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A Kaluza-Klein Gluon Model
Authors
- Elizabeth Drueke (Michigan State University)
- Joseph Nutter (Michigan State University)
- Reinhard Schwienhorst (Michigan State University)
- Natascia Vignaroli (Michigan State University)
- Devin G. E. Walker (SLAC National Accelerator Laboratory)
- Jiang-Hao Yu (The University of Texas at Austin)
- R. Sekhar Chivukula (Michigan State University)
- Elizabeth H. Simmons (Michigan State University)
Description of the Model
Colored vector bosons from new strong dynamics, Kaluza-Klein gluons or KKg’s (G*) in a dual 5D picture, have been searched for mainly in the t-tbar channel. The analysis in 1409.7607v2 analyzes the tc decay as depicted below: The benchmark adopted here is a simple renormalizable model of an extended color gauge sector, which realizes next-to-minimal flavor violation (NMFV). In this model, the third generation quarks couple differently than the light quarks under an extended
$SU(3)_1 \times SU(3)_2$
color gauge group. The mixing between light and third generation quarks is induced by the interactions of all three generation quarks with a set of new heavy vector-like quarks. The model reproduces the CKM mixing and generates flavor-changing neutral currents (FCNCs) from non-standard interactions. Due to the specific structure of the model, dangerous FCNCs are naturally suppressed and a large portion of the model parameter space is allowed by the data on meson mixing process and on
$b \to s\gamma$.
The model has the color gauge structure
$SU(3)_1 \times SU(3)_2$
The extended color symmetry is broken down to
$SU(3)_C$
by the (diagonal) expectation value,
$\langle \Phi \rangle \propto u \cdot {\cal I}$,
of a scalar field Phi which transforms as a
$(\bf 3, \bar{3})$
under the color gauge structure. It is assumed that color gauge breaking occurs at a scale much higher than the electroweak scale, u>>v.
Breaking the color symmetry induces a mixing between the
$SU(3)_1$ \rm{and} $SU(3)_2$
gauge fields
$A^{1}_{\mu}$ \rm{and} $A^{2}_{\mu}$,
which is diagonalized by a rotation determined by
$\cot\omega = \frac{g_1}{g_2} \qquad g_s = g_1 \sin\omega = g_2 \cos\omega$,
where g_s is the QCD strong coupling and g_1, g_2 are the SU(3)_1 and SU(3)_2 gauge couplings, respectively. The mixing diagonalization reveals two color vector boson mass eigenstates: the mass-less SM gluon and a new massive color-octet vector boson G* given by
$G^{*}_{\mu}=\cos\omega A^{1}_{\mu} - \sin\omega A^{2}_{\mu} \qquad M_{G^{*}} = \frac{g_s u}{\sin\omega \cos\omega}.$
In the NMFV model, the third generation quarks couple differently than the light quarks under the extended color group.
$g_L=(t_L, b_L),$ \rm{ } $t_R,$ \rm{ and } $b_R,$
as well as a new weak-doublet of vector-like quarks, transform as
$({\bf 3,1})$
under the color gauge group, while the light generation quarks are charged under SU(3)_2 and transform as
$({\bf 1,3})$
The G* interactions with the color currents associated with SU(3)_1 and SU(3)_2 are given by
$g_s \left(\cot\omega J^{\mu}_1 - \tan\omega J^{\mu}_2 \right)G^{*}_{\mu}.$
The G* can be produced at the LHC by quark-antiquark fusion determined by the G* coupling to light quarks
$g_s \tan\omega$
Gluon-gluon fusion production is forbidden at tree level by SU(3)_C gauge invariance.
The G* decay widths are:
$\Gamma[G^{*} \to t\bar t] = \frac{g^2_s}{24\pi} M_{G^{*}}\cot^2\omega \sqrt{1-4 \frac{m^2_t}{M^2_{G^{*}}}} (1+2\frac{m^2_t}{M^2_{G^{*}}}),$ \newline $\Gamma[G^{*} \to b\bar b] = \frac{g^2_s}{24\pi} M_{G^{*}}\cot^2\omega,$ \newline $\Gamma[G^{*} \to j j] = \frac{g^2_s}{6\pi} M_{G^{*}}\tan^2\omega.$
Additionally, the NMFV flavor structure of the model generates a G* to tc flavor violating decay with rate
$\Gamma[G^{*} \to t_L \bar c_L]=\Gamma[G^{*} \to c_L \bar t_L]\simeq \left(V_{cb}\right)^2 \frac{g^2_s}{48\pi} M_{G^{*}} \left( \cot\omega+\tan\omega \right)^2,$
where
$V_{cb}=0.0415$
is the CKM matrix element. Note here that G* FCNCs are induced by the mixing among left-handed quarks generated by the exchange of heavy vector-like quarks. This mixing is controlled by the 3x3 matrices U_L and D_L in the up- and down-quark sectors, respectively. In particular, the
$G* \to tc$
flavor violating decay is controlled by the
$(U_L)_{23}$
element. The CKM mixing matrix is given by
$V_{CKM}=U^{\dagger}_L D_L$.
At first order in the mixing parameters,
$(U_L)_{23}\equiv V_{cb} - (D_L)_{23}$.
The non-diagonal elements of D_L are strongly constrained by the data on
$b\to s \gamma$.
So
$(D_L)_{23}$
is thus forced to be small and, as a consequence,
$(U_L)_{23}\simeq V_{cb}$.
See more details in
Model Files
- proc_card: for generation of 500 GeV KKg (place in Cards/)
- run_card: for generation of 500 GeV KKg (place in Cards/)
- kkg_FV: the model and parameter cards for specific mass generations
Generation specifics
In 1409.7607v2, the samples were generated with the mass as the scale, dsqrt_q2fact1, and dsqrt_q2fact2 in the run_card. These samples were also generated without the pre-included MadGraph cuts as demonstrated in the run_card.dat for 500 GeV mass included above. The specific generations run were
p p > kkg > b~ c l- vl~ @1 p p > kkg > b c~ l+ vl @2
To generate a specific mass, param_card.dat in the generation file to the card of the appropriate mass in the param_cards directory (included as part of the model zip file).
Attachments (4)
-
KKg.png
(1.7 KB
) - added by 9 years ago.
Feynman Diagram for kkg > tc
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proc_card_mg5.dat
(1.9 KB
) - added by 9 years ago.
process card for a 500 GeV mass KKg
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run_card.dat
(13.8 KB
) - added by 9 years ago.
run card for a 500 GeV mass KKg
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kkg_FV.zip
(28.9 KB
) - added by 9 years ago.
model
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