

From the viewpoint of fibre bundle theory one faces the following problem. Since the fields in the 't Hooft-Polyakov Monopole are regular everywhere, they come from a trivial bundles, whereas the potential of the Dirac monopole (with $m\neq 0$) possessing a string singularity determines a nontrivial principal bundle. How is it then possible to recover the Dirac monopole from the 't Hooft-Polyakov monopole? With the help of the above gauge transformation we got the string singularity by "brute force" admitting a singularity $\gamma$. The answer within the framework of fibre bundles will be given in section 10.6.

Differential Geometry, Gauge Theories, and Gravity by M. Göckeler, T. Schücker


Recommended Resources

  • The best book is: Magnetic Monopoles by Shnir!
  • The Magnetic Monopole Fifty Years Later by Sidney R. Coleman is a great introduction
  • also good: Chapter 2 in Some Elementary Gauge Theory Concepts by Sheung Tsun Tsou, Hong-Mo Chan
  • Magnetic Monopoles by G. GIACOMELLI
  • MAGNETIC MONOPOLES by John Preskil

Researcher

Around a magnetic monopole the total space is not simple $S^2 \times U(1)$ (the trivial bundle), where $S^2$ is a spatial sphere around the monopole and $U(1)$ is our gauge group. Instead the monopole alters the global structure such that the total space is instead $S^3$ (the principal bundle). This means, through the presence of the magnetic monopole the fibers get glued differently together. This is reflected through a different connection on the fibre bundle, which is what we call in the physics a different gauge potential.

$S^3$ and $S^2 \times U(1)$ are locally the same but are globally different.

The best explanation for these things can be found in chapter 0 of the book Topology, Geometry and Gauge fields by G. Naber.


See also Hopf Bundle.

Examples

Example1
Example2:

FAQ

When do Monopoles exist in a theory?
A was necessary topological condition was given in Concerning the existence of monopoles in gauge field theories by Monastyrskii M.I. , Perelomov A.M.

It can be proved [2.25] that 't Hooft-Polyakov magnetic monopole solutions occur for any gauge theory in which a simple (or semi-simple) gauge group is broken down spontaneously to a factor group $H=H' \times U(1)$, where $H'$ is a simple or semi-simple gauge group and $U(1)$ is identified with the electromagnetic gauge group.

page 590 in Conceptual Foundations of Modern Particle Physics by Robert E Marshak

When the gauge group is compact, which means that the charge is quantized, monopoles exist. See, the great discussion chapter 2 of Some Elementary Gauge Theory Concepts by Hong-Mo Chan,Sheung Tsun Tsou

Take in particular theories with gauge algebra $\mathfrak{su}(n)$. It was noted in Section 1.4 that if we deal with pure Yang-Mills theory containing only gauge bosons, the gauge group is $SU(N)/Z_N$, but if the theory contains other fields belonging to the fundamental representation, such as quarks in QCD, then the gauge group is $SU(N)$. We shall now show that whereas monopole charges are admitted by the former theory, no monopole charge exists in the latter theory. It is sufficient to illustrate with the simplest example, namely the theory with the gauge algebra $\mathfrak{su}(2)$. […] [A] theory with gauge group $SU(2)$ cannot admit monopoles in the sense defined above since any closed curve on $\Gamma_0$ on $S^3$ can be continuously deformed to a point, as illustrated in Figure 2.5. On the other hand, if we are dealing with the pure Yang-Mills theory, the gauge group is no longer $SU(2)$ but $SU(2)/Z_2 \simeq SO(3)$, which is obtained from $SU(2)$ by identifying pairs of elements with opposite signs. […] Theories with gauge group $SU(N)$ have no monopoles, but the pure gauge theories with gauge group $SU(N)/Z_N$ will have monopoles whose charges take values in $Z_N$. Thus, in particular, full QCD containing both gluons and color triplet quarks has no monopoles while pure QCD with only gluons admit monopoles with charges labelled by a"triality", i.e. integers modulo 3, or equivalently the cube roots of unity: $\zeta_r= exp(i2\pi r/3)$, $r=0,1,2$.

page 24 in Some Elementary Gauge Theory Concepts by Hong-Mo Chan, Sheung Tsun Tsou

The condition for a nonsingular monopole is that the topological charge is in the kernel of the mapping $\pi_1(H) \to \pi_1(G)$. [..] The fact that the condition is both necessary and sufficient makes it the jewel of monopole theory, well worthy of being honored with a box. It enables us to tell instantly, without solving a single differential equation, whether a given theory admits non- singular monopoles, and what kinds it admits.

section 4.2 "Making Monopoles" in The Magnetic Monopole Fifty Years Later by Sidney R. Coleman

Why do we get monopoles in grand unified theories?
"gauge theories based on simple groups have magnetic monopoles" from Why Unify by H. Georgi

"Gauge theories in which a simple group G is spontaneously broken at a mass scale $M_X$ to a subgroup $G_1 \times U(1)$ containing an explicit $U(1)$ factor necessarily possess t'Hooft-Polyakov magnetic monopoles of mass $m \sim M_X /g^2$ . (These are topologically stable classical configurations of the gauge and Higgs fields of the theories). All grand unified theories possess such monopole solutions since $U(1)_{EM}$ is unbroken. In particular, $M_X \sim 10^{14}$ Gev in 3-2-1 desert theories, so that $m \sim 10^{16}$ GeV. These monopoles may have been produced prolifically in the early universe, especially at the time of the phase transition below which the grand unified symmetry was broken. " Langacker - Grand Unified Theories

"But upon grand unification into SU(5) [or more generally any group without U(1) factors] electric charge is quantized. The result here is deeply connected to Dirac’s remark (chapter IV.4) that electric charge is quantized if the magnetic monopole exists. We know from chapter V.7 that spontaneously broken nonabelian gauge theories such as the SU (5) theory contain the monopole." from Quantum Field Theory in a Nutshell by A. Zee

Is there a Dirac String attached to each monopole?

No! This was found by Wu and Yang through their description of the magnetic monopole, which makes it possible to avoid a string of singularities.

The above arguments hold for any sphere surrounding the monopole. Hence, by increasing continuously the radius of the sphere, the singularity on it will trace out a continuous curve. In other words, we have deduced that a monopole must be attached to a whole line of singularities stretching all the way to infinity. Such a line of singularities, first noted by Dirac, is called a Dirac string. […] From the above example, then, one sees that the Dirac string is actually not a physical singularity at all, but merely a singularity in our representation of the potential in a particular gauge choice. It is similar in nature to the coordinate singularity in the cartographer's zenithal projection of the globe. There, if the north pole is chose as the zenith, the the coordinates of the north pole is chose as the zenith, then the coordinates of the north pole ar singular, and if the south pole is chosen as the zenith, then the coordinates of the south pole are singular, although there is no actual singularity on the globe itself. To give a full representation of the globe, the cartographer usually uses two zenithal projections, say one from the north pole and one from the south pole; then specifies which point in one projection corresponds to which point on the other in the region where the two projections overlap, e.g. by giving the longitudes of points in the equatorial region on both charts. In a very similar fashion, one can give a fully nonsingular representation of the gauge potential $a_\mu$ over the whole surface surrounding a monopole provided that one pays the price of using more than one coordinate patch and specifying in the overlap regions of these patches the relation between the potentials defined in the different patches. […] In the presence of a monopole the electromagnetic potential $a_\mu(x)$ has to be patched.

page 29 in Some Elementary Gauge Theory Concepts by Hong-Mo Chan, Sheung Tsun Tsou

In the sphere example, if we use such a patched description, the gauge field is nonsingular in both patches. However, now the two expression for the magnetic flux through the two hemispheres do no longer cancel. By using Stokes' theorem, we only integrate over the boundary of both patches, which is just the equator

\begin{align} \int_{S^2} \text{ Flux} &= \int_{\text{ Northern Hemisphere}} da^{(1)} + \int_{\text{ Southern Hemisphere}} da^{(1)} \notag \\ &= \int_{\text{ Equator: } 0 \to 2 \pi} a^{(1)} + \int_{\text{ Equator: } 2 \pi \to 0} a^{(2)} \\ &= \int_{\text{ Equator: } 0 \to 2 \pi} a^{(1)} - \int_{\text{ Equator: } 0 \to 2 \pi} a^{(2)} \\ \tag{1} \end{align}

The description on the two hemispheres are related by a gauge transformation. This gauge transformation is also called the transition function:

\begin{align} a_\mu^{(1)} &= a_\mu^{(2)} - d\alpha^{(21)} \notag \\ \phi^{(2)} &= e^{-i \alpha^{(21)} } \phi^{(1)} . \tag{2} \end{align}

The transition function must be well defined in its region and therefore be single valued. This means especially that

$$ e^{-i \alpha^{(21)}(\theta, 2\pi) } = e^{-i \alpha^{(21)}(\theta, 0) } \tag{3}$$ where the interval $\{0,2\pi\}$ is meant around the equator, holds.

Now, from Eq. 2 it follows that the integral in Eq. 1 is simply

\begin{align} \int_{S^2} \text{ Flux} &= \int_{\text{ Equator}} a^{(1)} - \int_{\text{ Equator}} a^{(2)} \notag \\ &= \int_{\text{ Equator}} d\alpha^{(21)} = \alpha^{(21)} \left( \frac{\pi}{2}, 2\pi \right) - \alpha^{(21)} \left( \frac{\pi}{2}, 0 \right) \, . \end{align}

The magnetic flux is therefore the increase in $\alpha^{(21)} $ as we move around the equator. Because of Eq. 3 this must be an integer multiple of $2 \pi$.

This is discussed nicely in section 3.4 at page 65 in Topological Solitons by Manton and Sutcliffe.

The Wu-Yang approach not only eliminates the “Dirac string” but, in the process, does three things: (1) it provides a derivation of Dirac's quantization condition in a geometric context; (2) it exhibits the close relationship between a "global" (large) gauge transformation - in contrast to a "local" gauge transformation - to topological winding numbers (see §10.4a); and finally (3) it puts in proper perspective the relation between the Dirac magnetic monopole and the 't Hooft-Polyakov magnetic monopole (see §10.2c).

page 260 in Conceptual Foundations of Modern Particle Physics by Robert Eugene Marshak

What's the difference between Dirac Monopoles and. ’t Hooft–Polyakov Monopoles

The crucial difference with the original Dirac proposal was that, because these monopoles appear as regular, soliton-like solutions to the classical field equations, they are unavoidable and cannot be left out.

https://staff.science.uva.nl/f.a.bais/boeken/monop.pdf

The Dirac monopole can be added by hand to a pure $U(1)$ gauge theory. In contrast, the t' Hooft-Polyakov monopole appears in a $SU(2)$ or $SO(3)$ Yang-Mills theory, where additionally scalars are present.

Dirac monopoles are classified by $\pi_1(S^1)$ (source) and ’t Hooft–Polyakov monopoles by $\pi_2(G/H)=\pi_2(S^2)$, where $G$ is the gauge group before and $H$ after symmetry breaking.

Comparing the 't Hooft-Polyakov monopole with the Dirac monopole it will seem as if the have almost nothing in common; to be more precise, nothing at all except that they both possess magnetic charge. This is not quite true […] From Equation (10.59) we may say that the gauge transformation transfers responsibility for the monopole from the first (Dirac) term, to the second (topological, Higgs) one. […] It is shown how a gauge transformation relates the Dirac and 't Hooft-Polyakov monopoles.

page 412 and page 414 and page 424 in Quantum Field Theory by L. Ryder

The Georgi-Glashow model is capable of predicting a magnetic monopole of the non-singular "'tHooft-Polyakov" type which acquires the property of a Dirac monopole as $r \to \infty$. […] There are other important differences between the "'t Hooft-Polyakov" and Dirac monopoles: in particular, the finite core spatial structure of the "'t Hooft-Polyakov" monopole is quite different from the "string" singularities associated with the Dirac monopole.

page 587 in Conceptual Foundations of Modern Particle Physics by Robert E Marshak

Notice how the ’t Hooft–Polyakov monopole and Dirac monopole are very different beasts. Dirac monopoles are singular mathematical solutions of electrodynamics which necessitate the introduction of point particles as the sources of the magnetic flux. These particles have arbitrary spin and mass. In contrast ’t Hooft–Polyakov monopoles are nonsingular solutions arising from the interaction of a non-abelian gauge theory and a scalar field. All of their properties, such as their mass, are determined by the original theory.

page 455 in Quantum Field Theory for the gifted Amateur by T. Lancaster

Each of the apparently independent lines of thought followed in the two preceding sections has led us to consider a gauge theory with the symmetry group, G, spontaneously broken by the vacuum to a subgroup H. From §2 we expect to find electric charge quantisation (at least if the electric charge, Q, generates H= U(1)) and magnetic monopoles, whilst according to §3 we expect to find extended 'soliton' solutions to such theories with long-range magnetic fields. In this way we are led to anticipate a non-singular extended solution which at large distances looks like a Dirac monopole, and further that its magnetic charge will be related to the topological quantum number specified by the boundary conditions on the scalar fields. This section will show how these expectations are indeed realised.

Magnetic monopoles in gauge field theories by P GODDARD and DI OLIVE

What are typical properties of monopoles?

In general, the mass of of the resulting monopole $M_{mp}$ is fixed - in analogy to the Georgi-Glashow model - by the symmetry breaking scale $M_X$ for $G \to H' \times U(1)$ and is of order $M_{mp} \sim M_X/g^2$ [see Eq. (10.58)].

page 590 in Conceptual Foundations of Modern Particle Physics by Robert E Marshak

’t Hooft estimated the mass of these beasts as MW/α ≈ 137MW ≈ 11 TeV, making them very heavy indeed and outside the range of our experiments. Their existence therefore remains an open question.

page 455 in Quantum Field Theory for the gifted Amateur by T. Lancaster

See also section 4.4 "Why Monopoles are Heavy" in The Magnetic Monopole Fifty Years Later by Sidney R. Coleman

How can the GUT monopole problem be solved?

There are three known solutions to the GUT monopole over-abundance problem. The first is that the GUT phase transition that produces magnetic monopoles is followed by a period of inflation that dilutes the monopole density to acceptable levels [Guth, 1981]. The second is that the GUT model includes a period during which electromagnetism is broken. During this period, the magnetic monopoles will get connected by strings, leading to rapid annihilation and dilution [Langacker and Pi, 1980]. The third possibility is that the GUT phase transition never occurred and the universe was always in a state of broken GUT symmetry [Dvali, Melfo and Senjanovic, 1995]. All three solutions of the monopole over-abundance problem require fine tuning of parameters and/or model building solely for the purpose of eliminating magnetic monopoles.

https://arxiv.org/pdf/hep-ph/9801367.pdf

What's the experimental status of monopoles?
Even if all magnetic monopoles had annihilated in the early universe, we would see a relic radiation of these processes. This scenario is ruled out by cosmic data and this speaks strongly against a dense sea of magnetic monopoles in the early universe. (Source: page 250 in Topological Solitons by Manton, Sutcliff)

See also The search for magnetic monopoles by Arttu Rajantie

Are there magnetic monopoles in the standard model of particle physics?

Unfortunately - in terms of physical interest - the SSB of the standard electroweak group $G=SU(2)_L \times U(1)_Y$ to $H=U(1)_{EM}$ does not yield a 't Hooft-Polyakov-type monopole. With the knowledge that the electric charge Q is the sum of the $I_{3L}$ generator in $SU(2)_L$ and the $U(1)_Y$ generator, this can be seen as follows: the $U(1)_{EM}$ group does not lie entirely in the $U(1)_Y$ group and hence any non-contractible closed loop in $H=U(1)_{EM}$ [remember that $G/H=[SU(2)_L \times U(1)_Y]/U(1)_{EM}$ is the coset space] may be deformed in $G$ to stay non-contractible in $U(1)_Y$. Thus, unless the deformation of the closed loop in $U(1)_Y$ is trivial, it cannot be deformed to a point in $G$ and, consequently, the condition for a 't Hooft-Polyakov monopole [i.e. a contractible loop in $G$ and non-contractible in $H$] is not satisfied. The "exact sequence" statement of this negative result is: $$ \Pi_2[SU(2)_L \times U(1)_Y/U(1)_{EM}]\simeq \Pi_2[U(1)]_{SU(2)_L \times U(1)_Y} =0 \, ,$$ which tells us that no "'t Hooft-Polyakov" monopole can be generated from the SSB of the standard electroweak group.

page 590 in Conceptual Foundations of Modern Particle Physics by Marshak

Take note that some authors argue there could be topological objects in the standard model: https://ncatlab.org/nlab/show/monopole#ElectroweakMonopoles

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