SO(10)

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In particle physics, one of the grand unified theories (GUT) is based on the SO(10) Lie group. (The Lie group involved is not really the special orthogonal group SO(10), but rather its double cover Spin(10); but calling it SO(10) is the standard convention.)

Before SU(5), Harald Fritzsch and Peter Minkowski and independently Howard Georgi found that all the matter contents are incorporated into a single representation, spinorial 16 of SO(10). Historical note added: the Before in the previous sentence is misleading. Georgi found the SO(10) theory a few hours before finding SU(5) at the end of 1973 - this story is told in various places - for example [100th Birthday Celebration]. Fritzsch and Minkowski analyzed SO(10) in 1974.

It has the branching rules to [SU(5)×U(1)_χ]/Z₅.

${\displaystyle 45\rightarrow 24_{0}\oplus 10_{-4}\oplus {\overline {10}}_{4}\oplus 1_{0}}$

${\displaystyle 16\rightarrow 10_{1}\oplus {\bar {5}}_{-3}\oplus 1_{5}.}$

${\displaystyle 10\rightarrow 5_{-2}\oplus {\bar {5}}_{2}.}$

If the hypercharge is contained within SU(5), this is the conventional Georgi-Glashow model, with the ${\displaystyle 16}$ as the matter fields, the ${\displaystyle 10}$ as the electroweak Higgs field and the ${\displaystyle 24}$ within the ${\displaystyle 45}$ as the GUT Higgs field. The superpotential may then include renormalizable terms of the form ${\displaystyle Tr(45\cdot 45)}$; ${\displaystyle Tr(45\cdot 45\cdot 45)}$; ${\displaystyle 10\cdot 45\cdot 10}$, ${\displaystyle 10\cdot 16^{*}\cdot 16}$ and ${\displaystyle 16^{*}\cdot 16}$. The first three are responsible to the gauge symmetry breaking at low energies and give the Higgs mass, and the latter two give the matter particles masses and their Yukawa couplings to the Higgs.

There is another possible branching, under which the hypercharge is a linear combination of an SU(5) generator and χ. This is known as flipped SU(5).

Another important subgroup is either ${\displaystyle [\mathrm {SU} (4)\times \mathrm {SU} (2)_{L}\times \mathrm {SU} (2)_{R}/\mathbb {Z} _{2}}$ or ${\displaystyle \mathbb {Z} _{2}\rtimes [\mathrm {SU} (4)\times \mathrm {SU} (2)_{L}\times \mathrm {SU} (2)_{R}]/\mathbb {Z} _{2}}$ depending upon whether or not the left-right symmetry is broken, yielding the Pati-Salam model, whose branching rule is

${\displaystyle 16\rightarrow (4,2,1)\oplus ({\bar {4}},1,2).}$

The symmetry breaking of SO(10) is usually done with a combination of (( a 45_H OR a 54_H) AND ((a 16_H AND a ${\displaystyle {\overline {16}}_{H}}$) OR (a 126_H AND a ${\displaystyle {\overline {126}}_{H}}$)) ).

Let's say we choose a 54_H. When this Higgs field acquires a GUT scale VEV, we have a symmetry breaking to ${\displaystyle \mathbb {Z} _{2}\rtimes [\mathrm {SU} (4)\times \mathrm {SU} (2)_{L}\times \mathrm {SU} (2)_{R}]/\mathbb {Z} _{2}}$, i.e. the Pati-Salam model with a Z₂ left-right symmetry.

If we have a 45_H instead, this Higgs field can acquire any VEV in a two dimensional subspace without breaking the standard model. Depending on the direction of this linear combination, we can break the symmetry to SU(5)×U(1), the Georgi-Glashow model with a U(1) (diag(1,1,1,1,1,-1,-1,-1,-1,-1)), flipped SU(5) (diag(1,1,1,-1,-1,-1,-1,-1,1,1)), SU(4)×SU(2)×U(1) (diag(0,0,0,1,1,0,0,0,-1,-1)), the minimal left-right model (diag(1,1,1,0,0,-1,-1,-1,0,0)) or SU(3)×SU(2)×U(1)×U(1) for any other nonzero VEV.

The choice diag(1,1,1,0,0,-1,-1,-1,0,0) is called the Dimopoulos-Wilczek mechanism aka the missing VEV mechanism and it is proportional to B−L.

The choice of a 16_H and a ${\displaystyle {\overline {16}}_{H}}$ breaks the gauge group down to the Georgi-Glashow SU(5). The same comment applies to the choice of a 126_H and a ${\displaystyle {\overline {126}}_{H}}$.

It is the combination of BOTH a 45/54 and a 16/${\displaystyle {\overline {16}}}$ or 126/${\displaystyle {\overline {126}}}$ which breaks SO(10) down to the Standard Model.

The electroweak Higgs doublets come from an SO(10) 10_H. Unfortunately, this same 10 also contains triplets. The masses of the doublets have to be stabilized at the electroweak scale, which is many orders of magnitude smaller than the GUT scale whereas the triplets have to be really heavy in order to prevent triplet-mediated proton decays. See doublet-triplet splitting problem.

Among the solutions for it is the Dimopoulos-Wilczek mechanism, or the choice of diag(0,0,0,1,1,0,0,0,-1,-1) of <45>. Unfortunately, this is not stable once the 16/${\displaystyle {\overline {16}}}$ or 126/${\displaystyle {\overline {126}}}$ sector interacts with the 45 sector.^[1]

The matter representations come in three copies (generations) of the 16 representation. The Yukawa coupling is 10_H 16_f 16_f. This includes a right-handed neutrino. We can either include three copies of singlet representations φ and a Yukawa coupling ${\displaystyle <{\overline {16}}_{H}>16_{f}\phi }$ (see double seesaw mechanism) or add the Yukawa interaction ${\displaystyle <{\overline {126}}_{H}>16_{f}16_{f}}$ or add the nonrenormalizable coupling ${\displaystyle <{\overline {16}}_{H}><{\overline {16}}_{H}>16_{f}16_{f}}$. See seesaw mechanism.

• These graphics refer to the X bosons and Higgs bosons.
• 
  Dimension 6 proton decay mediated by the ${\displaystyle X}$ boson ${\displaystyle (3,2)_{-{\frac {5}{6}}}}$ in ${\displaystyle SU(5)}$ GUT
• 
  Dimension 6 proton decay mediated by the ${\displaystyle X}$ boson ${\displaystyle (3,2)_{\frac {1}{6}}}$ in flipped ${\displaystyle SU(5)}$ GUT

Note that SO(10) contains both the Georgi-Glashow SU(5) and flipped SU(5).

• Flipped SO(10)