The Flipped SU(5) model is a grand unified theory (GUT) first contemplated by Stephen Barr in 1982,[1] and by Dimitri Nanopoulos and others in 1984.[2] [3] Ignatios Antoniadis, John Ellis, John Hagelin, and Dimitri Nanopoulos developed the supersymmetric flipped SU(5), derived from the deeper-level superstring.[4] [5]
Some current efforts to explain the theoretical underpinnings for observed neutrino masses are being developed in the context of supersymmetric flipped .[6]
Flipped is not a fully unified model, because the factor of the Standard Model gauge group is within the factor of the GUT group. The addition of states below Mx in this model, while solving certain threshold correction issues in string theory, makes the model merely descriptive, rather than predictive.[7]
The flipped model states that the gauge group is:
Fermions form three families, each consisting of the representations
for the lepton doublet, L, and the up quarks ;
for the quark doublet, Q, the down quark, and the right-handed neutrino, ;
for the charged leptons, .
This assignment includes three right-handed neutrinos, which have never been observed, but are often postulated to explain the lightness of the observed neutrinos and neutrino oscillations. There is also a and/or called the Higgs fields which acquire a VEV, yielding the spontaneous symmetry breaking
The representations transform under this subgroup as the reducible representation as follows:
\bar{5}-3\to
| (\bar{3},1) | ||||
|
⊕
| (1,2) | ||||
|
101\to
| (3,2) | ||||
|
⊕
| (\bar{3},1) | ||||
|
⊕ (1,1)0
15\to(1,1)1
240\to(8,1)0 ⊕ (1,3)0 ⊕ (1,1)0 ⊕
| (3,2) | ||||
|
⊕
| (\bar{3},2) | ||||
|
The name "flipped" arose in comparison to the "standard" Georgi–Glashow model, in which and quark are respectively assigned to the and representation. In comparison with the standard, the flipped can accomplish the spontaneous symmetry breaking using Higgs fields of dimension 10, while the standard typically requires a 24-dimensional Higgs.[8]
The sign convention for varies from article/book to article.
The hypercharge Y/2 is a linear combination (sum) of the following:
\begin{pmatrix}{1\over15}&0&0&0&0\\0&{1\over15}&0&0&0\\0&0&{1\over15}&0&0\\0&0&0&-{1\over10}&0\\0&0&0&0&-{1\over10}\end{pmatrix}\inSU(5), \chi/5.
There are also the additional fields and containing the electroweak Higgs doublets.
Calling the representations for example, and is purely a physicist's convention, not a mathematician's convention, where representations are either labelled by Young tableaux or Dynkin diagrams with numbers on their vertices, and is a standard used by GUTtheorists.
Since the homotopy group
| \pi | ||||
|
\right)=0
this model does not predict monopoles. See 't Hooft–Polyakov monopole.
The superspace extension of Minkowski spacetime
SUSY over Minkowski spacetime with R-symmetry
(matter parity) not related to in any way for this particular model
Those associated with the gauge symmetry
As complex representations:
| label | description | multiplicity | rep | rep | ||
|---|---|---|---|---|---|---|
| GUT Higgs field | + | |||||
| GUT Higgs field | + | |||||
| electroweak Higgs field | + | |||||
| electroweak Higgs field | + | |||||
| matter fields | - | |||||
| matter fields | - | |||||
| left-handed positron | - | |||||
| sterile neutrino (optional) | - | |||||
| singlet | + |
A generic invariant renormalizable superpotential is a (complex) invariant cubic polynomial in the superfields which has an -charge of 2. It is a linear combination of the following terms:
\begin{matrix} S&S\\ S10H\overline{10}H&S
| \alpha\beta | |
| 10 | |
| H |
\overline{10}H\alpha\beta\\ 10H10HHd&\epsilon\alpha\beta\gamma\delta\epsilon
| \alpha\beta | |
| 10 | |
| H |
| \gamma\delta | |
| 10 | |
| H |
| \epsilon | |
| H | |
| d |
\\ \overline{10}H\overline{10}H
| \alpha\beta\gamma\delta\epsilon | |
| H | |
| u&\epsilon |
\overline{10}H\alpha\beta\overline{10}H\gamma\deltaHu\epsilon\\ Hd1010&\epsilon\alpha\beta\gamma\delta\epsilon
| \alpha | |
| H | |
| d |
| \beta\gamma | |
| 10 | |
| i |
| \delta\epsilon | |
| 10 | |
| j |
\\ Hd\bar{5}1
| \alpha | |
| &H | |
| d |
\bar{5}i\alpha1j\\ Hu10\bar{5}&Hu\alpha
| \alpha\beta | |
| 10 | |
| i |
\bar{5}j\beta\\ \overline{10}H10\phi&\overline{10}H\alpha\beta
| \alpha\beta | |
| 10 | |
| i |
\phij\\ \end{matrix}
The second column expands each term in index notation (neglecting the proper normalization coefficient). and are the generation indices. The coupling has coefficients which are symmetric in and .
In those models without the optional sterile neutrinos, we add the nonrenormalizable couplings instead.
\begin{matrix} (\overline{10}H10)(\overline{10}H10)&\overline{10}H\alpha\beta
| \alpha\beta | |
| 10 | |
| i |
\overline{10}H\gamma\delta
| \gamma\delta | |
| 10 | |
| j\\ \overline{10} |
H10\overline{10}H10&\overline{10}H\alpha\beta
| \beta\gamma | |
| 10 | |
| i\overline{10} |
H\gamma\delta
| \delta\alpha | |
| 10 | |
| j \end{matrix} |
These couplings do break the R-symmetry.